(SANITIZED)UNCLASSIFIED SOVIET PAPERS ON GAS STORAGE AND DISTRIBUTION, AND GASLINE AND COMPRESSOR CONSTRUCTION (SANITIZED)

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CIA-RDP80T00246A016600230001-2
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May 28, 1962
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Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Next 3 Page(s) In Document Denied Iq Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 CA USE ONLY SUMMARY ' This paper gives a brief analysis of the factors determining the efficiency of underground gas storages as the means of meeting variations in gas consumption. The author describes a method of determining the necessary capacity and optimum productivity of storages, the suitable geological conditions and methods of prospecting and exploring for underground storages ; and the results of a theoretical study of gas hydro- dynamic character in connection with underground gas storage are briefly stated. The first results of expe- rimental gas and air injections into underground storages in the USSR are also described. RESUME Le present memoire est une breve analyse des facteurs qui determinent 1'efficacite des stockages souter- rains pour faire face aux variations de la, consommation. L'auteur decrit une methode de determination de la capacite necessaire des reservoirs et de la cadence la plus favorable de soutirage. I1 decrit les conditions geologiques ainsi que les methodes de prospection et d'exl,ioration des stockages souterrains ainsi que les resultats d'une etude theorique au sujet de la dynamique des syst?mes eau-gaz qui a ete effectuee en relation avec les problemes; du stockage souterrain du gaz. L'auteur decrit les premiers resultats des experiences d'in- jection d'air et. de gaz effectuees'en URSS. Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 t~-- 1 PROBLEM OF UNDERGROUND GAS STORAGE IN THE USSR N. S. Ero f ecv, USSR There are variations in gas consumption by in- dustrial enterprises and especially utility and do- mestic consumers. To meet the requirements of all the consumers it is necessary to have stand-by capacities for gas production and transportation or storages near consumption regions which could ensure conservation of gas surpluses during off-peak periods and their withdrawal during peak-load periods. Technical-economic calculations and already exist- ing experience of a number of countries show that construction and operation of underground gas storages is the most rational means to meet seasonal variations of gas consumption by large industrial centres. The use of depleted gas or oil fields for this purpose, if they are situated relatively near con- sumption regions, is the most advantageous way. If there are no such fields near consumers one has to construct storages in porous aquifers. However, the construction of gas storages in aqui- fers is a complicated technical problem; it requires high expenditure, therefore this method can be eco- nomically justified only in some cases. Profitableness of underground gas storage depends on numerous factors of great variety. The most im- portant of them are : - degree of gas consumption irregularity; - capacity and length of the gas main; - distance between the gas storage and the place of consumption and the gas main; - geological and field'. features of the reservoir chosen for gas storage (trap reliability, collec- tor permeability, reservoir pressure, actual capacity etc.). In the USSR work on underground gas storage has been begun only a few years ago. For this time inte- resting economic investigations making it possible to determine the'necessary parameters of underground gas storages have been carried out; a great volume of exploring work has been done which resulted in finding and exploration of a number of favourable structures and areas; the theory and hydro-gas-dy- namic principles of storage construction in aqui- fers have been worked out; experimental injections of gas and air have been carried out under various geological conditions. IT ECONOMIC CRITERIA DETERMINING THE PARAMETERS OF UNDERGROUND GAS STORAGES Variations of gas consumption depend on the type of the consumer. Utility and domestic consumers cause the greatest seasonal variations, large indust- rial enterprises cause lesser ones. Evidently the degree of seasonal irregularity de- pends on the proportion of various consumers. How- ever the analysis of average for a number of years on large consumption regions shows coinciding re- sults. Irregularity factors (the ratio of gas consumption for a given month to average annual consumption for a month) for Kiev, Moscow and the USA (for 1955) are given in Table 1. Table 1. Factors of Gas Consumption Irregularity for Months Months Regions Kiev Moscow I USA January 1.29 1.22 1.27 February 1.28 1.31 1.34 March 1.18 1.21 1.24 April 0.97 0.99 1.035 May 0.82 0.75 0.845 June 0.76 0.70 0.785 July 0.74 0.69 0.73 August 0.77 0.74 0.74 September 0.79 0.82 0.76 October 0.95 1.0 0.88 November 1.15 1.22 1.06 December 1.33 1.36 1.34 Storage capacity necessary to meet seasonal varia- tions of gas consumption can he calculated by the formulas: V- EK>1-n>1 .100.... (1) 12 ...... or V= n 1 is the number of factors exceeding 1. K < 1 and n < I are the same indices less than I respectively. The required storage capacity for the cases given in Table 1 is as follows. Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 By formula 1 By formula 2 Average For Kiev 10.25 10.0 10.12 Moscow 11.08 10.91 11.0 the USA 10.07 10.5 10.6 The character of gas consumption variations de- termines not only necessary actual storage capacity but also its deliverability. Besides seasonal . variations there are day varia- tions of gas consumption. Factors of day irregularity reach 1.6-2.0 as compared with average day con- sumption during the year. Technical-economic calculations have showed that there exists an optimum irregularity factor under which the cost price of storage is minimum. Crea- tion of conditions under which wider variations would be met causes a considerable increase of stor- age cost price. For the analysed cases such an optimum factor is 1.35 corresponding to the maximum index of sea- sonal irregularity.. The growth of the cost price of additional stored gas is shown in Table 3. Growth of Cost Price as "K" Value Increases Irregulatity factor 1.35 1.40 1.45 1.50 1.55 1.60 Cost price of additio- nal stored gas (in % to the cost price under K = 1,35) 100 115 153 178 255 468 Taking into account the coincidence of results for various conditions when designing and constructing underground gas storages, we consider it possible to assume: - necessary actual storage capacity to be equal to 10-11 % of annual gas.consumption by a large industrial region or town; - storage deliverability to he equal to 35-40 % of average day consumption for a year. A comparative analysis on the basis of gross tech- nical-economic indices of underground gas storage efficiency depending on the capacity and length of a gas main permitted to draw the following conclu- sions: - the efficiency of 'underground gas storage operation increases as gas main capacity rises and especially as gas main length increases; - for most cases, gas main having the length up to 200 km, one should provide stand-by capa- cities for gas production and transportation and when gas mains have ? greater length one should construct underground gas storages if possible; - in such cases the economy obtained by under- ground storage operation by far exceeds the ex- penditure on their construction. For example, for a gas main, having the length of 1000 km and the capacity of 10 million cu.m. per day, the economy exceeds the expenditure on un- derground gas storage construction 10 times. LPB OE ICIAU USE ONL' In many cases, gas mains having great length and capacity, underground storage efficiency remains even when the storage is rather far from the consu- mer. For a gas main, having the length of 1000 kin. and the capacity of 5 million cu.m. per day, high efficiency remains even when the distance between the storage and the consumer is 200 km. Technical-economic investigations of the