CHAPTER VII--DRILLS, COUNTERSINKS, AND REAMERS

Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 STAT Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Chapter VII. DTU_LJ , COUNTE1INKS AND BE il'ERS DRILLS Des nation and 7 eae Drills are d.esi gned for (a) drilling holes in solid. mater:i a1; (b) overs~.e drilling of already existing holes (as, for instance' holes cast, forged, or drop-forged integrally); (c) the drilling of tapered center holes. (1) 04) By design and purpose, drills are divided as follows: spiral or twist drills; (2) center drills; (3) pointed drills; straight-flute drills; (5) drills with hard alloy- tiPped blades; (h) deep hole drills. T~rist drills are basically representative' of this group of tools, and they have found the widest application. They are used for the drilling of: (a) holes that require no subsequent machining; (b) holes .for subsequent countersinking; (c) holes for subsequent reaming; (d) holes for subsequent threading with taps. GOST 885 ? 241 cites the data recommended for use in the selection of drill diameters in relation to the purpose of drilling. wist Drills Definition and ty e A twist drill (helical di-i l is more correct) is a rod having two helical lips relieved at the point in Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 STAT';'.  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 (3) lef. tt hand straight shank for automatic machines (COST 2090 b3); () taper~sha.nk (COST 888 Li); (6) shortened with accelerated taper shank (OST 20182 - ~O); (7) lengthened with taper-shank (GUST 2092 m L3)3 (8) with tetrahedral tapering shank for ratchet drills (OST 20231 - ~l1? All the above enumerated types of twist drills are differentiated by their shanks ,g the bits being basical-iy the same in design conceptaana Heavy duty twist drills, such as deep-hole drills, are equipped w7 th special grooves to allow the flaw of coolant to the cutting edgesm For the machining of holes with two or three drill diameters, two or thre'e~step drills are produced. The basic terminology, desi.gnatiars, and definitions 'of drills are summarized in G0 ST 289L. L>, and the geometric parameters of the drill bats, in COST 2322 L3. Parts anca structural contpone A drill consists of the folloUr.'!.ng parts and structural components (Figure 1): Fit, Parts and structural components of a twi.st drill. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R0001 00240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 ~.~ cu~;ting part [ t,hc chisel ed~~ei y y2 P L .~- workings paxt, ~- G c ~, ~- shank 'length.; e ? tang; alibrata.ng par t; l~ ..~ . neck .., ~ t_hand} l .. ald.ing part; k helical flue (T'i~~litl~and or lef e .. h '? o on - margin; web; b cutting edge (tw ~. brata.ng edge (two on stray-ght taper shank drills); c ~nk drills); a wW transverse edge (one at drill po. ), sha s back (relievers.) surfaces ~... Front surface ~ of a drill are? (a) the The basic stxuctuTal elements edge (b) the direction of the helical cll~ set. ~ , _ ~ [ FL ;awing ; cutting par flute ` (d.) the cutting edge angles, ~'1.ute; (c ) the shape of the (e) the fax.rn of back (relieved) surface; (f) the back taper~ (g) the holding parts i rocess of cutting, The cut,tinF; par, li~ is bds if~ in the p cutting companents of the dr111 m Since it contains all the acts as a guide in the process of The ca1.~.brat~-ng part ac, allowance for the reshaxpenir~g -' cutting and is also the surplus ' mar ins are the cal ibrat~ing edgesg oa the drill ? At a. is J.tip g Which. determine the final formata.on of the drill hale Fe 2), the double angle in plan Angle 2 ~ (see g the ~SUred in plans has a great effect upon t~h.e po~.n ~, angle men ,. selected in re7.ati0n to the metal It is work Of the drill. It ~.~ machined, as indicated iii Table 1. ., angle and helical f ~.utc rake angle. . Fib, Cutting edge Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Section ab  Declassified n Part - Sanitized Copy Approved for Release 2012/03/20 TABLE 1 u.r......rM+nwn+~wwnwwrurrw.n+.w.~M~MYMw~.4eMOr.Nrouexv!1MltwlMWwYN'WA(O1MlI.A1id~11.HtaMdb~:Eiwl~A_Y_N.FWU:Vi.IM'MM%:;i~Y'1WNl'N,i:'~'Y,+^?~in}Hy angle 'W (see Figure 2) is in close relation to the front 1e. 1Jith W increased., the front angle becomes increased, ang the cuttthg is facilitated, with a decrease in torque and axial pressure, and an improved outflow of chip from the flutes. However, with he increase in angle C) , he cutting edge of the dri11 is weakened. This weakening, in the presence of the same value for angle ~O , is relatively greater in the case of small drills than in the case of large ones. Therefore, small drills for universal use are designed with a smaller a) Steel, cast iron, hard bronzes 116 a 118 r BraSSg SGf'~: brGnzema.oo.oasa.a..ra 130 Alumirtl~m, duralunin, silumin, Material to be machined CIA-R D P82-00039 R000100240004-1 2' in degrees 1L0 r Rea copper ....a.....?..a...a?.... l25 Ebonite, celluloida..a.??e..a a 85 90 Marble and other br~..tt1e materials 80 Direction of helical` flutes The helical flute rake angle electron, babbit.. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Values of angle 2  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Drills fabricated from high-speed steel work at an accelerated cutting cycle as compared with drills oracle from carbon steel or aloe steel, therefore, angle W is to be of greater value for the former than for the latter. The values of angle for drills in universal use are furnished in Table 2 TABLE 2 Values of angle for drills in ianiversai use Fnvp?10.~1o?',JmFnop~!~"~ ~Rl!I!!RJL?"M1~A7'?1 W Eq ,.;trNk~'tM11'NW.FM' 117nM+IM"'"tVM'1!aMtMPoN!MRWyA'~W?MrM!M~M~M2~PPC!A*NII.tN;NWSA.W~w;flIwrFfd. ' Drills from carbon steel Drills from high ..speed steel. Y 4 .. ihJ'Yrh'A',4'`{;eJfrn%?N'~Z. 'J.?.HY.t^! aaV, N~:;d~~ w%tb*d1~+'.i G a. .. w+w~+.urwuM+nuwue~n~uamrT~trtxeFtF~mt^. t~R(dlMMw~ra~M~++w.a,N'"+%a?fM1UiulN.lw.a;NCt43t;4vK~f arntl w y Drill diameters , W S' diameters ~~ millimeters in degrees in millimeters in degrees in 4 r` p+'utri% . d, t ' !'p:Pn ~4t4Fwi+14*a7.1'W.?M1~;';V`6,6, ~yyArp;awvwneFSw~!lRa4+rt~YUi~31'riM~k7eR~+"' I 1.145 1.55 ~ 3Q 3ml " L00 L.2 ' 6.0 6.2 8.2 8.3 11.5 ii.6 16.0 i6.5 - 22.0 22.5 _ 33.0 33.5 35.0 355 ..o U.1.5 - 8 0 ,. a , M.t.~ WY ~ v:m+:akiF!3~FW'!RT.+O'r:t%CX'G.;~Y9".a'^,~'!tFFS%~",~(NtY'~5'a!v'r'~!AMPs~.q~,k..idiftGliroRn'x,~mt a4'~jSi~~r"i!4iJ.N~Y!Wh~r t 22 0.25 ? 1,0 19 ~C 23 1.05 m l?5 20 232L. 1.55 3.0 2022 25 :i 6.? f. 22 26 6.8 to a 0 21~ 10`.1 17.0 25 27 6 28 17.5 28.0 26 t 29 28.5 3900 ;? 27 iyl d r 30 39?5 ?80 28 31 T; 3132 32 33 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 CIA-R D P82-00039 R000100240004-1 The selection of angle W` :1s made in re1atjon to the type of material being machinedo This is of a 1-? p r ,~.,,u1,ar im- portance in the case of special drills. Angle CL) (in degrees) in special drills for the machining of brass soft bronzes ebonite, Bakelite, and celluloid is 8 - 12 degrees, for the machining of marble and other brittle materials ~- 10 = l degree,, for red copper and aiuminur,? ? 3 5 . 45 degrees, with lower values for small drills and higher values for large drills. gist drills are usually made for right-hand cutting with a right-hand direction of the flutes, Drills with a lef t~hand direction of the flutes are used rarely, main/ for work on automatic lathes. 5ha e of the flute The profile of th.e drill flute must conform with. rigid specifications. It must provide for: (a) strength of the drill; (b) rational dis tribu~;ior~ . of metal t~roughout the section to prevent cracking in heat-treatment; a (c) ample space for chip dis ositian? p , (d) t,he correct formation'., of chip upon the cutting edge and, its easy outflow from the flute, The basic components of the flute profile are the thickness of the drill web, the width of the flute the for of the cutting edge and the blending curves, The diameter of the web do (see Figure 2) is selected, in relation to the size of the drill. In order to attain a higher degree of strength, the web diameter for small drills is 6 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 made relatively greater than for large dri11s. For drillrelatively gzea~ a diameter of 0oc _ 1.2 millimeters, ...the web diameter e dual. s (O28 + 0.20)D; for drills _th a diameter of 1oS M, 12 mina. o w~ meters, the web diameter is (0a19 ~ 0415)D; for drills. with a diameter of 13 80 ml i llirrieters, the web diameter is (Q.iL~ ? 0.125)D, where D ~. 's the drill diameter. Drills made from high' ounof a high degree of decarbonization in speed steel., on acc the he a t tr eat men , must have their flutes ground. By the the web diameter for high?epeed chills, of a virtue of this, to 18 ndilii..meters, before grinding, will be d.iamc;ter D = 0.2~ er gre?.ter than the web diameter of carbon 0 03 M () 20 mi11 lme , t ti, .. ? For driLL sizes in excess of 18 millimeters no steel drills allowance for grinding is necessary the drill, the web diameter is increased. To strengthen in the d:>rrection1 of the shanke %n the case of carbon steel ax y1..1s, the th.ickeniz1; of the web equals l.~ millim.eters, and f or high -sf>e ed dx ills , 1.75 millimeters per each 100 miilimeters of lengths e zdth of the flute is usually equal to the width '~_ of the lip. For hhaspeE;d steel drills, it should be some- what wider than the width of the lip (let us say, by 1/128 of the outside diameter of the drill). The cutting edge of the drill may be rectilinear, Con ,ave. As yet, no preference has been established. vex or concave, - At present, all our domestic plants and first-rate firms abroad fabricate drills with rectilinear cutting edgeso Declassified in Part - Sanitized Copy Approved for Release 2012/03/20: CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 To avoid cracking in heat treatment and to facilitate the chip outflow, the flute profile is to have well rounded curves (see page 327 for the description of the profile-milling cutters, with the aid of which this is accomplished)* Drill angles. The cutting edge angles may be considered as the grinding angles of the dr7_ll and also in the process of cutting Front rake angle is the angle between the plane tangent to the front surface at the contemplated point of the cutting edge, and a plane normal, at the same point, to the surface of rotation of the cutting edge about the drill axis. c 5c e 1 h /V t/ ' [Drawl.ngl / Fiore 3? Drill cutting edge angles. [Drawin Fure ~. Front rake angle at any point of cutting edge. 'i'o determine the front rake angle, it is necessary to visualize the main intersecting plane, in which it is subject Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 C . ~yz ~v ros~t4.. here C ; r) is the distance of the contemplated R point X from the drib. axis; R is the outside diameter of drill; is the angle formed by radius rx with. the axis of sylr~metry of the transverse section of the drill. The thickness of the connector characterized by the angle / insignificant effect upon the angle /{ exerts an Disregarding it, we may use the following approJ{amated formula to cbange. Plane NN (see Figure 3), normal to cutting edge ( N)' is accepted as such a plane. The front rake angle at any point X of the cutting edge (see Figure 1 9 analyzed in the plane NN, is determined by L~, formula to ?i, a) SrrJ It follows from the formula that the front rake angle s which depends on the ratio between C = rx and angles R and edge even for the same diameter of drill, sharpened to a definite to angle 9 The maXlmtlm (positive) value of angle 3.s at a point is not uniform along the entire length of the cutting Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 . Z2  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 on the periphery ui the drill, arid the minimum (negative) value is in the transverse cutting edge section ab (see Figure 2). The sharply varying front rake angle is a considerable organic defect in the design of the twist dr. i.lla It causes the non- uniform and rapid wear of the cutting edges At the periphery of the drill, where the greatest cutting speed takes place, the maximum amount of heat is liberated, and, due to the small angle of taper, it cannot be eliminated rapidly, causing the maximum wear to develop where the transition from taper to cylinder occurs. plane tangent to the back surface at the contemplated point of the cutting edge and a plane which is tangent at the same point to a surface generated by the rotation of the cutting edge about the drill axis. According to the prevailing standard. definitions, the back angle, similarly to the front angle, is measured in the plane NN (see Figur 3 ) normal to the cutting edge The main plane of intersection for the back angle is plane 00, directed' along the .drill axis arid tangent to the cylindrical surface which is generated by the contprnplated point in the rotation of the cutting edge about the drill axi..s. The ratio between the values of angles and in the planes NN and 00, for a paint at the drill periphery, may be expressed by the approximated formula (disregarding the .w thicatness of the webs: Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 The back relief angle O'- is the angle between a  Declassified n Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 ta?2.. CYN -- Z72 _ CMG 5?