effici- ency of underground gas storage were carried out in the Institute ?Ukrgiprogasb. Their results were published in a number of its works. The obtained conclusions and worked out criteria are used in the USSR when prospecting and explor- ing structures favourable for underground gas stor- ages. III GEOLOGICAL CONDITIONS AND METHODS OF WORK ON PRO- SPECT AND EXPLORATION OF UNDERGROUND GAS STORAGES More than 75 % of gas produced in our country is to be consumed by 'towns and industrial centres situated far from gas and oil fields. Therefore to meet seasonal variations of gas consumption, the main efforts are directed at the search for structures favourable for construction of underground storages in aquifers. Prospecting and exploring work is carried out on a large scale under various geological conditions. It is directed at the search for local anticline struc- tures and well permeable water-bearing intercala- tions overlaid with clay strata of sufficient thick- ness. For the majority of regions with the largest gas consumption the. geological conditions are little favourable. In this connection the limit parameters determin- ing the suitability of an object (the amplitude and dimensions of the structure, the depth, thickness and permeability of the stratum) are not established. Structures with the .amplitude of 12-15 in and strata lying at the depth of 800-900 in and 150-200 in. are being explored. The thickness of clay overburdens varies from several metres to 100-150 in. All the strata being prospecting are represented by sand and sandstones, their permeability ranges from 0.5-1.0 darcy to several darcies. Serious obstacles are caused by the low stability of sand streaks lying at small depth (200-300 m.). To prevent sanding up one has to provide wells with special filters. On one of the areas exploration of a stratum represented by cracked limestone is planned. On one of the areas a sand lens lying in clay Devoni- an strata is prepared for experimental gas injection. The maximum thickness of the sandstone is 15 in., porosity is 25 %, permeability is 0.4-0.5 darcy, depth of lying is 745 in., initial stratum pressure is 78 atm. Experimental withdrawal of 2000 m3 of water caus- ed pressure drop in the lens by 5 atm. Experts believe that an underground storage con- structed in such lenticular sandstone (if one suc- ceeds in drying it completely) will have a number of operating advantages. Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80TOO246AO16600230001-2 Prospecting and exploring in the following sequence: u OFF C y uS : ONLY Methods of calculation of water displacement by gas in gently and steep dipping dome shaped aqui- ferous structures were worked out. These methods make it possible to take into account the absence or presence of a gas cap at the beginning of injection as well as the unloading effect at the elastic drive of an aquifer. Special investigations were devoted to non-steady - study of general geological data of the region with large gas consumption, search for struc- tures by means of seismic prospecting and drilling of profiles of shallow wells; - checking and study of the chosen structures by means of drilling of a network of shallow structural wells; - exploration of the aquifer by means of drill- ing and special testing of exploratory wells; - experimental gas injection. Practice has shown that usual exploration by means of drilling of wells is insufficient for the preparation of an underground gas storage. To obtain a quantitative characteristic of the aqui- fer and its overburden within the limits of a future underground storage special methods of well testing called hydroexploration have been developed and are used. The essence of these methods is that after creation of a system of wells uncovering the stratum being explored and the overlying permeable stratum, a series of tests on water withdrawal from some wells and observation of the pressure in other ones is carried out. On the basis of these tests aquifer conditions, the degree of communication of different sections, absence of overburden leakage, averaged numerical values of main stratum parameters-per- meability and pressurebearing characteristic are de- termined. Recently a successful test of area stratum explora- tion by means of injection of a sinal.l air quantity (200-250 thousand cu.m.) by usual compressors in a well and of observation of levels in other wells was carried out. This method is especially valuable when exploring wellpermeable thick acquiferswhere it is difficult to- cause pressure changes, sufficient for observation, by means of water withdrawal. In the USSR since 1957 750 shallow structural test wells and 156 exploratory wells have been drilled for prospecting and exploring of underground gas storages; area >>hydroexplorationb has been carried out in five structures. IV ABOUT HYDRO-GAS-DYNAMIC PRINCIPLES OF CONSTRUCTION OF UNDERGROUND STORAGES IN AQUIFERS Complex exploration, design and construction of underground gas storages in aquifers required special theoretical investigations and solution of a number of hydro-gas-dynamic problems. Such investigations are carried out in the All-Union Scientific Research Institute for Natural Gas (.vVNIIGAS>) and in the Academician Gubkin Moscow Institute of Oil-Chemi- cal and Gas Industry (?MINKFI & GP>>). The results of these investigations were published in a number of works, the list of which is included in this paper. Because of highly special character of these in- vestigations in this paper we confine ourselves to the enumeration of the most important solved pro- blems. liquid and gas inflow to hydrodynamically imper- fect wells. A theory was developed and a correspond- ing practical method of determination of geological- physical stratum parameters on the basis of data of hydrodynamically imperfect wells testing was given. An original solution of the problem of non-steady liquid or gas filtration under the harmonic law of pressure or flow change was found. On the basis of this solution simple working formulas were obtain- ed and a method of determination of geological-phy- sical parameters of the collector according to pres- sure distribution in the stratum, caused by the in- fluence of the change in liquid flow or pressure, was. worked out. xperimental investigations with the model of coef- ficient of water displacement by gas in sand weze carried out. It was found that the displacement coefficient greatly depends on the frontal displacement velo- city, sharply decreasing as this velocity increases. Visual observations showed that there was no plug displacement of water by gas and that blocked up>> water saturated zones formed. The overburden zone of the reservoir was filled by gas faster than the bottom zone. The efficiency of displacement de- pends on the geometrical position of the gas injection region with respect to the unloading region. The more the distance between the injection region and the unloading region, the higher the efficiency of water displacement by gas is. These investigations are only at their beginning, their results must be checked in practice. Finding of the conditions of the maximum displacement in a stratum which is practically always heterogeneous is the main problem. The developed theoretical principles and working formulas found a use in strata hydroexploration, in design and carrying out experimental gas and air injection. V SOME RESULTS OF EXPERI- MENTAL WORK The most interesting results were obtained by gas injection in one of the experimental storages. Gas was injected in a Gdov Cambrian water-bearing sandstone. Its thickness was 10-12 in.; porosity 0.22, permeability from 0.5 to 2.1 darcy, the depth of lying.800-930 m., pressure in the upper part of the structure 82 atm. The stratum was overlaid with a clay series having the thickness up to 100 in. How- ever a lens of breccia of crystalline rocks lies in this series. This lens probably contacts in upthrust with the Gdov sandstone. Structurally the stratum is gently folded, the northern wing complicated and separated by tectonic ruptures. The complexity of this structure caused a great FOR OFFICIAL USE ON Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80TOO246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80TOO246AO16600230001-2 volume of exploratory work. It was necessary to drill 40 exploratory wells which were further used for gas injection, unloading and observations. Gas injection is effected by means of two com- pressors having the power of 1000 h.p. ensuring two-stage compression from 25 to 55 atm. and from 55 to 125 atm. and the output of 500 thousand cu.m. per day. In 1959 for three months 23 million cu.m. of gas were injected. Injection was effected through 2-4 wells, the maximum well head pressure being 103 atm. Injection showed good well injectability up to 500 thousand cu.m. per day, practical isolation of the northern wing of the fold and connection of the Gdov sandstone with the breccia lens. During the winter observation of pressure redistribution was maintained. Attemps at getting dry gas failed. Since April 1960 gas injection was resumed. The maximum injection amounted to 620 thousand cu.m. per day. The well head pressure amounted to 100- 102 atm. The total injection was 80 million cu.m. At injection unloading was 'effected - water was let out, from the wells situated down dip from the group of injection wells. Three unloading wells were situated at the distance of 700-1000 m. from the injection wells and five - at the di- stance of 1500-2500 in. On the whole 176 thousand cu.m. of water was let out. There was no gas break- through to the unloading wells. The unloading en- sured more uniform and more complete water dis- placement from the Gdov sandstone. To control the possible gas leakage from the brec- cia lens wells were drilled to the overlying sand stratum. Observation showed the absence of reac- tion in these wells. In winter months an experimental gas ejection from the Gdov sandstone will be carried out. On another area an experimental air injection into a gently dipping aquifer was carried out. Its thick- ness is 10-15 in., porosity - 0.20-0.25, average permeability 1.3 darcy, the depth' of lying - 395- 420 m., bottom pressure - 36 atm. A group of seven wells 'was drilled for experiment, the injection well being in the centre, the control and observation wells being at mutually perpendicular di- rections at the distance of 25 and 50 in. Observa- tions were also carried out in exploratory wells drilled earlier and located at' various distances. 3260 thousand cu.m. of air under the well head pressure of injection well 40-40.5 atm. were injected, 80 thousand cu.m. per day on the average.. After pressure drop to 36.7 atm. air outlet from the same well was. begun. Altogether 1423 thousand cu.m. or 44 % of injected air were let out, including 917 thousand cu.m. dr 29 % of dry air, then water appeared, the quantity of which gradually increased. Despite the relatively small scale of the experi- ment its results demonstrate a practical possibility of construction, under certain conditions of a gas storage in gently dipping or horizontal strata. It is intended to continue the test, injecting a greater volume of air and making a longer delay. Careful observations showed a very uneven air advancement in the stratum. Average displacement radius being 300 in., some bbreakthroughsb reached 1000 in. Air displaced water only in the lower part of the stratum amounting to about one third of its thick- ness. This is undoubtedly cgnnectcd with the hetero- geneity of the stratum and the change of its reser- voir properties on the strike and cross-section. At the same time one can assume that, the volume of the injected air and injection pressure increased, the unevenness of displacement will be partially levelled off. In 1958 and 1959 in some regions of the USSR several small underground gas storages in partially depleted gas fields were constructed. At present four storages are in operation.-For the whole period of their operation 93.1 million cu.m. of gas were injected into these storages including 53.7 million cu.m. in 1960 and 18.7, million cu.m. were withdrawn. One storage was constructed in a Permian sand stratum lying at the depth of 400. These deposits present a small brachyanticline fold with an ampli- tude of 32 in. The initial gas reserves were 30 million cu.m., the initial stratum pressure was 54.2 atm. abs. For the time of operation 18.4 million cu.m. were withdrawn, the stratum pressure decreased to 16.5 atm. abs. Injection was begun in 1958 and since that time two complete cycles of injection and, with- drawal were carried out. Now the third injection is going on. On the whole 16.1 million cu.m. were in- jected, 10.7 million cu.m. were withdrawn. The pres- sure in the stratum rose to 32.6 atm. abs. and fell to 16.2 atm. abs. Injection and withdrawal were carried out by means of four wells. At the beginning of 1960 a leakage in one of the wells drilled earlier was found. At present the well is under repair. In another region a partially depleted deposit of the field is used as an underground gas storage for' 3 years, and in 1960 gas injection into other deposits of the same field. was begun. By September this year 90 million cu.m. of gas were injected into all the three deposits. The operation of storages constructed in partially depleted deposits does not cause special difficulties. From the economic point of view the use of such sto- rages for the accumulation of summer surpluses of gas produced together with oil is the most expedient way. In spite of the technical complexity of the con- struction of underground gas storages in aquifers, the economic efficiency of meeting variations in gas consumption by means of underground storages, un- der the condition of distant transport, is beyond doubt. It is necessary to accumulate the facts to de- fine more exactly the quantitative criteria of effi- ciency under various conditions. In the whole world there are very few under- ground gas storages constructed in aquifers. The most urgent problems of the technical aspect of the underground gas storage are the following ones: - the further improvement of the methods of ex- ploration; - the development of a method reliably determin- ing the absence of leakage of the overburden as early as at the stage of storage exploration; - the ensuring of controlled and uniform dis- placement of water by gas from a stratum which is practically always heterogeneous; E?I ? FIF FTU- "I'll nC1i Uof 'J !L Y Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80TOO246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246A016600230001-2 - the development of methods of storages con- struction in horizontal aquifers; The exchange of information and experience among the countries, members of the International Gas Union, will contribute to the quickest solution of these problems. 1. Of Bottom Water Advancement in Gas Deposits of Dome Type. Charniy I. A. Transactions of the Aca- demy of Sciences of the USSR. Department of Tech- nical Sciences N 9, 1950. 2. Gas Production and Transportation Chapter X. Brisk- man A. A., Ivanov A. K. et al. Gostoptekhizdat, 1955. 3. Underground Gas Storage in the Trust >Kuibishev- Gasw., Borisov S. D., Semyonov V. E. Gazovaya Pro- mishlennost. N II, 1958. 4. Underground Gas Storage. Raaben V. N., Levikin E. V. Gazovaya Promishlennost. N 10, 1958. 5. Technical-Economic Determination of the Number of Wells, the Volume of Cushion Gas, the Power of a Compressor Station and the Depth of Trap Searching at Underground Gas Storage. Shirkovskiy A. I. Gazo- vaya Promishlennost. N II. 1958. 6. Efficiency of Underground Gas Storages Utilization. Torzhevskiy V. K. Collection of Papers of the All- Union Conference >>Ways of Development of Gas In- dustry of the USSR. Gostoptekhizdat, 1958. 7. Of the Methods of Gas Storages Construction. Shir- kovskiy A. I. Collection >>Ways of Development of Gas Industry of the USSR. Gostoptekhizdat, 1958. 8. To the Problem of the Method of Calculation of Gas Injection into an Aquifer to Construct an Under- ground Gas Storage. Levikin E. V., Khein A. A. Gazo- vaya Promishlennost, N I, 1959. 9. Approximate Method of Calculation of Gas Injection into an Aquifer and its Comparison with Some Ac- curate Solutions. Filinov M. V., Charniy I. A., Trans- actions of the Academy of Sciences of the USSR. De- partment of Technical Sciences; N 1, 1959. 