/ii? 9 In order to attain a more or le ss uniform angle of taper throughout the cutting edges and also to provide for the adequate value of the back angle in the process of cutting, it becomes necessary for the back relief angle to be variable also. At the periphery, its value is accepted as 8 -JJ degrees, at the web -- as 20 p 2 degrees, depending on the drill diameter Sma:l.isize drills have greater values of the back relief angle at the periphery than larger'-size drills0 Cutting edge angles in the process of cuttingo Taro motions tike place in drilling: rotary (the cutting speed) and forward (the feed). As a result of these motions, each point of the cutting edge is shifted along a helical line at a pitch equal to the value of the feed per one revolution. The. helical surface generated in the process of cutting by the cutting edge is the cutting surface, and the plane tangent to it is the cutting plane. Figure `depicts the cross section of the drill by a plane normal to the cutting edge and the evolution of the helical line the trajectory of point A per one revolution of the driliA C Dr awi ng Cutt.ng edge angles of drill in the process of cutting. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 CIA-RDP82-00039R0001 00240004-1 fez n t~N -fan as sin, In order to attain a more or less uniform angle of taper throughout the cutting edges and also to provide for the adequate va7.ue of the back angle in the process of cutting, it becomes necessary for the back relief angle to be variable also. At the periphery, its value is accepted as 8 - l- degrees, at the web -- as 20 2 degrees, depending on the drill diarnetern Smallsize drills have greater values of the back relief angle at the periphery than lar. ger~size drillso CUtfi,i.n ~ed angi.es in the process of cuttingo Two motions take place in drilling rotary (the cutting speed) and forward (the feed). As a result of these motions, each point of the cutting edge is shifted along a helical line at a pitch equal to the value of the, feed per one revolution. The helical surface generated in the process of cutting by the cutting edge is the cutting surface, and the plane tangent to it is the cutting plane. Figure S depicts the cross section of the drill by a plane normal to the cutting edge and the evolution of the helical line the trajectory of point A per one revolution of the drill. C Drawing, Cutting edge angles of drill in the process of cutting. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 P :is the evolved length' of the circurnf erence 7Y D; pw is the value of feed per one revolution; Ali is the cutting trajectory (the evolved helical line generated by point A) ; AN is tile normal to the cutting trajectory; Q , )2 are the back relief and front rake angles, respectively, of the drill bit; c'.r , y~r are t}ie respective cutting angles; & is the angle of inclination of the cutting trajectory (the angle between the actual trajectory of cutting and the conditional tra jec Cory, .~bich is the circumference described by the rotation of the dr:LU1.. without; the feeding motion) The front cutting angle d?r is the angle between a plane tangent to the front surface a t the contemplated point o..1 ?t;he cut Li np; cclz~e, and a plane no:hmaa to the cutting edge at; the sae point. '1'k1e back cutt:u7g angle (fir. is the angle between a plane tangent to the back surface at the contemplated point of the cutting edge, and the cutting plane at the same point. Both these angles are to be measured in the main plane 555 ot intersection. The ratio between, , Gt and , J is expressed as follows: 1 &; Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Angle r; is determined by formula S d In the presence of uniform feed. and reduce, value of D, that is, with the points of the cutting edge moving away from the drill periphery toward the drill web, angle & is increased0 r1his is one of the reasons for the selection of a variable back relief angle- m Bank surface forma To provide for a variable back relief angle, twist drills undergo special sharpening rIC index for correct drill sharpening is the strict adherence to the following requisite values: (1) of the drill bit angle (2) oi' the transverse cutting edge angle ; (3) of the back relief angle.. for points at the drill periphery and at the drill web. In, addition, the cutt ng edges, longitudinally, are ' to be of the same length and have equal angles , and the drill axis is to pass through the center of the transverse cutting edge [the chisel edge] . The non. observance of the symmetry of the cutting edges will result in their non-uniform (oneu?sided) loading and excessive free play of the drill, which :in turn will result in a drill hole of excessive diameter. The transverse cutting edge [ chisel edge] Wan;le Z (see Figure 2) in properly 'sharpened drills is equal to L7 50 degrees for up to 12.mi1limeter drills and 52 S~ degrees Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 for drills of l2~mi11imeter? diameter and above, The slarpening of drills may be ~ done along the helical or conical surfacer The most widespread drill sharpening machines operate on the second principled Both these tes of drill sharpening; are presenter) diagrarnmaticall Figiue 6, which merits special attention, since it .represents the drill sharpening done on machines of domestic makes as well as machines irnported from abroado [ Drag ng] Fi uTe 6m Drill!.. sharpening; diagramed he back relief angles are to be determined in relation not only to the drill- diameter, but also to the type . y pe of mah ,,.r~a,l machined This is related to a definite setup in the dhil;l~ sharpening machines To set up the ~,? p ~l-l sharpening machine as per Figure 6, (a) it is necessary to know the double angle 2 O for the conical surface, distance a from the cane apex to the drill. axis, and (b), the value o: f the displacement of the cone axis from the drill axiso These values are in r.elat:l.oi~ to the drill bit angle 2 : the chisel edge angle and the back relief angle m The correl.atiansl~ips between them are expressed by the following for~nula s fad n ( f 4) C9/( x zJ \d Jtr /k'\2 CCs ) () lJ ~ b Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 '-2 ac:)-  Declassified n Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 O, s(J)4*__ [c5(d) 1z] 4 = fan.(6t2P) -zMn..(~t~)T-~d~ dilere is the angle between radius rx of an arbitrarily chosen point of the cutting edge and the axis of symmetry of the drill (for a point lying in the web of the drill angle ,J' is transformed into ); 2 is the apex angle of the generating cone; S W 90O , where 2 is the drill bit angle; Q` is the back relief angle at an arbitrary point of the cutting edge, which point lies on the cylinder surface of radius rx. It is derived by evolving the cylinder surface of radius rinto a flat surface,, as the angle between the straight line of intersection of the cylinder with the drill bit cone (2 C' ) and a line tangent to the intersection curve of the same cylinder with the generating cone of sharpening drill against the working surface and the liberation of heat attendant upon it, the lip of the drill is depressed along its entire length, with the exception of a small margin left at the cutting edge. This margin is basically designed for gliding the drill in the process of cutting. The width of the margin is to be held to a minimum, otherwise excessive friction will develop between the margin and the work surface. The 1s Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 The margin. In order to reduce the friction of the  t Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 intermediate part (the angle) between the drill bit cone and the calibrating part of the drill is under maximtui stress, dun to the maximum cutting speed at the drill periphery and the maximum liberatLon of heat then. ea The intermediate part, as the weakest part of the drill, cannot provide for the proper elimination of heat~ As a small particles of the metal being drilled become brazed onto the margin at the above men ti.oned intermed:Late ang:te, causing thereby a further increase in friction and in liberation of heat. This leads to the rapid wear and d:Lsintegra-t,ion of the intermediate part of the drill. The recommended values for the margin are given in Table 3. Drills having a diameter of 0.2S ? 0.5 millimeters are made without a margin. The margin values inci.cated in rr'able 3 are in effect for originally fabricated drills. In milling, the width of the margin is to be reduced, since it increases after grinding along the diameter. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R0001 00240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 o drillin. mm a M~ Y I -- J-- ;-....-.:.r_:ro w-..7:.sx.:.?r~?x.u.n,:arv. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Mar in valies F J z 1 5 b' s i d l-i J 0.08 I X098 ~ o.lo ~ 0.10 ~ 0.15 t ? F S  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Back taper. For smoother operation (reduction of friction and heat), the drill. is made with a back taper in the calibrating part, that is, the diameter of the drill bit at the shank is smaller than the diameter at the cutting parts The value of the taper per each 100 millimeters of length is to be within the following range Drill diameter Taper in mm in min 1 ~6 0,03 00()L 6 18 O s O5 .. 0.06 18 -80 0.07 0.10 In the case of straight-shank 12Mmiilimeter drills, the back taper runs the full length of the drills The reduction in the drill' diameter resulting from subsequent resharpenings does not perceptibly affect the size of the drill hole, since it is compensated by the free play of the drill In continuous operation, the drill may lose its back taper on account of the excessive wear in the margin. This occurs very frequently in low-alloy highspeed steel drills. To avoid furthexwear and possible jamming, such drills are to have their back taper restored. The holding art ofthe ' shank. Drills are made either with straight shank (diameter shank (diameter ;- millimeters). SDI 18 M 20 millimeters) or tapered Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified S traigh t'shank drills up to 6 millimeters in diameter may also be made on reverse centersa In order to avoid the ti~.rning of the drill in the chuck or the drill holder in highspeed operations, the straight shank has a flattened rectangular end. to fit the driving slot. Taper shank drills are made with a Morse taper. The moment of torque being generated in the process of drilling is to be relayed by the taper exclusively, without the participa- tion or the tang, the purpose of which is only to force the drill out from the tapered sleeve of the spindle. `fl e taper shank (see Figure 7 ) must be designed so as to sustain the full torque M, which is determined by formula 1- n Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 .p Q pfd F ('J'- :2 2 Li where / 0.096 is the coefficient of friction occurring between the surfaces of the sleeve and the tapered shank under the effect of the axia:L force Q; 5'-" is one half of the apex angle of the cone; D and d are the maximum and minimum diameters of the working part of the shank taper. The axial force Q may be resolved into P and V, it being the case that force P induces on the surface of the drill body a friction force P The term enclosed in parentheses accounts for.. the error in the angle of taped" (on condition that the total error in the tapers of the sleeve and the shank Li ( is not in excess of 10 minutes, i t may be accepted for l Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified n Part- Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 manufactured drills as manut'es, that is, a total error of ? minutes [Drawing] lure 7. Forces acting upon the drill taper. There is a constant ratio between M and Q in relation to the material being rnachineda M C.oL.p) occurs in the case of soft steele Considering the possibility of the occurrence of unfavorable circumstances (accelerated deflections in angle the drill, jamming of the chap, and the like), we may accept, for purposes of computation, a three fold increase in the value of the ratio M Q Substituting the values for M into the formula, the rnaximum diameter of the drill, corresponding to each number of Morse taper, can be determined. It must be noted, that the maximum computed diameter of drills does not coincide with the established standards. In a coincidence of unfavorable circumstances, not only the taper shank, but also the tang may participate in the relaying of the torque. This is the usual cause for the breaking of the tang. 1tJith this in mind, the All?wUnion Committee on Standards pub - lished an additional standard, GOS T 889 -~ 14 for drills with accelerated taper to be used in Yeavyduty- operation. 2'minutes, for sleeves as ? 