10. Paper' on Economic Problems of Underground Gas Storage. United Nations Organization. Economic Com- mission for Europe. Gas Working Party. 1959. 11. Underground Gas Storage in Foreign Countries. Bi- shard P. A., Scientific-Technical Collection on Gas Technique. Issue 2 )Underground Gas Storage>>. GOSINTI, Moscow, 1960. 12. Technical-Economic Indices of Underground Storage of Natural Gas. Torzhevskiy V. K. Scientific-Techni- cal Collection on Gas Technique. Issue 2. >>Under- ground Gas Storage. GOSINTI, Moscow, 1960. 13. State of Geological-Exploration Work Connected with Underground Gas Storage. Lodzhevskiy I. G. Collec- tion >Development of Gas Industry of the USSR. Gostoptekhizdat, 1960. 14. Experience in the Application of the Methods of Field Geophysics in Studying Objects for Underground Gas Storage. Kholin A. I. Collection ?Development of Gas Industry of the USSR. Gostoptekhizdat, 1960. 15. Of Seismic Prospecting of Structures for Underground Gas Storages. Ryahinkin L. A., Serdobolskiy L. A. Collection ?Development of Gas Industry of the USSR, Gostoptekhizdat, 1960. 16. Basic Principles of Combined Geological Hydrodyna- mic Exploration of Water-Bearing Traps for Under- ground Gas Storages. Khein A. L. Collection ?Develop- ment of Gas Industry of the USSR. Gostoptekhizdat, 1960. 17. Hydrodynamic Principles of Construction of Under- ground Gas Storages in Horizontal and Gently Dipp- ing Aquifers. Charniy I. A. Collection ?Development of the Gas Industry of the USSR. Gostoptekhizdat, 1960. 'tn' jFFPPCG Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 STAT Next 1 Page(s) In Document Denied Iq Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 EGH wmca USE ONLY. The year 1948, when the first gas main, from Saratov to Moscow, was put into service, should be con- sidered the beginning of industrial development of the gas industry in the USSR. At that time, commercial gas reserves were extremely limited and exploratory drilling for natural gas was carried out only on a very small scale. Gas consumption was limited to public utility services. It was after 1956 that the gas industry began to develop rapidly, which is clear from the following data on actual and projected gas output and production, in billions of cubic metres: 1955, 10.4; 1959, 37.2; 196(1 47.1; 1965, 150. Construction of gas mains, which is highly mechanized, has been carried out on a large scale; their total length increased 3.3 times in 1959 as compared with 1955, and the pipelines are mainly of large diameter (720 to 1,02(kmm). By the end of 1959, gas was being supplied to more than 230 towns and 166 workmen's settlements. By the end of 1965, towns and workmen's settlements with a total population of more than 40 million will be supplied with gas. Realization of such high rates of development of the gas industry is based on the availability of large reserves of natural gases in various regions and in almost all of the suitable geological formations of the USSR. The total estimated gas reserves in the USSR are 55 to 60 trillion cubic metres. In the USSR, development of gas and gas-condensate fields is carried out on a scientific basis. The greatest attention is paid to the study of all the geological components of a specified province - of the field or of the storage reservoir itself and of the associated hydrodynamic phenomena. Rational operation of the gaseous field entails the choosing of a layout and spacing for the wells, and of a progressive scheme of drilling dependent on the actual hydrodynamic characteristics of the storage re- servoir. The application of scientifically based methods for the recovery of natural gas and liquid hydrocarbons leads to a sharp diminution of the number of wells to be drilled, and, as a result, to great economy of material, capital investment and labour. Natural gas is increasingly utilized in various branches of the national economy of the USSR. Gas utilization has increased most of all in the chemical, metallurgical and cement industries, and, espe- cially, in the public utility services. Industrial and domestic utilization of gas is highly effective; it results not only in decreasing the unit cost of production, but also in improving the quality of materials such as metal, cement, etc., and in raising the productivity of industrial plant such as blast furnaces, open hearth furnaces, heat treatment furnaces, ce- ment kilns, etc. Domestic gas utilization has resulted in considerable economy of money and labour for heating and cooking. 't'own gas distribution systems are constructed in the USSR with d view to providing adequate gas supply to industrial plants, public utilities and domestic consumers. Various methods are used to ensure regular gas supplies at different times of the year and of the day and to establish the necessary peak-demand reserves, the most effective being the construction of underground gas storages near large centres of gas consumption. The utilization of liquefied petroleum gases is being widely developed, and the volume of L.P.G. con- sunmed is increasing very rapidly. Liquefied petroleum gases are used as a raw material in the chemical industry, as a source of town gas and for distribution to settlements situated far from gas mains, as a motor transport fuel, and for agricul- tural machinery and other purposes. For these purposes, liquefied gases are distributed by pipelines as well as by specially designed mobile tanks and in cylinders of various designs and dimensions. FOR OFFICIAL USE ONLY Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80TOO246AO16600230001-2 '~~st ars USE P>k' It ESUMI3 L'aunee 1948, all cours de laquelle le pipeline (le Saratov-Moscou a etc mis en exploitation, doit Ore con- aiderec comme lc debut du developpcment industriel do l'industrie du gaz en URSS. A cette epoque, les reserves coinmerciales etaicnt extrcmement limitees ct lcs forages d'exploration pour trouver du gaz naturel etaicnt cffectues A tine echelle tres reduite. La consommation do gaz so limitait aux services publics. Apres ll'annee 1956, 1'industric (lu gaz comntenga a Sc developper rapidement, cc qui ressort des chiffres ci-dessous qui montrent le,developpement do la production et de ]'emission do gaz (en milliards de m3) : 1955 1959 1960 1965 10.4 37.2 47.1 150 La construction des pipelines a etc effectuee a line tres gran de echclle; lour longueur a augmente do 3,3 fois en 1959 par rapport a 1955. On construit stu?tout des pipelines do grande dimension (720 A 1 020 mm) et lour pose est hautement mecanisec. Fin 1959, le gaz etait fourni A plus de 230 villes et 166 cites ouvricres. Pour la fin de 1965, des villes et des cites ouvricres totalisant tine population de plus de 40 millions (]'habitants scront alimentees en gaz. La possibilite do realisation do progres daps 1'industrie du gaz A un taux aussi clove est basee stir la dis- 11ponibilite de grandes reserves de gaz naturel daus differentes regions et reparties A pelt pros clans tonics les couches presentant des structures favorables dims le territoire de ]'URSS. Le total des reserves prevues en URSS est estime it 55 oil 60 trillions de m3. ],I'll URSS, le developpcment des champs de gaz naturel et la recuperation du gaz des gisements petroliferes sort effectues d'a pros des bases tres scientifiques. On attache In plus grande attention A ]'etude de toes les elements geologiques d'une province determines, du champ on du reservoir lui-memo et des phenomenes d'ecoulement. L'exploitation rationnelle des champs de gaz comprend le choix de ]'implantation des puits clans Ic champ lni-tticnte, de In distance entre les puits et de l'ordre de progression du forage qui depend des carac- teristiques reel4es du champ et des conditions de 1'ecoulement gazeux clans celui-ci. L'emploi tie methodes basees stir des elements scientifiques pour la recuperation du gaz, des condensats et l'exploitation des champs de gaz huntide, a entraine tine rapide diminution du nombre de puits A forer et, comme resultat tine grande economic de materiel, de depenses et de main d'a:uvre. l.e gaz naturel est utilise do plus en plus dins differentes branches de 1'econontie nationale en URSS. L'utilisation du gaz s'est surtout developpee Bans les industries chimiques, metallurgiques et cimentieres ainsi que clans les services publics. 11'emploi du gaz daps- l'industrie et pour les besoins (lomestiques s'est montre hautement efficient; de son etuploi resultent non seulement tine diminution du tout de la production mail egalement line amelioration do la qualite des produits finis (metal, ciment, etc.) et tine augmentation de la productivite des unites in- dustrielles (hauts-fourneaux, fours A sole, fours de traitentents thermiques, fours A ciment, etc.). L'emploi du gaz pour les besoins domestiques a permis des economies considerables d'argent et de tra- vail it la population dans le domaine du chauffage et de In cuisine. Les systentes do distribution de gaz de ville sont construits on URSS en fonction des possibilites de fournitures regulieres aux installations industriellcs, aux services publics et aux consonunateurs domestiques. Pour regulariser la fourniture de gaz pendant les differentes periodes de 1'annee et all tours d'une memo journec ainsi que pour assurer les reserves necessaires, on emploie differentes methodes. La plus efficace est cello do In construction de reservoirs de stockage souterrain pros des grands centres de consommation. L'emploi des gaz de petrole liquefies s'est largement developpe et la consommation des G.P.L. augmente tres rapidement. Les gaz de petrole liquefies sont utilises comme maticre premiere dans I'industrie chimique, pour ]'ali- mentation on gaz des villes et des cites situCes A tine trop grande distance des canalisations de gaz, comme carburant pour ]es automobiles et lcs moteurs des tracteurs et des machines agricoles ainsi qu'A d'autres fins. Les [!az do petrole liquefies sort transportcs par canalisations aussi bien quo par cautions et en bouteiles do diffcrents modcles et (le differentes dimensions. U'z,d"111 tA .USEC14.. Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80TOO246AO16600230001-2 . Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 T7 F I'tllE PROGRESS OF GAS DISTRI13L1'I'1ON IN 'I'I11," USSR F. I. Trcbin and A. .1. Sorol,?in, 1/SSI? DEVELOPMENT OF GAS SUPPLY IN THE USSR f GENERAL DATA ON TIIE DEVE- LOPMENT OF GAS INDUSTRY IN THE USSR TILL 1960 Gas industry is a 'young branch of the national economy of the USSR. The year of 1948 when the construction of the gas main Saratov-Moscow was completed and put into practice should be con- sidered the beginning of gas industry development in the USSR. In 1949 the gas main Dashava - Kiev - Bryansk - Moscow was put into practice. The prospecting of gas fields on commercial scale began after World War II. By 1946 commercial reserves of natural gas in the USSR were small and concentrated only in the Orenburg and Saratov Regions, the Konii Auto- nomous Soviet Socialist Republic and in some regions of the Ukraine (the Stanislav and Lvov ones). Under those conditions gas recovery from gas fields was limited. The whole gas. quantity was entirely used for public utility services. Because of the ever-growing requirements for gas fuel the production of manufactured gases in the USSR was developed to'some extent. Plants for pro- ducing manufactured gases out of shale in the Es- tonian Soviet Socialist Republic and in the Lenin- grad Region and out of brown coal in the Tula Re- gion were built. In the cities of Moscow, Leningrad and others gas for public utility services was also produced at plants of various schemes out of various raw mate- rials (solid and liquid fuels). Extensive development of gas industry was neces- sary. The Communist Party of the Soviet Union and the Soviet Government -took measures to develop this branch of industry. In 1956 it was found necessary to develop gas industry in every possible way, to intensify geological=prospecting and exploratory work to find new gas deposits, to ensure the in- crease of commercial-gas reserves by 85-90% for 5 years, to raise the output and production of gas to 40 billion cu. in. in 1960, i.e. to increase gas produc- tion 3.9 times more than in 1955. In connection with the resolution of the develop- event of chemical industry a further increase of demand for gas as a raw material for chemical and nil-chemical industry manifested itself. In 1959 planned figures of the development of the national economy of the USSR for 1959-1965 were approved. The planned figures envisage ".. , a change of fuel balance structure by means of priority development of the output and production of the most economic kinds of fuel- oil and gas. In 1965 to ensure oil out- put of 230-240 m.m.t, gas output and production of 150 billion cu.m.". These plans are being successfully fulfilled. In 1959 gas output and production amounted to 37.2 billion cu.m., i.e. 3.5 times more than in 1955. In 1960 gas output amid production amounted to 47.1 billion cuan. which exceeded those of the entire year of 1957 as well as the level of the task estab- lished for 1960 by the planned figures approved according to the Sixth Five-Year Plan. Such high rates of the increase of oil and gas out- put will make it possible to raise their share in the total volume of fuel production from 21% in 1958 up to 519'o in 1965; the share of gas will be increased from 5.4% up to 17.5%. Still more significant changes will take place in the structure of the fuel balance as regards the power use of fuel. The share of oil in this balance will increase for 7 years from 10.9% up to 17.8% and the share of gas will increase from 2.6% up to 24.8%, i.e. gas will constitute nearly a quarter of the power fuel. Having started the construction of a gas grid of great length the Soviet Union began to increase fast the rates of gas mains construction. For this pur- pose specialized organisations were created, equip- ped with modern building machines and mechanisms (dig-out trenchers, pipe cleaning machines, insulat- ing and electric welding machines, pipe line layers etc.). As a result, if in 1941 the construction of the first gas main Buguruslan-Kuibishev (150 ]cm) took about 1.5 year, in 1959 3,843 km of gas mains were laid. The total length of gas mains in the USSR in- creased by 35% for 1959 and by the end of 1959. the gas mains grid was about 80 % of the total grid increase for the preceding two years. Parallel with the length increase of the gas mains grid the transmission capacity of gas mains con- siderably increased at the rates considerably above those of length increase of gas mains. This is indi- cative of the fuller use of gas mains transmission capacily. In order to increase further gas mains efficiency gas turbine power plants meeting the modern rccluirenienls of distant transmission of large gas quantities are used at compressor stations and dc- '; Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13 d/: CIA-RDP80T00246AO16600230001-2 ;N1 ~ signing of powerful gas-motor compressors is being 1 1 mastered. I Tile development of distant gas supply in the USSR is carried out on a new basis meeting the modern requirements and the technique of distant gas transport at ion. '.this development is based on the use of pipes of large diameters. At. present the length of gas mains having the rli:uneter of 720 mm it and more exceeds 101/,, of the total length of gas mains in the, USSIt whereas in the USA the share of gas mains having the diameter more than 760 nnn is only 1.1%%. Gas transportation per 1 knr of gas mains in Uu+ USSR amounts to about. 