3 The most unfavorable ratio , excessive blunting of Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Pro Tess in drill `des ;n. A twist drill ` of conventional design is not a perfect. tool, Its substantia l defect. is, first of all, the sharp variation of the front rake angle throughout the entire length of the cutting edges Suggestions for the improvement in the front rake angle design of the twist drill are, at best, compromise proposals, The maximum stressed (by work load sustained and heat to be eliminated) area of the drill is its intermediate part , where the tapered. shape blends into the cylindra_cal shape. This is the weakest area by reason of the excessive value of the front rake angle, To decrease the value of this angle , a special recess is made during the sharpening of the front SU?face. The drill is rude with a greater angle of inclinatio. n and a helical flute of special design, as shown in leigLune 8 by the continuou line FPB1, in place of the usual flute as shown by the dotted line AFA1, [ Drawing '~ ure 8, Drill with recess made in the sharpening of the front surface. ; Z 2e 2 -~. E. ~a.:c a L Variation in from; rake angle in the pres ,, enc; c, of special. recess in the front surfaced Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Special milling cutters are used in the fabrication of such drills 0 For the equalization of the front angle, the front surface at the drill periphery is additionally recessed out in sharpening. Area BP (crossa-hatched surface in Figure 8) is ground off until it coincides with the rectilinear area APo The front rake angle remains constant from A to P, and only at point P does it begin to decrease in a direction toward the web? The variation in angle 1 (a) for the conventional drill, and (b) for the drill with specially recessed front surface, is presented graphically in Figure 9. Some improvement, with relation to the wear of the drill, may be obtained by removing the slight bevel in the front surface along the cutting edge. 'he bevel usually varies in width. At the periphery of the drill it is at its widest, equalling half the feed value, and is gradually reduced to zero in the direction of the web. The increase in the front _rake `angle at th.e web is obtained by recessing of the transverse edge and. its simuL. taneous shortening. The transverse cutting edge, due to the excessive cutting angle 9C~? t ,.> ~ ~. 72 (see Figure 2), works under heavy stress. It does not, cut, but scrapes the material. It was es tablished experimentally that about 6~ percent of the force of feed and about l~ percent of the torque is sustained by the transverse cutting edge [chisel edged of the drill. With it recess-sharpenin1;, the axial cutting force is decreased, and the process of c1ii.p formation improved. The recess~sharpenjnr of the chisel edge is particu~ Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 l a:rly necessary in the case of worn-off drills,' the web of which is considerably thickened toward the shank, and in the case of large-size drills. [Drawing] Figure 1G. Recess-sharpening of the chie;el edge of drill. The recommended recess-sharpening of the chisel edge :is depicted in Figure 1.O To the left and to the right of the chisel edge, metal is removed so that recesses are formed. These recesses, in intersecting the back surface, form, in plan, straight lines; which are a continuation of the cutting edge from A to D. With this time of sharpening, the value of the front rake angle in the chisel edge zone is increased, wi th the chisel edge either foreshortened or left intact, as the case may be. Recess-snarpenin.g does not weaken the chisel edge. I. t is done after each regular sharpening of the drill, or, at least, after two or three regular sharpenings. 'the length of the chisel edge after recess-Sharpening, for drill sizes of from l2 to 80 millimeters, is accepted within the range 15 7. millimeters, and the length of the recess-sharpening along the drill., within the range 3 a l miliimeter s The detrimental effect of the chisel edge may be elimi- nated by cutting out a groove at the drill point perpendicular to the direction of the cutting edges. The cutting out is done by a grinding disk of a diameter not to exceed i.5 millimeters. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  cutting speed, particularly when dr. i11in; in cast iron, it is Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 in order to increase the durability of the drill and the recornmended that the drill be sharpened to a double angle ( see Figure :Ll_ ) : the conventional sharpening to 2 9 = 116 118 degrees; and an additional sharpening to 2 w 70 7 degreesa nIhe width of the edge is made to be from Udi8 to U.22 of the drill d.iarneter~ The higher durability of the drill ob~ tairled. in this manner is clue to an improvement in chip formation (a thinner and ender chip) and to an improved heat elimination. Double sharpening i ~ reconinierid.ed for drills having a diameter in excess of 10 w 12 miliimeterse For small size drills it is not; effective. [ Drawing] Figlzre ii. Double-sharpening of drill. To decrease the detrimental effect of to cylirdrica:L margin, it is recommended that it be relieved at the cutting part for a length l= 145 - L. millimeters, in the case of l?_ - 80 m:i_l.l.ime:te.r. dril.l.s (see Figure 12)a The relievi.nL; of ` ~`~ , the margin i.s d.orle to an angle (- = 6 B degrees, leaving fal~t: a slight bevel f within the range of 0.1 0.3 millimeters. G Drawing] Section AB Fevre l2. 'lie relieving of the margin,.. 2L. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 To cirt ec!,owri wear, the small intermediate angles where the taper ends and the cylinder begins 'should be curved out in the strip AB -- 5 - 6 millimeters long (see Figure 13). The radius of this curvature, in relation to the diameter of the drill, i s to be within the range C.~ ' 1.2 millimeters. View along arrow C [ Drawing] I ___ . Rounding out the angles in order to facilitate cutting, particularly in he 90 degrees, a pointed drill works under more difficult cond .ti.ons' than a twist c?rill. To render angle ~S more favorable, the front surface is re- cessed so that` 0. When the recess is deep, the blade is weakened, and the general strength of the drill is diminished. The back relief angle is selected within the range of 10 - 20 degrees, it being the case that for drilling in ductile and Section CT) Pointed drill's. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 CIA-R D P82-00039 R000100240004-1 Drawing St a vht-flute drills are used for the drilling of holes in thin sheets of ductile metal, such as brass4 In contradistinction to twist drills, the screwing in and jamming effect of the drill in the hole is absent. Their cutting elements' are selected in the same manner as for twist drills. Their shortcoming consists in the fact that, like pointed drills, their cutting angle is greater than 90 degrees, which handicaps the work of the drill. Drills with hard-alto roped blades. Due to the physical properties of hard alloys, these drills have only limited application. They are suitable for drilling in materials that do not require high values for the front rake angle, such as cast iron (particularly in 'the presence of casting skint), hard steels, plastic masses, ebonite, bake lice, glass, and the like, and also in those cases when the feed values for hard alloy tools and high-speed steel tools are fairly equal. In this case, the productivity of the machine tool is increased due to the utilization of higher cutting speeds, as, for example, in the machining of light alloys, cast iron, etc., in high-speed machines. Due to the low strength of the hard alloy-tipped blade and the necessary presence of considerable cutting angles, it becomes necessary. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 to forego the utilization of hard alloys in the drilling of ductile metals (such as steels with o < 100 kilograms per square millimeter). Drills with hardwai1ey~.tipped` blades are made in sizes ranging from 3 to 0 millimeters, it being the case that in small-size drills (up to 8 millimeters), in place of a com- plete brazed-in blade, a cutting hard-alloy insert is butt. brazed to the holder. The diameter of the holder is made smaller by 0.3 - oa5 millimeter than the diameter of the inp sect. Hard-.alloy~tipped drills must comply with rigid speci- fications as to strength, reliability, simplicity of blade bracing, and rigidity of the entire structure. The drill is to resist well the cutting force and is not to show any yielding during its work. The vibration in the drill is the basic cause for the chipping of the blade. Due to the weak- ness of the drill point and the drill web,' twist drills are not very amenable to hard alloy tippling. To reinforce the drill, it becomes necessary to enlarge the web and to thicken it'. The length of the hard-alloy tipped drill bit is made smaller as compared with conventional drills, since they can be utilized only (resharpening stock) in a length equal to that of the hard-alloy blade. The smaller length of the drill bit results in a smaller degree of yield.ing during the drilling operation. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 tins part of the drill holder, drills designed for the machining of part-icu1ar1Y hard materials are made from i:i hardened high-speed steel. In other cases, the material for the drill holder can be alloy- or high-carbon steelo The design of the drill varies in relation to the designation of the drill (type of material to be machined, depth of drilling) e In the drilling of ,hallow holes, the direction of the flutes has no inportant bearing on the chip outflow. The , flutes may even be straights For deep-hole drilling, drills wLth helical flutes must be used. The angle of inclinap Lion is selected in relation to the material machined, being 10 - l~ degrees in the case of hard materials giving an overflow chip (Figure 25, a) and 5~ - 60 degrees in the case of brittle materials giving 'a spailing chip (r'ig?e 2~, b). As can be seen rom Figure 2~, b, the calibrating part of the f drill ac t s as a screw conveyor for leading out the chip format Angle 2 for the cutting pant of the drill, ~.ons e materials giving an overflow chip, is selected in the case of at 12~ M 130 degrees, and, in the case of materials giving a sppalling chip, at 116 - 118 degrees. To avoid weakening, the front surface of the blade is sharpened to a small front rake angle within the range of 0 - 3 degrees for materials giving an overflow chip, and, within the range of 1~ p 7 degrees for materials giving a palling chip. Table 6 cites the data on the selection' of angles 27 and 7 in relation to various Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 materials to be machines.. Blade Blade ,iure 2 Drills with hard-alloy blades. Cast iron HB = 200 . HR = 300 X00 Steel castings, stainless steel, chromium nickel steel O~ = l40 kilograms per square lnillime ter . . . . . . . ? . . ? . ? ? . ? ? ganese steel .. ? Malleable iron Phosphor bronze Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Material to be machined in degrees TABLE 6 Data for the selection of angles 2 and for various materials  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 The transverse cutting edge [the chisel edge. should be sharpened. The back taper, for the length of the blade, is selected within the range of 0.03 0.05 millimeters. To facilitate the flow of the chip, the flute surfaces must be well burnished. drilling to a depth exceeding the diameter of the drill 5 or more times. There is contlnuous and radial drilling. In the latter case, not all the metal is forraed. into chip a bar remains in the center of the :blank. This bar is re- moved, depending on its size, by breaking off or undercutting. The machining is done in a boring lathe, usually, with rotating work and forward motion of tool, and, less frequently, with both rotating work and rotating tool. Specifications for deep bole drilling are as follows. the drill-hole axis is to run true to a straight line; the drill hole is to be concentric in relation to the external surfaces; the drill hole is: to run cylindrically true throughout its entire length; the degree of finish and precision is to run within the range of OST second and third class. Deep?hole drills run in size within the range of 6 - 100 millimeters, and their various designs are stipulated by the various sizes and specifications of the work. Ordnance drill. An ordnance drill is a cylindrical bar Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 sheared off approximately to half its diameter (Figure 26). To avoid jamming, the front surface is made higher than the center by the value f = 0.2 + 0.5 millimeters, depending on  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 the size of the drill. The main cutting edge is at a right angle to the drill axis, and the auxiliary cutting edge is sheared off at an angle of 10 degrees. At its beginning, it is set off from the drill axis by 0?S millimeter. The drill point is chamfered to a radius of 1 p 1?5 millimeters. Along the entire length of the drill bit, a strip is sheared off at an angle of. 30 '- L5 degrees. The back relief angle is equal to 8 a 10 degrees The back taper is accepted within the range of 0.03 Oa05 millimeters per 100 millimeters of length. Sometimes the drill is made with a recess' in the front surface (see section NN). Section NN drill resembles a boring cutter, and must, therefore, be placed in a jig, or begin its work from a preliminarily rough drilled hole in order to provide an adequate bearing surface, The drill operates under difficult conditions due to the large cutting angle (90 degrees), to the difficulties in the egress of the chip and in the admission of coolant, Another defect of the ordnance drill is the non--warranty of the true geometric axis of the drill hole due to the drift of the drill a Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 [ the bit], 60 i~O millimeters long, made from highspeed steel, and the clamping part, made from carbon steel, the end of which is inserted into a s:Leeve for .fitting into the chuck. The bit is eauipped with a round or sickle-shaped hole (with an angle of 130 - 11O degrees) for the admission to the cutting edge of the coolant mixture (Figure 27). On its return, the coolant liquid, together with the chip, flows out along the flute. ? The flute angle plays an important part. Due to the great drilling depth, the drill sustains longitudinal bending and twisting, stresses, which necessitates a provision' for the adequate rigidity of the holder, particularly when drilling to small diameters. Angle ( also stipulates the dimensions of the flutes, along which the feeding and the leading-'oi1' of the coolant and the chip take place. With a decrease in the value of angle 'J , the rigidity of the holder and the velocity tension are increased, with the attendant increase in the friction of the chip 2gainst the flute surfaces and the danger of the chip becoming wedged in the flute. It is recommended that angle ) be kept within the range of 100 ~- 120 degrees. Section AR Section CD Figure 27. Rifle drill. `The drill has one cutting edge, consisting of two parts: external and internal. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 To guide the drill and to facilitate its penetration'. d ' e ; about the drill of the metal,' the drill point is displac ' axis by the distance b (see Figure 28) This displacement "n forms a taper (see Figure'29, a), which acts as a bearing for the drill, providing a guide in the cutting process. The value of displacement b has a considerable effect upon the work of the drill (upon its drift, its durability, the finish of the machined.surface, and the like), and it is to be in relaw tion'to the drill design and sharpening, and also to the characteristics of the work material. Usually, b = a = O 25D (drill diameter). It is, however' better to select the value of b as smaller than the value of a (such as b = O.21J; a Oe3U), and angle ) as less than angle (such as ~0 degrees and : 70 degrees). Under these conditions, the calibrating edge, having a bevel f, will sustain a mini mum of pressure, since the cutting .force component which is perpendicular to the.drill axis will be of a greater value for edge N :than for edge W (PN > P 1 in Figure 28).. Declassified in Part - Sanitized Axis of cone apex Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R0001 00240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 CIA-R D P82-00039 R000100240004-1 The calibrating` bevel cannot' penetrate the work metal, and merely removes the combings. This prevents tl.iie drift of the drill and the excessive widening of the drill hole, and also increases its durability. A somewhat increased. pressure toward the side opposite to bevel f is sustained by the cylindrical surface of the drill body or by the solid guide bevel0 To reduce friction, the drill bit is made with a back taper within the range of OolO Oe3O millimeters per lO0 s millimeters of running length in the case of S - 40 milli I, , II r1 meter drillso To reduce the contact surface and increase the effect of the coolant liquid, strips vdth narrow margins cut out are provided. Margin f (see Figure 27) designated for the trimming and the calibrating of the drill hole is to, be within the range of O.I. - 0.6 mUimeter.lith excessive ~f values of f, the drill has a tendency to jam. The cylindrical bearing surface must lie opposite the margin f. The remaining margins are guides, and their dimen- sions are selected by considerations of design, with due note takers of the width of the strips . he depth of the strips is usually o0l~ - O.2~ millimeters, The flute apex is to be below the center of the drill (by h O.OS = 0.18 millimeter), otherwise it will not function, and may bend, or even break. During the running of the drill, with the flute apex below the drill center, a core is formed in the center of the drill hole (see Figure 29, b). The diameter of this core is the Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Margin Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 of this core easier, its diameter must not exceed 0.03 of the drill 'hole' diameter. The front rake angle is to be kept within the range of - 8 degrees, the back relief angle on edge N -- within the range of 8 10 degrees, the back relief angle on edge W --within the range 12 a 20 degrees, the drill point angle Their height, in relation to the value of feed per one revo-? lution and to the ductility of the work metal, may be accepted as 17s, where s is the value of feed in millimeters. The chip breakers are to have undercuts at a 6 ?? 8 degree angle to provide for the corrugated form of the chip and the requisite direction of its egress. Margin Figure 30, Hardwallo J-tiPped rifle drill. Hard-alloy tip Experience is available in the use of hard-alloy-tipped rifle drills of a 7p~ 13 mi1li7heter diameter( see Figure 30). A. hard''ai1oy adapter equipped wi th a flute f oz the chip ? flow and an angular catch is brazed with its face to a short carbonM steel holder, which, in turn, is brazed onto the basic tube.  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 CIA-R D P82-00039 R000100240004-1 Sharpening is effected with the aid 'of a diamond grinding disk mounted on a conventional drill-sharpening machined The geometric parameters of this drill bit' are presented in Figure F _ e_ 31. Deep hole drill. F. Drawings] A substantial defect of rifle drills is the presence of only one cutting edge, a circumstance which reduces its productivity. A conventional twist drill with flutes for admitt1ing coolant, although equipped with two cutting edges, does not provide for high productivity, since the drill, from time to time, must be removed from the drill hole for the removal of the accumulated chip. Figure 31 shows the con- struction of a deep-hole twist drill. In the place of twos it has four margins, which form the channels for the admission of coolant. The shank has a drilled hole communicating with the hole at the end of the helical flutes which is perpendicular Although this drill has high productivity, it does not Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 provide .1'or a good surface finish and is not free from drift. The drift is caused by the improper sharpening of the multi- blade drill and by the presence of the chisel edger The detrimental effect of the latter may be reduced or even corn- pletely eliminated by the following: (l) the drilling out (in the drill) of - a longitudinal hole, the diameter of which is to be greater than the chisel edge diameter (such a drill see Figure 32, a ? has an internal flow-off of the chip and,. in drilling, will form a core); (2) the drilling; out of a blind center hole, hidden in one of the helical flutes, with a ledge for the breaking off of the forming core, which is removed through the hole in an outward direction (Figure 32, b); (3) the substitution- of one cutting edge by two cutting edges that really cut into the work metal and do not merely crush it (Figure 32, c). Large-diameter holes, on the order of 75 millimeters. and 'above, are drilled by the method of radial drilling, with the leaving of a central core of considerable diameter.. Radial drilling is effected by a single-blade drill, or, more fre- quently, by a multi-blade type drill head. The head consists of a frame with clamped-in cutters, the number of which is selected in relation to the requisite diameter of the hole. Figure .33 shown the drill head face. Three cutters (2), wedge-braced t.), machine the metal from two sides (diameters D and d). Between' the central core and the drill head frame (1) there is a gap of 6 millimeters for the admission of coolant.. For the outflow of coolant with the chip, gap B is Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Veremeychuk,' I. Sm , 'Radial .Drilling, Mashinostroitel' (Machine Builder), no 12, 19t~O. Nemirovskiy, AQ so, nCom.puta'tion of Back Relief Angles of Drill", Trull stanko.instrumental' nova Tool Institute), volume VI, Publication S tankin, 19Li.O. Suvorov, A. I., "Deep.-Hole Drilling' Mashinostroitelt (Machine' Build.er ), No 12, 'l9Li.0 COUNTERSINKS Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA RDP82 00039R000100240004-1 provided 'between the hole/ drilled out and the drill head frame. The 'drill head is equipped with metal or wood guide cams (3). Designation and. ypes Countersinks are intended for (a) enlarging cylindrical holes previously obtained by cold or hot treatment; BIBLIOGRAPHY AND SOURCES . Aref'yev, M. G., and Ka.rpov, L. I., Profuction of Rifle Barrels, Oborongiz, 19L;.  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 (b) machining cylindrical recesses for screwheads or necks 'of screws, etc.; (c) machining conical recesses for center holes under screwheads, for valve seats, and the lake; (d) trimming of face surfaces. For the first, group of operations, the following types of countersinks are usede (l) taper-shank (CeOST V 1676 2 inserted-blade (OST 'NK1 3677) with arbors; (OST NKTP 3678 (3) sectional- adjustable inserted blade (GOST 2255 For the second group of operations, the. following types of countersinks are used.: (1) with pin for enlarging cylindrical screwhead holes; (2) with pin for enlarging holes for screw necks. For the ttird group of operations, countersinks known ;ij as countersinlt reamers are used (1) 60 degree included' angle plain centering (OST 3728); (2) 60 degree included angle for center holes without a safety cone (OST 3729 combined with OS T 3730); (3) 60 degree included angle for centering with taper shank (OST 3731) ; (G) countersink reamers with various other included angle values (7 degrees, 90 degrees, etc.) for various opera tions For the fourth group of operations, spot-facing counter- sinks are used (1) with shank; (2) inserted blade, one-side and two~sid~, solid and sectional. Declassified in Part !_-Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 eS and the geometz^y of cQUn~ersinks. Designate-oils, Countersinks for enlarging holes are used for holes to be ' finished to thefourth to fifth classes of precision and for holes to be reamed to the second to third classes of precision. The external diameter. of the countersink is selected to con ' th the requisite stock allowance- for ;, w s- farm with the above - reaming taken into account. A countersank consists of the following parts an ' l ~ the bit; 11 -the cutting ~-guxe 3 design elements (Figure 3L) , ~ par?b; 12 ? the librating part; 13 the neck; i - the ca . d .. the arbor fitting hole; k the flute shank; e a the ?tang, 'th ri ht?hand or left-hand direction); (straight or helical, wi g p the lip; f a the margin. The basic elemenis of design are: (a) the cutting ~. , the d~.rectlon of the flute, (c) the blade angles; pare (b)> d the margin; (e`) the back taper. F?gur ? Counter Sirlk parts and elements of designs ~. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Drawing] , where t is the thickness 'of the chip; is the Figure 36. Geometric elements of countersink, C Drawings] Figure 37. Angle of inclination of the cutting edge? of countersink. In the technological process of machining the hole, the countersink occupies an intermediate place between the drill and the reamer; The design of it is stipulated by this fact. The countersink resembles a drill, but has a greater number of lips, which provides for better guiding and a higher degree of finish in the machined surface. In contradistinction to a reamer, the countersi :. cuts by means of facing teeth, namely, by the face cutting edge m and the margin edge n (see Figure 35). The value of t cutting part angle. The value n -? ,where so is the z value of feed per one revolution and z is the number of lipso The geometry of the countersink tooth is depicted in Figure 36`; the front surface (l), along which' the chip is ejected; the back surfaces ..,, axe. main (2) facing the work surface, ' auxi- liary (3 ) a which is the cylindrical surface of the margin, touching the work surface; the main cutting edge (Li.), formed .. 5 ' n ' r~W ~'^~;t' i4l rAnS .ii 1kY fp&~ ~Y ~p~~f~ ~p ' ` ll Declassified in /. [Drawing] Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Margin on tapered part  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 by the intersection of the front and main back surf aces, and performing the basic work of cutting; the auxiliary cutting edge (S), formed by the intersection of the front surface and the auxiliary back surface (the margin)', blade point '(6), which is the point of intersection of the main and auxiliary cutting edges. To determine the cutting angles, it is necessary to know the coordinating planes ~- the basic plane and the cutting plane. The basic plane passes through the given point of the main cutting edge and the countersink axis perpendicular to its face. The cutting plane passes through the given point of the main cutting edge tangent to the surface of cutting. In analyzing the cutting angles in a static position, the cylindrical surface generated. by the rotation of the given point of the cutting edge (without feed) is considered as the surface of cuttingo The angles in plan (main and auxiliary ) are 1 included between the direction of feed and the corresponding projection of the main or auxiliary cutting edge, respectively, upon the basic plane (see Figure 35). The `cutting edge angle of inclination ,4. is included between the main cutting edge and the basic plane. It is measured in a plane passing through the given point of the Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20: CIA-RDP82-00039R000100240004-1 cutting edge normal to the basic plane. By analogy with a cutter, the cutting edge of the countersink may be designed in three variants (see Figure 37) When the point of the tooth , is below the remaining pain~, y Cs of the cutting edges angle 2. is positive (> U), when it is above, angle ~. is nega tive ( < 0), when it is at the same height, is formed by a plane tangent The .:front rake angl:, to the front surface at the given point of the cutting edges and a plane normal to the cutting plane, drawn through the .. same point The back relief angle O- is formed by a plane tangent to the back surface at the given point of the cutting edge, and the cutting plane passing through the same point. To complete the determinadan, it is necessary to establish the coordinating plane. The front rake angle and the back rely ?.ef` angle O- of the countersink are usually : specified, by analogy with UST 6698 ("Basic concepts in machining r , with cutters") 'in the main section plane normal to the projection of the cutting edge upon the basic plane ( see Figure 38)a The back relief angle can also be measured in a plane tangent to the surface of motion. Section KK Direction Fi ure 38! Cutting edge angles measured in various planes. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R0001 00240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20: CIA-RDP82-00039R000100240004-1 When designing and fabricating countersinks, it is necessary, by analogy with cutters, to operate with front rake and back relief angles measured in planes: (l) KK -- normal to the direction of feed ( ' J ); (2) LL - para~ llel to the direction of feed, tangent at the given point to the cylindrical surface generated by the rotation (without feed) of this point cutting edge ( cZr, ( ?-z'??2) (3) RR 7t)a normal to the The relationships between the front rake and back relief angles as measured in various planes are tan ? tan, ? ? tan Yz = tan Z/ tan Zi;/ = tan ? tan v2' =tan ' ? r (N. cos M tars Z ? sin s sin + tan , ? cos ' ; cos 92 + tan ' sin' ; cos 2; cot al = cot , cos Z' . tan , ? sin cot tX == cot, cx? sire + tan 2 cos cot' cot ~j ? cos 9 + 'cot ? sin' cot w cot ~ /V ? C05 2 . When operating with formulas containing ,. , it is necessary to adhere to the rule of signs for the tangents. Angle / is determined by formulas: tan 2 = tan 2` ? cos I tan sin tan 2 = cot cos - cot . . sin Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 For the determination of / -/ in the ?ace section, there is the formula tan tan 2 sin, The cutting part angle exerts a considerable effect on the form and the ejection of the chip, and is selected on the basis of experimental, data. A properly designed angle C is conducive to the proper ejection of the chip as conformant with the direction of the flute. This is of particular `im~ portance in the case of metals that give an overflow chip. In machining steel, angle 9 is taken as 60 degrees. To increase tool durability in the machining of steely the cutting edge is to be additionally sharpened at angle ) = 30 degrees, along a :Length equal to three times the value of the machining stock the side. For machining in cast iron, angle 9 is taken as 60 or )4 degrees without additional sharpening In the case of hard-alloy-tipped countersinks, angle 2 is some- times increased to 7degrees. Like a twist drill, a countersank is equipped with a helical flute. To form a positive front rake angle, the direction of the flute must coincide with the direction of cutting. In plane LL, the front rake angle , for a point on the periphery, equals the angle of inclination ( CD ) of the helical flute. Angle ) , which is linked with the front rake angle, is selected in relation to the work material 61 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 and, the countersink diameter. As the hardness of the work` material is increased and the diameter of the countersink reduced (for the strengthening of the cutting edge), angle C?) is decreased. In countersinks for universal use, it is accepted. within the range of 10 25 degrees. bracing of the blades in sectional- countersinks, it is some- force' and torque are diminished. The angle is se:Lec ted in relation to the work mater, ibility in the place of -maximum stress. _ This is of particular V't importance in the case of hard-alloy-tipped tools characterized +4 N I rt by higher brittleness. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 the case of a new countersink, the value of is to be so selected that, following all the permissible resharpenings it will still remain greater than or equal to zero. Angle in the new countersink is also to be in relation to the working height of the blade, and, generally, it is to fall within the range of l2 16 degrees There are various designs of sectional countersinks. The most successful design is the one in which the bracing of to blades is accomplished by way of riffled construction (see Figure 1~?a Section ABGD [Drawing] [ .Drawing] Section ABCD [Drawing] [Drawing] [Drawing] [Drawing] [Drawing] [Drawing Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  I Declassified n Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Let us analyze these riffled constructions. The countersink represented in Figure L.2, a,consists of a body (1) with grooves inclined about the tool axis and with wedge- shaped knives (2 ) with a p degree radial inclination angle. The body grooves and the blades are riffled so as to permit the adjusting of the diameter after blunting by shafting over one or several rifle graduations. The wedgelike shape of the blades provides for their reliable bracing in the body of the tools The defect of this design is that there is no axial hlade adjustment. Figure 42, b, shows a modified design. The blade (2) and the body groove (1) have transversely running riffles and a double inclination, degrees in a radis.1 direction and 1 degree 30 minutes in an axial direction. The countersink is provided with double control, radial and axial. The defect in this design is that the transverse` direction of the riffles does not allow the use of the broaching method in the machining of the body grooves,' requiring instead the laborious operation of slotting. Figure L2, C, shows a design consisting of a body (1) with wedge-shaped grooves inclined about the tool axis, wedges (2), and blades (3). The lateral side of the groove and the adjacent side of the blade have longitudinal riffles, while the other side of the blade and side of the wedge adjacent to the latter have transverse riffles. This design provides for double blade adjustment, axial and radial. The defects in this 68 .~ Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Declassified in Part - Sanitized  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 design are the ciosed-_n groove, which makes it impossible to use the method of broaching in the machining of the riffles, and the projection in the blade for the transverse riffle. . In the design shown in Figure L2, d, the blades (3) and wedges (2) are riffled longitudinally. Wedge (2), with a radial inclination of degrees, braces blade (3) in the body (1) by the method of tight fit. The design provides for double blade adjustment (axial and radial). The defect in the design is to complexity of machining the grooves for. the tight fit. re countersink in Figure 2Li, e 'shows an improved design as compared to the preceding one. Blades (3) and wedges (2) are longitudinally riffled. The grooves in the body (1) have a s-degree radial inclination and a 3~degree longitudinal inclination. Double blade regulation is provided for ?seC ti0nal countersinks are to satisfy the following specifications: (1) strength, reliability and rigidity in the bracing of blades in the body; (2) simplicity in fabrica- tion and the provision for adjustability of blades following reaz^; (3) provision for a normal sharpening allowance along the diameter following adjustment; (Li.) the more or less perma- nent overhang of the blade with relation to the face of the tool in resharpenings (see dimension k in Figure L3). Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Drawing Figure 430 The limit values of countersink wear (amount of stock removed by cumulative sharpenings)o In the process of machining, the countersink blade wears at the corner, or the transition area, formed by the intersection of the back surface of the cutting part and the cylindrical surface of the margin (the cross-hatched triangle with length ;A in Figure 43 The countersink wear, when working in cast iron, runs approximately at the angle Based on this, it may be recommended that the sharpening be done to an additional angle along a length of bevel determined by 0.8 ? 102 millimeters. In order to restore the cutting capacity of the counter sink, it is necessary to grind, off the blade along the back surface by Talue h, the diameter of the countersink remaining the same. in sharpening, the extent of overhang of the blade (dimension k) with relation to the face, is reduced. This would lead to inadequacies in the work of the countersink. Therefore, the feature of the bracing of the blade should be so designed as to provide for the possibility of retaining this dimension more or less unchanged. There are limit values to the amount of stock that can be removed along the axis M and along the height M1 of sectional countersinks by resharpening s. ` Grinding off of stock beyond' Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 those limit values does not any longe insure the requisite` strength and reliability in the bracing of the blades, The following sharpening stock values were established empiricall.y. where L is the length of the knife; m is the length of the angular edge, a is the depth of the recess in the front face, and s is the pitch of the riffle, The 'best' indexes 'pertaining to ` the minimum allowance for grinding and the maximum permissible number' of .. resharpen ings are given in the layout shown in Figure L2, d, which has been authorized. as standard by GOST 2253 Sectional. countersin]s with a diameter from LO to 75 millimeters are made with taper shanks. Inserted blade COUflter's:inks are made in diameters LtO to 100 mill imeters. The number of teeth in countersinks with a diame der of up to 55 millimeters is standardized as 1 a -~, nd in those s e with a diameter of above 55 millimeters, as 6. Figure 44 shows the elements of standard bracing b g by the method of riffling (GUST 2568 a LU ) , The riffle angle is 90 degrees and the riffle pitch is 0,75 1,0 millimete r9 The apexes are sheared off to form a little platform: of 0,1 M 0.2 millvneter; the riffle notches form li t t1e platforms 0.0$ 0,1 millimeters wide. The riffle thickness equals the thickness of the notch along the center line of the profile, Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 The cutting elements of sectional countersinks are determined by taking into account the work material and the countersink blade material, and also the characteristics of the countersink designo [Drawing] ~,igur:4? Standard riffling for inserted blades. Bracing'the countersink. Countersinks of standard design, from 10 to 36 millimeters in diameter, are made with taper shanks, and countersinks with a diameter of 25 milli meters and above are `made with holes for `setting into arbors. The arbors are also made with taper shanks. Shanks with Morse tapers provide for the excellent centering of the tool, resulting in diminished vibration and improved quality of the work surface. As airecult of operating wear and the removal of stock by subsequent resharpenings, only a relatively small section of the cylindrical part of the countersink sustains a reduction in length. In order to increase the number of possible resharpenings, it is recommended, in the case of end countersinks, that a hole be drilled in the face of the tool, and, in the case of inserted blade countersinks,,the length of the, front part of the tapered hole (up to the internal charnf er) be increased by ~0' percent, as compared to the length specified for standard countersinks. Such a construction ,pro- vides for the reliable bracing of the countersink in the arbor, Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 regardless. of the many resharpenings. In countersinks of standard design, there is no comp plete utilization ,of the material constituting the cylindrical part. To eliminate this defect, sectional countersinks with removable heads .are used. The removable head is set into a hardened carbon steel, or alloy steel body, which has the form. of a conventional countersink with tapered shank, The removable head, which is the cutting part of the countersink, is either solid high-speed steel or is equipped with brazed?on hard alloy t blades, Countersinks of such design are very effective in machining with control guides (for instance in aggregate machine tools) and also in the machining of deep holes. The long body of the countersink provides excellent guidance in the work. The junction of the cutting head with the body is effected by several methods. In the design shown in Figure 145, a, the head is equipped with a 'square extension, for which. a square hole is provided in the body of the countersink, with a through groove provided in the body to facilitate the ejection of the head, The head is stayed with the aid of a bolt passing through its entire length (Figure L5, b)o {Drawings] Section AB (b) Figure J45. Countersink shaft with square hole for head, 73 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 regardless of the many resharpenings. CIA-R D P82-00039 R000100240004-1 In countersinks of standard design, there is no con' plete utilization of the material constituting the cylindrical part. To eliminate this defect,' sectional countersinks with removable heads are used. The removable head is set into a hardened carbon steel or alloy steel body, which has the form of a conventional countersink with tapered shank, The removable head, which is the cutting part of the countersink, is either solid high-speed steel or is equipped with brazed-on hard alloy blades. Countersinks of such design are very effective in machining with control guides (for instance in aggregate machine tools) and also in the machining of deep holes. The long body. of the countersink provides excellent guidance in the work. The junction of the cutting head with the body is effected by several methods, n the design shown in Figure L5, a, the head is equipped with a square extension, for which a square hole is provided in the body of the countersink, with a 'through groove! provided in the body to facilitate the ejection. of the head. The head is stayed with the aid of a bolt passing through its entire length (Figure L, b)0 [Drawing S j Section' AB (b) Figure i:5 Countersink shaft with square hole for head. 73- Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Drawings G Drawings) [Drawings] Section AB Section CD Figure l.6. Countersink shaft with hexagonal hole for head, Section AB Section AB Section ABCD Figure 1i8. Countersink shaft with sheared tang (a) and with rectangular groove and securing screw (b). in place of the square, which simplifies the design. The stay bolt is screwed into a hexagonal nut, which, in turn, is in- serted into the hexagonal hole in the countersink body. The nut is prevented from falling out by a spring in the form of an unlocked ring : into the corresponding internal champ fer of the hole. To facilitate ejection, the hole is made to run` through. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Bracing, as depicted in Figure L8, is effected by two alternate methods: (1) by the tang of the shank inserted into it the corresponding recess (Figure L~8, a); (2) with the aid of' the tang of the shank, the rectangular groove at the greater diameter of taper, and the securing screw (Figure 48, b). Declassified in Part - Sanitized Copy Approved for Release 2012/03/20: CIA-RDP82-00039R000100240004-1 The bracing shown in Figure L.7 consists of a dowel pin, inserted into the holes drilled in the countersink body and the countersink head. To facilitate the ejection of the head, a spring, braced against the internal face of the head taper, is provided. Sectional countersinks are also used for the machining of shallow holes. One such design is depicted' in Figure X90 The body is Morse-tapered, while the countersink head has a straight shank with two projecting cams in the center for bayonet bracing. The head, compressing the spring, is in- serted into the body and turned in a direction opposite to the tool rotation. The cams fall into the corresponding in- ternal chamfers of the body and effect the transmission of torqued This countersink design is rather complex in fabric cation. [Drawings] Figure 1t9. Shaft with bayonet bracing. 75  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Relieved -.-.-..-- surface ; Section EE Figure 52, Double-thrust countersink with large surplus stock, Figure 50 depicts the bracing of straight-shank counter- sinks in quick-change chucksm This design is authorized as an All-Union standard (COST 3009 - L). The shank has an annular groove' (1), flan' surface (2), indicated by dimension ii, [ Drawing [Drawings] Position Drawing] [Drawing] Section BB Section DD Section AA  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 and radial groove (3)' having a width (b) - bowel pin (i ) is pressed into the body of the chuck, and a locator device, consisting of dowel (5) and annular spring (6) is provided. The countersink shaft is inserted into the chuck, in position 10 The flat surface (2) passes freely under dowel (L).; Dowel (5) under the action of spring (6) is flipped into pped xntothe annular groove (1), fixating thereby the proper location of the tool, When the machine spindle with the chuck mounted on i t rotatesi dowel ()4) enters groove 3), working motion of the countersunk (position II) a The locator device prevents the countersink from falling out and renders effective the rapid and convenient bracing of the s g hank in the chuck, At each turn of the machine spindle, the chuck dowel, entering the groove, by itself grips and guides the counter sink. This arrangement is particularly important in the case of vertical spindle machines In actual operations, both a dowel locator device (Figure 51,` a) and a ball locator device (Figure 51, b) are used. Shanks of the above described type (for 10 ~. 5o milli- meter countersinks) successfully replace the Morse gaper type of bracingo The advantages are manifested in the simplifica~ tion and rapidity of mounting and dismounting the tool, and also in a saving in material, since the shank assembi,~ of y this type is 2 ? 3 times shorter than a Morse taper shank. The defect of such bracing is that the straight shank, as comp pared to the taper shank, does not provide for better too cen? tering nor for a; higher degree 77 grips the shank, and effects the of surface finish. It can, Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 00 11  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 therefore, be recommended for work of lesser precision. The double-thrust countersink depicted in Figure 52, is braced in the arbor with the aid of two torque-transmitting dowels and a center hole. The countersink is used for the machining of through, blind, step, and profile holes, having a diameter of from 30 to 200 millimeters and a length up to Li000 millimeterso When machining in continuous material, it is frequently used in combination with a drill mounted on the arbor ahead of the countersink. The countersink is capable of removing considerable machining stock allowances, has greater productivity and durability, and permits a consider.- able number of resharpenings. The back surface of the main cutting edge, which is relieved, non-ground, with chip breaking annular grooves, has a 60 or i~ degree angle in plan. The calibrating part S cylinder-ground, or ground to a small bark relief angle (30t ,.'2? 3O). sharpening is done only alung the front surface. In contradistinction to the conventional counter sifk a double thrust countersink has a short bit without wide margins, which prevents the wedging of the chip and g _ its adherence to the tools The front rake angle is selected in relation to the work material within the range 10 - 2, degrees; the back relief angle is 8 degrees. For purposes of proper ejection of the chip, the cutting edge has an angle of inclination degrees. 78 ? 10 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 ~auntersinks for Cylindrieal Holes. To machine holes to fit cylindrical heads (Figure 3, a) or screw necks (Figure ~3, b), 'countersinks are used. These' ` not differ from each other, with the exception countersinks do of the sizes of diameters and pivot journals. In small sizes, ~. they are made with straight shanks, and in large sizes, with taper shanks. At times they are made in the inserted blade characteristic of this type of countersink formti A special is the presence of a pivot journal at the face of the bit. ' serves to guide the countersink in'operation The pivot journal and to provide for co-axiality of the countersink hole to flat the screw head and the hole to fit the screw stem. The pivot journal is made either integral with the countersink body or is replaceable. The last type is preferable, since it permits more resharpenngs, facilitates the process of sharpening, and ~. utilization of. the countersink fora group of permits the diameters by shifting from one size of journal to another. ... Figure 3. Form of cylindrical holes. CDrawing] [Drawing] (a) (b) 79 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Taper 1:50 Section AA F e51~0 Bracing replaceable pivot journal to countersink. Morse taper No 1 Section AB Section 0D . Figure 5L depicts the bracing of 'the pivotjournal to the countersink with the aid of a 'tapered section. There are other methods of bracing the journal to the countersink, as shown in Figure Li5 in the preceding text. The shaping of the countersink bit, in this case, is depicted in Figure 55. The angle of inclination of the helical flute C.L) is 10 15 degrees; the undercut at the face is 8 - 10 degrees; the back relief angle at the calibrating part _ 8 degrees; with lip 1 -' 1 0.2 millimeters. The lip has an additional taper at an angle Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 O.i: 25 - 30 degrees. The angle of inclination of the cutting edge ,L 10 degrees. For the machining of center holes, the following types f,f of countersink reamers are used: plain, single-tooth (Figure 56, a), conical twist (Figure 56, b), centering (Figure 56, c), ;`'Sad centering with safety cone (Figure 6, d). In machining centerp #` k ing holes, the most frequently used angles 2 are 60-degree` ,y angles, and less frequently 75 and 90 degrees. For the machining of conical holes, conical countersink, reamers are also used (Figure 57). They are fabricated with an angle 2 9 - 60, 75, 90, and 120 degrees, and with a diameter from 12 to 60 milli- meters. The number of teeth is selected, respectively, from 6 to 120. To facilitate the process of cutting, it is recomp mended to shear off, with skipping of one tooth, a little section of length 1 1.5 .5 millimeters. The web thick- ness at face is selected, equal to 001D, and the diameter of sheared face d ;^ (o.15 t 0.18)1J, where D is the diameter of the countersink reamer. The angle of the recess Z is in relation to the number of teeth and the angle of the tooth body , which is determined by formula where: Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  [Drawn Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 CIA-R D P82-00039 R000100240004-1 no less than 30 ~0 degrees, Upon computations angle .. is rounded out to fall in line with the conventional series of angles of angular i1ling cutters. In order to maintain the m rm along the entire length of the tooth' width of hp p _ un~.f o it is necessary to compute angle ~ of, the dividing ..head setting, r which is determined by formula is the apex angle of the countersink reamer cone; where 2 360? . 1a. is the recess angle. The width of lip p is selected within the range 0.0~ - 0.06 millimeters. The back relief angle = 6 ., 8 degrees. `rhe front surface is directed along the radius. The countersink reamers are made either with taper spank or with shank as per Figure O. ... [Drawing] Section AB  Declassified in Part Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 'Section AB Face~Tximming Co~~rsinks The peculiar characteristic off' these countersinks an the face only. Countersinks of is the presence of teeth made with hellcat teeth on the stem... this type are rarel;Y The design is insertedtooths with shank,, of the type shown . ' ~ in Figure SO, or to f?t into quickchange chucks. In the .are ro~ected frarn'a double face. The latter cases the teeth p first the second face are used -after the first teeth projeat~.ng from Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 (d) a e] des of countersank Figure ~6. [See also preceding p g reamer's. .  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 set of teeth is blunted. The teeth, particularly for machining in cast iron, are hard-alloy. To maintain coaxiali.ty of the hole and the work surface, the countersinks operate together with the pivot journals`in the same manner as screwhead counter- sinks. The pivot journals are either detachable, or integral with arbor. Bracing with arbor is effected by a screw. Popu- lar diameters for countersinks of this type are within the range 11.E - LO millimeters. Due to the heavy-duty character of the work, the number of teeth is not to exceed 2, Li., or 6. Figure 58, a, shows the cutting 'parts of this countersink, [Drawings] Section EF Section AB Section CD [Drawing] [Drawing] [Drawing] [Drawings] Figure 8. Countersink for trimming of face surfaces to fit into quick-change chuck (with cam bracing). Drawings] Figure 59. Face-trimming countersink with square bracing. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  the trimming of large surfaces are made with chip breakers arranged in chessboard fashion Special notice is to be taken of the countersink design shown in Figure 58, b suitable for the trimming of surfaces inaccessible or inconvenient to reach from above. The countersink has whole with parallel sides, and the arbor end has an irregularly shaped cross section. Such a design provides for the perpendicularity of the cutting teeth faces about the tool, axis even when there is some free play between the countersink and the arbor. Bracing of countersink to ' arbor with the aid of a screw, dowel, roller or ball, when these are present on the face which is opposite to the location of the cutting edges, is not as effective as the above described design. the arbor to fit into a square hole in the countersink ch~nlr and a thrust tapered washer abutting thecountersink. The washer has a groove in it in order to facilitate connecting with or disconnecting from arbor. sink to the arbor, with the aid of a square tip at the end of Combination Countersinks and Irregularly Shaped Countersinks. In order to combine several operations (transitions) into one, combination tools are used. A combination tool has many advantages; (1) it allows the utilization of a standard machine tool for complex machining, (2) it cuts down machining time, thereby reducing production costs, (3) it reduces checking Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 In order to facilitate machining, countersinks for Figure ~9 shows another design for bracing the counter Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 times since the precision of the work is insured by the proper tool sharpening. There are two alternate designs of a combination tool, It is either made up of tools of the same type differing only in size, or of tools of different types. Outstanding examples of the first group are step countersinks for holes with two, three, or more diameters countersink, vari..type teeth for considerable machining stock removal [Drawings] A convenient design of a two-step-countersink is shown in Figure 60. Its characteristic feature is the alternating disposition of boring and face-trimming teeth. In contradistinction to the non-alternatin -tooth des, g igns the aiternating??tooth, design provides for a considerable number Qf resharpenings. Countersinks with alternating teeth are also used successfully/ for boring holes, hen , there is considerable stock to be removed, The stock to be removed Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 is distributed between two or three groups of teeth, which are disposed on peripheral circles of various diameters (see Figure 61). Each subsequent tooth overlaps the pre ceding one. In designing the above, circumferences of the requisite diameters are. drawn. By the requisite thicknesses and height of the teeth, their central angles are determined within such a range as to require the minimum number of milling cutters for milling . thy; countersink flutes. After the flutes have been milled, the teeth are sheared off, heightwise and lengthwise, to conform with the amount of surplus stock to be removed by each group of teeth, respec- tively. Each group is usually made up of 3 -, though sometimes of only two, teeth. To improve cutting, counter- sinks are usually supplied with helical teeth having an angle of inclination &) w l5 - 20 desgrees for the largest circum- ference. It should also be remembered that angle L) assumes lower values' for the other circumferences'. Outstanding "examples of the second group are combiriaw ton tools consisting of a drill and countersink, or reamer and countersink, or boring cutters, countersink and reamer, or other combinations. Figure 62 shows combination tools for the machining of a series of surfaces and flat surfaces, which are indicated by corresponding markings on the tools and on the work. blanks. Letter O indicates a roughing pass; letter Oh, `a finishing pass, 87. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 The Geometric Parameters of Sectional Countersinks, Thesis, Moscow Machine Tool Institute, 19Li.1 No 11, 1936. Leading Data on Countersink Operation, ENINS, 195. REAMERS Designation and Types of Reamers Reamers are designed for the machining of precision holes. They are used for finish- and rough operations. In relation to specifications, reamers produce holes within a wide range of tolerances, from the fifth to the first class of precision. The correct work performed by a reamer depends on the design and quality of its fabrication, as well as on oper- ating conditions (cutting practice, cooling, the value of the stock to be, removed, the `quality of the sharpening and lapping of the cutting edges etc.)  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 (1) by the nature of their application -- hand-operated reamers (OST 2512 - 39), machine-.operated reamers (COST V 1672 1673 I.2), boiler 'reamers; (2) by the shape of the hole to be machined drical and taper (OsT `2i3 -~ 216 - 39); (3) by the manner of bracing insert reamers (4ST NKTP 3676); cylin?- ().) by the tooth design reamers with inserted teeth (GOST 883 16, ' 88La. h6, and 1S23 and roamers with teeth integral with body; (5) by the adjustability of dimensions -- adjustable reamers and non-adjustable reamers. The basic concepts, designations and terminology per- taining to reamers are established in accordance with OST NKTP Reamers wi h milled teeth4 This reamer is a cylindri- cal body with flutes for the formation of cutting edges (Figure 63). i Drawings] Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  3 degrees;` for ductile materials, such as steel, it is 12 1~ degrees. In the case of boiler reamers, it is 1.5 3 degrees. Reamers with angle 7 L5 degrees on the cutting part are very popular. Such reamers demonstrate good cutting ability and a high degree of surface finish. To insure free. entry into the hole, the smaller diameter Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 tural elements: 1 - the working part; ll CIA-RDP82-00039R0001 00240004-1 the cutting part; the calibrating part; 13 -- the cylindrical part; 1 the back taper; 1 -- the shank; 16 -- the neck; e the -- the tooth, k -~ the flute; s -w the front surface; square, z ~ ..w the back surface; a the front rake angle; 0`- -- the t back relief angle. The basic elements of reamer design are the cutting and the s,lxbratlng partss the number of teeth, the direction of c the teeth, the sharpening angles of the teeth, the pitch of the teethgm oves, the flute profile; and the holding part. The cutting (tapered) part 1 1 serves for the maxi mum removal of stock. The cone angle 9 (in degrees), which affects the durability of the reamer and the degree of finish of the work surface, is accepted, in the case of hand-operated . reamers, as0.S 1, degrees. In the case of machine-operated , ~ reamers} it is determined with relation to the work material:  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 CIA-RDP82-00039R0001 00240004-1 of the cutting 'part is made smaller than the d' xame ter of the reamer by 1.3 l.L of the stock allowance for reaming, In addition, 'a 145 w degree bevel is removed at the end of the cutting part to prevent the teeth from chipping in the presence of a heavier stock to be removed or any defects in the hole. The transition. from the cutting part g part to the calibrating part is chamfered. For the machining of light alloys, a special sharpening of the cutting part is recommended, as is done in the. case of fluteless taps. The lip an the cutting part is sheared at an 'angle of 30 degrees to the axis and the flute is co.rres-pondingly deepened at an angle of 15 dagrees. Such a shaping of the cutting part provides for a positive front rake angle up to 8 degrees. To eliminate the possibility of weakening the tool by such additional sharpening, the width of the lip is increased to compensate for the reduction in the. number of teeth, . Thy calibrating part 12 guides the reamer a. n the work, imparts precision and hlgh' finish to the... hole, and Insures the presence of resharpening stock. An increase in length 12 results in harder work for the reamer `' and in its iarnming in the hole. it is, therefore, recommends d that. in the case of short reamers the length/ 2 0.25 ? 0..3 of the ; reamer diameter. A small value of 12 saves steel and reduces the buckling of the reamer in hardening. The back` taper .J Is made for the purpose pux`p of reducing x 91 . Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 the friction between the reamer and the surface of the hole and of forestalling the splitting of the hole by the cali- brating part segment adjoining the neck. The lesser diameter of the taper (at neck) is smaller than its greater diameter by a value of O.OQ~ millimeters to zero, for hand reamers, by 0.04 0.06 millimeters, for machine-operated' reamers' and by 0.06 - 0.10 millimeters, for _oscillating reamers. Due` to the small back taper in hand reamers, they frequently have no cylindrical'segmento The reaming of par ticularly clean holes of small length (up to 20 millimeters) can be done with reamers without a back taper. The number of teeth is usually even to compensate for the error in measurement of the reamer diameter with the microM . ? ; meter, in relation to diameter D in millimeters and the reamer designation as per formula z x.1.5 + (2 i L)o For reamers with a greater number of teeth, a greater value of z is selected, since, with the increase in the number of teeth, the degree of finish becomes higher. In the case of boiler reamers, the number of teeth is selected within the range from 3 to 8, in relation to the diameters Reamers are equipped with straight' or helical teeth. Helical teeth provide for a better finish and higher durability of tool. Straight-tooth rea:ners, when properly designed, re ' Declassified in . 92. suit in holes fully satisfactory in :.precision and =surface `finish. Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 The fabrication, sharpening, and control of straight-tooth reamers is considerably simpler than for helical-tooth reamers. The machining of holes with longitudinal grooves of or length 0 ise-interrup,ed holes is to be done with helical-tooth reamers. w The hand of direction of the helical. teeth is to be opposite to the hand of direction of the rotation of the reamer, in order to eliminate the possibility of the self-tightening and jamming of the reamer in the hole, and also to forestall the possibility of the reamer shank becoming detached from the machine spindle. The angle of flute inclination is selected in relation to the flute material: for gray iron and hard steel', it is 7 - 8 degrees; for malleable iron and steel 12 - 20 degrees; for aluminum and light alloys -~. 3S degrees; for boiler work -- 2~ - 30 degrees. The eripheral_~non-uniform distribution of the teeth in the hole being reamed forestalls the appearance of longi' tudinal lines, 'which would be disposed in conformity with the pitch of the teeth The cause for the appearance of a riffled surface is the periodical variation of the tooth load, ac- countable to the non-uniformity in the work material, to hard or soft inclusions, and the like. The non uniformity in patch may be attained by various methods (see Figure 6)4), method b being the one in widest use, since it provides for greater simplicity in the fabrica- tion of the reamer and convenience in the microrneter~gaging of its diameter, .. 93 i. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 L0 o 1.6 148 ...- '. t k 0 00 10 3a ^0 3140 t c 36 37301 39 ? . ~o 12 2'7?30' 28o30 f 29o3o t; 30030! , 31?3o t 32030t J~ I/yyg~ p ` Yw.T4ruY11Wew4`N^+Y4x+M'hhN,H,~YaM1 nu.,.rh. A~. Iw, rx a^NMAILINWAI uWWlGbl{NCik1YAT '.eN1UwMNN++eihV,:xY.yf'C.T4 r.u?wwww__,~wwxf_w ?+r'M^wrfHn.TUeu,w+1U,~Naw.uH nurxlnuMrn+'mwrr.utraetvrw Note: The dividing head disk is to have L9 holeso Non-uniformity in the pitch of the teeth can also be attained by slanting flutes with a change in direction for each two adjacent teeth. The angles for the cutting part are selected in rela~ ton to the designation of the reamer and to the work material. Data pertaining to the non-.uniformity in the pitch of the teeth is cited in Table 7. Figure 6). Methods of forming a nonuniform pitch in the reamer teeth. a pitch varied in all teeth; b pitch varied to both sides of the control teeth lying on one diameter; same values for pitch for each two opposite teetho Non~uniforrnity in the pitch of teeth Number of teeth Angle of turn .....wmrwwwrwuwW,wu~sw,mww~rw++~s~wrw'wil.x~w.M+'w Woam4a4uMwnwwxnM+.wow:.,.,.~.:nwl.nwxne+aoxnvlYe+wT.r+'rrvwn:.N+m+mram+'wirrvuwlwrwu'rAV*7tTln WLLK~W:uwula~J1YMNTNk~M:M~Ar)'7xM1A4t"r'1~~".+'NMIS+N~~thA[Ib1k% Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R0001 wr,CYrM1I`wuRMU W WAn W MMa V TR~w~~MIVMM 4N1/'AdunbnlF'k?i W ~17u~T':AV MMRiVIV41 W A~tlM>wk~YMMO.MYMAAw~ W~M1M1~N f Vt~fMT[ NNI#YdF1MM!N!b51Y:0~7JMN}4kJ': i 903 t 6200.,. 00240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Back relief angle ~X, for the cutting pare is selected within the range of L - 8 degrees. For finishing reamers, The sharpen- point, while, on the `calibrating part, a small `margin is left (Figure 65)o The margin provides for the guiding of the reamer in, the hole, promotes a smoother surface finish, pro- vides for proper. calibration of the hole' and facilitates the control of the reamer along its diameter. The margin width is selected as 0.05 - 0.3 millimeter, in relation to reamer size. In the machining of ductile materials, when it becomes necessary to prevent the adhesion of the chip, th.e margin width is reduced to 0.05 - 0.08 millimeter. The grinding of th.e margin at an angle of 30' - 1030 ? is also recommended. In the case of hand reamers, and also machine- operated reamers with chrornated edges, the margin width is to be kept within 0.15 - 0.18 m liimeters? The margin width in machine-operated reamers may be increased to Oa3 - 0.1L. milli s meters, when machining holes of special precision in steel and cast iron' in which case the reaming is done by mechanical feed and at low cutting speed. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Adjustable cylindrical reamers, and also taper and bailer rearnerss are to be sharpened to two angles: G 8 degrees and c` - 1 20 degrees (Figure 65, b) Front rake angle of the reamer is accepted as equal to zero; the front surface is directed along the radium In the case of more rigid specifications pertaining to the finish, it is recommended that angle be given a surface negative value of minus degrees. In order to avoid the adhesion of chip to the cutting edge when reaming in ductile material, angle 7 is to have a positive value within the range of - 10 degreesa In the case of boiler reamers, which are not only to remove the predetermined machining stock but also the layer of mewl formed by the boiler plate displacement, angle is to be positive within the range of 12 - l~ degrees. Angie 7 is measured in a plane normal to the direction` of the, flute. The ratio between. angle in a normal section and angle in the face section (for a point located at the ~ periphery) is expressed by formula Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 where a is the angle of flute inclination.  