2 iu.rn. cu.nr/year and will be as high as 4 nr.nn. eu.iii/year in 1965 whereas in the United States of America the volume of gas trans- portation per 1 kin of gas mains amounts to 0.8-0.9 nr.nr. cu.m/year. Despite the considerable lag of the length of the operating gas luains grid in the USSR behind the length of such grid in the USA the Soviet Union does not aim at overtaking the USA in this respect. This index does not characfcrize any economic supe- riority but rather shows absence of plan and private- owncrslrip\methods of construction of gas mains grids in the USA carried out by individual com- panies. Under the conditions of planned economy in the USSR gas transportation and distribution can be car- ried out by means of a gas mains grid of lesser length in spite of the vast territory of our country. This will be carried out by means of construction of gas mains of higher capacity and of their more rational use and distribution in the country. At the construction of gas mains in the Soviet Union high-efficiency mechanisms created by na- tional industry are widely used. The process of pipe welding and control of welding joints has been automatized. Line -construction methods and original highly effective methods of laying pipe lines across water obstacles and marsh-ridden districts are used. In 1959 mechanization of labour - consuming work at gas mains construction reached a high level: in earth work - 97c/0; in pipe cleaning work - 98.6%; in insulation work - 95.8%; in assembly- welding work - 71.3%. The level of mechanization of welding work at gas mains construction achieved in the USSR ex- ceeds the level of mechanization of this work in the USA. In the current seven-year period of 1959-1965 it is planned to construct 40 gas mains with the dia- meters of 720-1020 mm. The length of individual gas mains will reach 2000 km. '.I'he program of this construction is being successfully fulfilled. The fulfilment of the plan of gas mains construc- tion for 1959-1965 will make it possible to create a system of gas supply for all the fifteen Union re- publics forming the USSR which will be an impor- tant factor of the further progress of their economy. The consumption of natural and casing-]read gas for public utility services increased during only one year -. 1959 - by 48.6 '/, as compared with 1958. In the USSR all expenditures on gasification of flats used by citizens are made all the expense of the state. People pay only the cost of the gas they use. It A T 1 S 0 F T n C i) I?; V I: 1. () P MI C N T 0-I" GAS IN1)l1S'I'ItY To ensure the fulfilment of the cnvisagcd pulls of gas output increase in the current seven-year period as well as further rapid increase of its output in the following years il is planned to ensure an out- stripping increase of discovered counnrercial gas rc- servcs. The confidence in the reality of adopted plans of increasing commercial gas reserves, necessary for rapid development of gas industry, increase of the share of gas in the fuel balance of tit(., country and supplying rapidly developing chemical industry with raw materials, is based on the results of geo- physical and geological prospecting, exploratory and drilling work, carried out in recent years in the . territory of the USS11 It was found by this work that commercial accu- mulations of gas and gas condensate are distributed nearly along the entire cross-section of the deposits presenting the geological structure of the territory of the USSR; at the same time very large gas-herring zones in various regions of our country were dis- covered. The work done made it possible to discover new gas-bearing regions and large natural gas fields. Only for 1959 dill the commercial reserves of natural gas increase by 70% as compared with the reserves which the country had possessed by the beginning of the seven-year period. Parallel with the increase of commercial gas quantities of already known gas fields, for 1959 and the first half-year of 1960 27 new gas fields in va- rious regions of our country were discovered. During the recent years serious success has been achieved in the search for gas, gas-oil and oil fields in a number-of regions of Siberia. The total estimate of natural gas reserves in this region amounts to many billions of cu.m. Very fa- vourable results have been obtained in a number of regions of Central and East Siberia. Within the next few years the volume of geological prospecting and exploratory work for gas in the vast territoires of Siberia, as well as in the northern regions of the Soviet Union will be considerably extended. This undoubtedly will cause discovery of large gas reserves and will make it possible to supply these distrait regions of our country with cheap fuel. The Caspian lowland is the most perspective pro- vince with respect to gas-bearing structures. This region is still very poorly investigated. Here accord- ing to preliminary data entire sedimentary complex from Devon to Tertiary deposits inclusive is an oil- and gas-bearing one. By its geological structure the Caspian depression reminds of the basin of the Gulf of Mexico in the USA where a of all the gas reserves of the USA are concentrated and more than 230 billion cu.m. of gas and up to 70 million t. of oil per annum are pro- duced. he favourable geographical location. of the Cas- pian lowland situated between the principal regions of gas consumption of the European part of the USSR and the Urals makes it especially perspective and subject to intensive prospecting. r-? 1 N C I t I ' A S I () I C A S l t l S I' I t V 1: S T i t t 1 ' . ( 1 S S i t A S ,\ B A S I S Of,' 11 I G 11 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 CVI\ JI a I%rw- 111 1 ' '11 O 1 t 1 . I 11 S l ) I : I ) 1 : \' I I . O I ' \ 1 I ?: \ .I' l) F (i :\ S- :\ N I) G .\ S - l: t) IN I) F IN, S :\ '1' l: F[ 1: I. I) S I\' I' I I I: I ' S S l t immense I)rulilciuz of devclollutenl of nalurll gas and Oil Output inspire the scienlisls, crlginvers anti \~orlcers of ,its and oil indllslry I1) cre:lliye work 1o raise constantly the cconOloic efficiency 1)I' :ill I)rancllcs of, 'ns- and oil-producing industry geo- physical and I)rosl)ecling work, drilling. Iccllnitluc and technology of field develol)nlcnl, well and gas field operal ion. The technology of developnu?nl of gas and gas-oil fields has an intporlance gamily to he Oyer-csliulaletl for increasing economic el'1'iciene?y of gas- and ()il- producing industry. Nor cunlp:u?isiut lei its point out that ctlpilal investment in the development nl' lame gas- and has-oil fields ill so)ne cases Inay exeeed those ill construction of the largest Ihcrlnoeleclric and Ilych?oelectrie, power slat ions, large nlclallurgicul and other plants. The most capital-consuming sh?uclures ill gas and gas-oil fields are wells. Almost in all gas and Oil fields the expenditure on wells nnwunts to more Ilan a half of total expenditure. Therefore a tendency arises to reduce the number of wells in the field as much as possible. But on the other hand, olhcr things being equal, the less the mm11lber of wells, the less the current reservoir production as a whole is and in most eases the less gas or oil take-off is too. 't'hat is why a thorough and comprehensive study of the problenf is neccssar in order to determine the optimum production of both the deposit as it whole and individual wells, that is, to find the most advantageous system of development. This requires a deep analysis and profound knowledge of geo- logical, physical, gals ltvtlrodynufnie and economic factors. Rational system of development of a gas field taking into account the development of other fields must satisfy the country's gas regmirenfents to the full at the minimum national-economic expenditure :tnd ensuring as I'll]] gas and oil take-off of reservoirs (deposits) as possible. It. goes without. saying that the raising of economic efficiency of gas or gas-oil field development by means of reducing the nulubec of wells, must be accompanied by file growlh 1)f their production, so that. (lie total production of the deposit or the field as a whole may not diminish alld gas and oil take-off may remain high. hvidently this may be achieved by means of the optili)unt well spacing on the area, the optimum distance between the wells fully taking into account geological, psysi- cal and gas Ilydrodynantic fcalures, by nlc:nts of rational conditions of well operation and various measures intensifying the processes of devt?lopnurnt. But all this is possible only ill case each of these problems and the System of field development. as a whole are worked out of., more precisely, grounded by means of really scientific methods of designing and analysis of development of gas reservoirs and fields. 'T'hese scientifically-based inelhods of de- signing of rational development of gas, gas-conden- sate and gas-oil deposits in every individual case are based on combined use of mlclhods of geology, geophysics, lulderground gas I)ydrotlynanfics and reservoir physics, IIranch and general economlics, nucle:u? ph\sit?s and modern rlcclrouic conlpuling It-vIolilllic. II gtics wilhuul s;lyiOg Ih;tl flit' nn)dern level of inlrcduc?lion of scientific :fruit 'eniolils inlo the practice of develupn)enl of gas, gas-condeus:tle anll :c;-oil fields will he Iliglicr and higher and our 111ccrclicnl knowledge will alwavs grow only ill case conslaiil and cancel analysis of the achieved is cilstu?cd ;)fill a cancel eslinfale of uin? currcnl tuis- takes and achieyenu?nts is given. Sunuuing 111) the above, we call point owl that by the svslcIll 1)l' developnfenl of gas fields we mean Ilse cunlrnl of the process of gas nfigraliotl ill the reser- voir (tlcl)usil) to wells by 1ucaids of spacing life opli- nunu number of oiler:fling (anti observation) wells, it definite order of their pulling into operation and cslablishlnenl of the opt 01111111 lec?hnological condi- l ions of operation. In the Soviet Union every gas and gas-oil field is developed on the basis of a project of technological schemes of its develupmc?nt. We usually call such schemes a general scheme of development of a field or a deposit. The project of construction of ;t gas or gas-oil field is included as a rule in every genemul scheme of field development. I,et its briefly consider the basic principles of de- sigrting the general schetme of field development and of the project of consh?uclion of the gas field. Al designing the system of dcvelopnfent the main rcquircnu?nt is to get as accurate initial data as pos- sible which would correctly reflect Ilse actual con- dilions of gas (or gas-condensate Oe gas and oil) accullmialiun ill the reservoir. For a long time we lfave already passed on from geological-statistic mnethids of estimation of the pro- cess of development to more strict, scientifically- basetl methods of investigation of the physics anti mechanics of the migration of gases and liquid (Iwo- and three-phase systems) ill porous reservoirs and to the use Of the laws of gas-liquid systems fittru- tion at projecting field development. Methods of geo- logical ill vestigalion of gas and oil deposits as -swell as methods of economic analysis of various systems of development have undef?gone as rapid a progress. An example can be given to conl'irnt this. As a result of :application of scientific principles of de- velopment of'I'11ifnaz:t oil field in the Bashkir ASSII for the first tittle the method of artificial main- tenance of reservoir pressure by means of edge water flood was used inn large oil field. This made it possible to increase rapidly the intensity of using wells as industrial constructions. In this field we gave 11p forilterly used well spacing in the form of h'iangle every 251) nt. and passed on to well spacing ill the forum of ring lines parallel to the internal cOn- four of water-oil contact in accordance with the field slruc.ture. 'T'he chosen distance between the lines was 5(1(1 nt. and between the wells within the lilies -- 101 in. Owing to such well spacing their numhcr was reduced nearly .1'1)111' tinter. The pro- duction of, wells proved to be o1) the level of planned one, high and steady. Fluty production method of Operation was principally applied which has already rent:fined for more than 12 years. This splendid in- d11S11?i;iI experiment carried uul ill one of the largest nil fields Of Ilw world made it possible to luakc lase t,l' the uhlaim'd experience with Currc.4p1)nding 1110- FOR .OFFICIAL USE ONLY Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246A016600230001-2 p flu6CIAL USA Cann e On time b difications in all other gas-oil fields of the Soviet Union. As to purely gas and gas-condensate fields, at pre- sent we do not apply artificial methods of main- tenance of reservoir pressure in them but this ex- perience made it possible to adopt a general method of designing of the system of development of these fields and their analysis in the process of develop- ment. At present for every gas and especially gas- condensate field being developed research and de- sign work is carried out to determine the expediency of using methods of maintenance of reservoir pres- sure. The use of gas hydrodynamic methods to deter- mine, the main technological indices of the process of development by means of electric and other mo- dels is a basic feature of the scientific principles of development designs of gas, gas-condensate and gas- oil fields. Analytical "testing" of many versions of technological schemes of development for a given deposit and obtaining the main indices charac- terizing different versions of a scheme allow as if to makethe reservoir (deposit) work under various conditions, i.e. tinder various depressions, numbers of wells and their spacing, various productions etc. To workout a general technological scheme for gas or gas-condensate field development the geo- logical data of the given geological province and of the deposit or field, physics and hydrodynamics of reservoirs as well as all the technical-economic in dices, are studied in detail. On the basis of studying the general geology and hydrogeology of the, given geological province the sources of pressure in the field and hydraulic head pressure of the water drive system are determined. On the basis of the investigation of gas inflow in wells the permeability of the reservoir and bottom hole zone according to field data, pressure bearing characteristic, reservoir conditions, productivity factor, mechanical strength of the reservoir (or more precisely, that of its bottom hole zone), well pro- duction under various conditions (under constant rate of gas flow from the reservoir to a well, constant depression, constant gradient and constant recovery etc.) are determined; reservoir pressure according to the measurements of the well, gas-water contact, the activity of reservoir waters, the possibility of water coning in wells, the conditions of water con- densate falling out in the well bore etc. are de- termined. Taking into account the above-mentioned factors as well as general dimensions of the structure and the thickness of separate reservoirs, commercial re- serves of gas and condensate are determined and when there are oil rings, oil reserves are determined. Complete absense of leakage on the path of gas movement from the reservoir to the surface is one of the main requirements of the rational scheme of gas field development. Gas seepage from the reservoir through leaks in the casing or in the cement ring between the casing and the well wall or through leaks in the place of contact of the cement ring with rock on the well wall is absolutely intolerable. These strict demands are caused by the necessity both to preserve gas re- serves and to ensure the safety of people living and working in buildings situated in the zone of possible gas migration. asis of the gener:d scheure of field de- velopment a project. of construction of the field is worked out. This project envisages: well head setting tip; series-parallel gas gathering system; gathering, gas purification, dehydration and metering centres; gas gathering pattern; gathering system of pipe lines for gas condensate; water pipe lines and sewerage; power lines and lighting circuits; communication system; roads; fields offices, repair shops, garage etc.; settlements for personnel. If there is a sufficient quantity of gas condensate in the field, gas distilla- tion facilities and plants for additional gas dehydra- tion and purification on head constructions of gas mains are installed. In gas-oil fields besides these installations accord- ing to the quantity of casing-head gas (recovered to- gether with oil) gasoline plants are built, in some cases of large capacity. In the USSR the problems of telecontrol of the principal objects of gas fields are on the whole solved. These objects include wells in operation spaced on vast field territories, the systems of gas gathering and local gas transport, gas separation; purification and dehydration as well as gas teetering. However it is necessary to point