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 3 w 3.~ 6 - 5 6 5 6 om2~ 0e12 8 o03 0.12 0.14 0.12 6 oo odS 8; 0.6 001 9C Dimensions and types of flute profiles are enumerated in Table 8 TABLE 8 Dimensions of reamer flute profiles Diameter Number Width of lip (margin) in of reamer of p teeth in mm r,n degrees i ra mm Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 hype A Tae B [Drawing] [Drawing] [Drawing] ] [Draw~.ng ] Figure 66. The profile of the reamer flutes, [Drawings] Figure 67. The milling of the flutes with the aid of a double angle milling cutter. CDrawing I.Lute) is free of the above defects. For medium and large sizes, the use of a profile with the outline of the back of the tooth along the radius (for type B flute) is recommended. Such a profile provides for an adequate space for the chip and the requisite strength of the tooth. A single angle milling cutter (for type A flute) (see Figure 66), makes a poor front surface, and the face milling teeth wear rapidly. Due to the undercut, in the tooth this r ~ type of milling cutter is not suitable for milling helical teeth reamers. A double-angle milliri~ cutter ~ (for ..type B In order to avoid the appearance of cracks in harden,.. g, the hollow of the flute is to be rounded to a radius 0.3 08 miJ.limoters, Declassified in Part - Sanitized Copy Approved for Release  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 When milling a flute for a reamer of non-uniform pitch (Figure 67), in order to maintain the same value of p, it becomes necessary to change the depth' of the flute and the distance between the axes of the reamer and the milling cutter for each new flute0 .5iILL&L !T where R 3 is the radius of the blank (with a stock allowance of 0.1,E - 0.11 millimeter for grinding). To simplify the operation of milling the flutes, special shape milling cutters are used, which machine not the flute, but the tooth of the reamer (see Figure 68), with the width of lip p remaining the same, without a change in the depth of milling. The defect of the special shape milling cutters consists in the fact that the back of the tooth receives a Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Figure 70. Duplex special shape milling cutter for the milling of reamers. The special shape milling cutter may be replaced' by two milling cutters' assembled into one duplex unit (Figure 70), with the width of lip p adjustable by an intermediate ring. The profile dimensions for' special shape milling cutters are given in Table 9, and th.e designations of the profile corn- ponents are shown in Figure 71. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 small shoulder a, 0 l - 0.2 millimeter high (Figure' 69). This method of milling with special shape milling cutters is applicable to straight-tooth reamers only  Special shape `milling cutter profiles Figure 71) Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 in degrees  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Part Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 The clamping part of hand reamers consists of a short neck 16, straight shank 1, and square e. The neck 'serves to facilitate the grinding of the cutting part and shank, the square for bracing in the respective' hollow, the shank for 0.03 - 0.08 millimeter smaller than the reamer diameter. The clamping part of machine-operated reamers is made : (1) cylindrical, for reamers up to 10 ? 12-millimeter size; (2) with Morse taper; (3) with square (not in wide use). Machine-operated reamers have a long neck to facilitate the reaming of deep holes. Detachable reamers are made with tapered holes, the taper being 1:30. OST 2811 - Lt0. ..A diagram of the 'disposition of diameter tolerances for reamer, designated for the machining of work with depar- tures by a system of holes, is shown in Figure 72, The values for the tolerance components are given in Table 10. Nominal 0 Figure ?72. Tolerance diagram for reamer diameter: N ? tolerance Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 for non-precision of fabrication; Pmax and Pin .._ markings off values of the hole being reamed; T p? guaranteed reserve of wearing stock along diameter of reamer under operating con- ditions; tolerance for hole; AB -- upper departure of reamer diameter; CD -- lower departure of reamer diameter. Reamers of Sectional Design. Reamers of sectional design are divided into release reamers and inserted tooth reamers. Release' reamers are used in assembling work. Their teeth are made integral with body, but they r spread along the diameter, due to the combined action of axially cut out splines and an adjusting taper screw or ball in a specially bored hole. Inserted tooth reamers come in various designs; the most 1 I~ rational being the design where the teeth are inserted into the body with the aid of riffles. Bracing and adjusting to i~ size is effected in the same manner as in the case of counter" ! ?~ < sink teeth (see original page 338) Sectional reamers are made with a small number of `teeth; Diameter of reamer Number of teeth (in millimeters) CIA-R D P82-00039 R000100240004-1 8 10 130 Mlo 12 Declassified in Part -Sanitized Copy Approved for Release 2012J03/20 :CIA-RDP82-000398000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 These reamers are also made with non-uniform pitch, in accordance with data presented in Table 7. Tool angles and cutting and calibrating parts are the same as in the case of solid 'reamers. It is recomrrlended that concavities be made for each tooth in the body of the reamer, along the cutting edge, to facilitate the ejection of the chip. Specifications for inserted tooth reamers are estab- lished by GUST 1523 ? 42 TABLE 10 Tolerance components for reamer diameter Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Tolerance values in microns (3) () () (6) (7) (8) (9) (10) ntmr+n.., wtaae! r n atxea arvrx?~+va, nr srtm~sra;, srxsn r 7 910 12 iii. 16 18 Second class 7 9 11 12 1?'. 16 18 20  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 pirst class ~ U y" -- ~ Precision toler- aces in fabrication of 'precisian a N o 12 1~ 1 l 2p 20 Second class 1 of precision Taper Reamers Taper reamers are used far the reaming of a cylindrical for the calibration of an already tapered hale to a taper, or holes prelirinarily machined by another tool. Taper reamers are made in the following types: 7 or 1:10}; for Morse taper hoJ.es; (2) for tap hales (taper l: (3) for dowel p s (toper 1:~p); (L) Coal rea.t~1ers for '~.n hole detachable tools, reamers, countersinks, etc.. (,apex 1:30)? Taper reamers for Morse toper holes (Figure 73) are three or two. The first set (Figure 73,a) fabricated in sets of is :>.n the form of a countersink, threaded at an angle of inclina- to the inclination angle of the Morse taper. The tion equal coincides with the direction of cut. The lead of the thread. reamer converts a cylindrical hale into a step hole. The at their back surfaces, their number ranging teeth are relieved, Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R0001 00240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 [Drawings] [Drawings] [Drawings] Figure 73. Taper reamers for Morse taper holes; s - thread height of tooth; k width of thread flute; a ?- depth of thread flute. The second reamer (Figure 73, b) has rectangular left- from 3 to 8, in relation to the taper ratio. Each projecting part performs with a small angle, similarly to a boring cutter with 'face-cutting edge. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 hand thread (for right-hand cutting). The thread is for the purpose of breaking up the chip and for effecting smaller steps in the hole. The number of threads per inch in 8 w in relation to the taper ratio; b = s; a b; the S 2J teeth are sharp-pointed, with small 1 T millimeter margin. The third reamer (Figure 73, c) is little. different, in its design, from a cylindrical reamer. The pitch of the teeth is uniform. The margin width is 0.05 0.08 millimeter.  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 CIA-R D P82-00039 R000100240004-1 Taper reamers for tap holes and tools come wit1l one reamer in each set. The elements of design are determined in th.e same manner as in the case of conventional cylindrical reamers." Reamers for dowel pin holes serve for the reaming of already existing cylindrical holes in various parts of machines connected by dowels. Due to their small taper ratio (1:~0), they remove an insignificant layer of metal, and, therefore, convert a cylindrical hole into 'a'tapered one without prelimi- nary reaming. The front end diameter is 'so calculated that the reamer projects 1.~ - millimeters from the hole, To increase the number of possible sharpenings, the cutting part is made longer than the standard dowel length. The number of teeth is within the range of Li. to 6. Reamers up to the - 8 millimeter size are equipped with reversible centers. Reamers up to the 3 millimeter size are of trihedral or pentahedra) shape, in section, the ribs serving as the cutting edges.. Screw dowel reamers,; the design ofi which is depicted in Figure h, and the sizes enumerated in Table 11, permit high cutting speeds and are characterized by great durability. [Drawing] Figure h.o Screw-dowel machine-operated reamer. 108 Declassified n Part - Sanitized Copy Approved for Release  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 Screw-dowel machine operated reamers dimensions in 'millimeters) ( direction of the helical teeth is opposite to the The direction of cut, ~ ting thereby the possibility of self el~.ma.na tightening of the reamer. The flutes provide ample space for the chip, inating the possibility of jamming. Hand-operated el- ' ~-m reamers of this type differ from the chine-operated ones by teeth (3 M L,) and the greater value of the greater. number of imeters). The angle of the milling cutter pitch (12 .. 60 mill used in is 75 degrees. In the remainin ~.n their fabrication 0 8 o. 0.2 80? Lo 2 Oob 0. 0.8 - 0o2 80? 7.2 '26? 1.0 0.3 80? 9.0 260304 ? 4 1L 2r~o30 ~ 1.6 o.~ 80 0 1~0 o.b 80? 90 26?3o~ 1$ o.8 80? 11.2 26? ld l.o 80o 13. 26 ? .~ er of the milling cutter for milling Note:` ~'.... width; ~T angle of p of, the reamer flutes. 1 10 8 1 lE 10 2 20 13 2 2y 16 2 30 Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 features, the designs are similar. Hard-All oy-TTDied Reamers of hard alloys in reaming is stipulated by The use wear and by their relati vo7..y low their great resistance to sensitivity to the nonahomogerzeity and inczstations in the work maters al. Hard?~loy~t~.pped reamers permit the application of a - ,.. cutting speed several times greater than. is possible with highspeed steel reamers. the accumula~3i0 n of grease on the In order to avoid ., rinding the reamer teeth, the length of grinding disk when g blades is calculated to be the exact length the hard-a7.loy of th.e working parts which, in turn, is made shorter by one in the case of conventional reamers. Carbon third than ea~ler body, the carbon content being steel is used for the r o.6 Q7 percent. This ' s p' ermssible, s~Ce ::.the body of or .: ~. resence of teeth along the full the reamer, due to the p t, does not comp: into contact with: length of the working par the work surface. The thickness of the hard?a].10y blades otherwise it would be Impossible to must not be too great, use them a. ?n the case of small size reamers. The thickness of the hard-alloy blade is usually equal to 1/10 - 112 of its length. front rake angle: = 0, the back relief angle The f the cutting angle = 2 degrees; 12` t 15 :degrees, 110 ?. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1  Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1 the bevel on the face is one millimeter X L degrees. The back taper runs within the range of OuO15 = 0~02S millimeters For reaming blind holes, it is recommended that the reamer be equipped with face-cutting teeth. For the machining of deep holes, three'-tooth short reamers with brazed-on hard-alloy blades (T15K6), equipped with a hardwood front guide, are used. The cutting angle 9p = 75 degrees; the back relief angle upon the cutting 7 edge is ~C?W 3 degrees. These reamers work under conditions of intensive cooling during accelerated cutting speeds. 1 hen machining in hard metals with 1 > 90 klom grams per square millimeter, trihedral reamers Without milled flutes are used. The hard-alloy blades are brazed into the grooves, disposed at the apexes of the trihedral section of the body, in such a way that the front rake angle 1) has a negative value. The back relief angle O( = 8 degrees. The back taper is made to an angle of 2 degrees. Such reamers operate at high cutting speeds -up to 80 meters per minute. BIBLTOGRAPI{Y AND SOURCES 1. Kutay, A. K., and Shtermer, G. A., Tolerances, Reamers, and Countersinks, ONTID 1936. 2. Semchenko, I. I., Cutting Tool, volume I, ONTI, 1936? 3. Chetverikov, S. S., Metal Cutting Tools, Mashgiz, 1915. Declassified in Part - Sanitized Copy Approved for Release 2012/03/20 : CIA-RDP82-00039R000100240004-1