out that all work in the field of telecontrol and automation of gas production did not include the principal techno- logical process of gas and gas condensate field development, that is the process of control and re- gulation of gas reservoir operation. One can imagine a reservoir of approximately uniform properties and thickness with wells spaced according to the project of field development. Development drilling of the deposit is completed, rates of development and consequently the level of gas output are determined' too. In this case the control of the process of develop- ment can be based either on the principle of uni- form pressure decrease in the gas deposit or on the principle of uniform gas front advancement. When maintaining reservoir pressure in the pro- cess of gas condensate field development gas and gas-condensate recovery from separate wells as well as distribution of gas repressuring among injection wells must be determined, also according to the principle of uniform gas front advancement. As the operation of some wells is stopped for long terms there will be a very complicated problem of finding in the process of field development for every moment of time, the distribution of the predeter- mined total gas production among separate wells in operation and the total volume of water repressing through injection wells, to preserve the above- mentioned conditions as well as the permissible de- pression value. The problem of the control of the processes in the reservoir characterized by its considerable hetero- geneity will be very complicated too. Automatized control of the process of develop- ment will evidently include: primary instruments supplying information about the current condition of the reservoir and apparatus treating this informa- tion and either making recommendations on the control of this process or directly controlling it by means of actuating mechanisms. At present Soviet experts in automation of gas and oil producing industry are working out such a pro- gram of control. It is evident that in the nearest fiQB OFFICIAL USE ONLY Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246A016600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 FOR OFFICIAL USh UNIT future the solution of these problems will he found by means of special electronic computers combined with electronic analogue computers. These electronic computers and analogue com- puters will also find wide application for the solu- tion of problems of complex designing, rational methods of field development, gas gathering, puri- fication and distant gas transportation. 1V STRUCTURE OF NATURAL GAS UTILIZATION The use of fuel and power resources of our country having the most favourable technical-economic in- dices and thermal characteristics is the general line of the development of fuel and power industry of the Soviet Union for the current seven-year period. Growth of natural gas utilization in the USSR by main consumers during a three-year period, is cha- racterized by the following indices: Ratio of 1959 to 1957 Total growth of gas consumption 1.9 times Growth of gas consumption by: a) public utility services .... 2.4 x b) industry ................ 1.9 Thus priority growth of gas consumption for the above-mentioned period took place with utility ser- vices and despite relatively great difficulties in the gasification of utility consumers as compared with gas supply to industrial enterprises this task is the primary one when' problems of gas supply of the country are being solved. Among industrial consumers the greatest growth took place with metallurgical, chemical and cement industry. Natural gas supply to power stations deserves spe- cial attention. This consumer is of great importance for gas industry because it can not only utilize large quantities of gas but also diminish monthly and daily gas consumption fluctuations. V TECHNICAL-ECONOMIC INDI- CES OF GAS UTILIZATION EFFI- CIENCY IN DIFFERENT BRANCHES OF INDUSTRY AND IN PUBLIC UTILITY SERVICES Wide utilization of natural.gas .in the national economy of the country gives a great economic ef- fect, Suffice it to point out that labour expenditure per I ton of natural gas production (in terms of standard heating value fuel) is about 20 times less than per 1 ton of coal production. The cost of gas production is about 8-10 times less than that of coal production. . When utilizing gas, plants efficiency increases, production quality improves and sanitary labour conditions improve radically. One should bear in mind that the degree of effi- ciency which is achieved by industrial enterprises, when utilizing gas, is different; it depends on many factors, namely on the kind of fuel substituted, its cost, distance of gas transportation, process tech- nology, type of plant units etc. F OFFICIAL USE ONLY Ferrous metal industry is one of the large con- sumers of gas entirely for Ieclinological purposes. Gas utilization in the blast furnaces process (100- 110 cu.ur. of gas per 1 ton of cast iron) makes it possible to reduce coke consumption by 15% as well as to improve the process technology by means of raising blast temperature, decreasing slag share and heat losses Willi off-gases etc. The efficiency of the utilization of natural gas in open-hearth furnaces is also high. In mechanical engineering and metal-working in- dustry a considerable effect is achieved by natural gas utilization. Using gas instead of other kinds of fuel in various heat treatment furnaces and furnaces for punching, pressing and forging improves their efficiency, re- duces fuel consumption, waste and losses from scale. Substituting natural gas for oil fuel in various heat treatment furnaces makes it possible to raise furnace efficiency by 2-4~%, to decrease fuel consumption thanks to better mixing of gas with air as well as to reduce heat losses to the surroundings and with off- gases. Inside factory expenditure on fuel transportation and on other economic items decreases simultane- ously. It should be especially noted that substitution of natural gas for other kinds of fuel in heat treat- ment furnaces facilitates the application of more progressive technology and design of plant units themselves which can be confirmed by the follow- ing comparison of results of calculations made. (in % to the indices of an oil fuel furnace) Oil fuel Gas furnace furnace Ordi- High- nary speed Efficiency ............. 100 110 175 Standard heating value fuel consumption ..... 100 92 59 Waste of metal ......... 100 67 17 Cost of heating ........ 100 92 61 In the industry of building materials natural gas is also widely used. Economic efficiency from gas utilization in this industry is considerable too. In cement industry gas utilization makes it pos- sible to reduce specific fuel expenditure and conse- quently to reduce the cost of a production unit. Besides the efficiency of cement kilns working on gas increases. Cement quality improves, capital investments in building new plants diminish and the total quantity of service personnel is reduced. In electric power stations substitution of gas for solid or liquid fuel greatly affects the reduction of electric power cost. Besides, electric power plants operation on gas causes an increase in the efficiency of boiler plants. Natural gas utilization for gas supply of towns, settlements and rural regions is of great social- econornic importance. Besides the above-mentioned branches of industry and utility consumers natural gas in the USSR is used, for technological purposes in textile, light and food industries as well as in oil-gas industry (for manufacturing of special sorts of carbon black). In all cases natural gas utilization improves technical-economic indices of production and in a Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 o WI-ir1tj1AL U6t UIVLY number of regions this kind of fuel is preferable to others. The highest effect is gained by natural ,its utiliza- tion for technological needs of industry; gas utiliza- tion in energetics is less effective but also in Ibis case indices are incomparably better than at utiliza- tion of solid fuels. VI TOWN GAS 1).1 STIt111UTION SYS1,Eif S Gas supply of towns and settlements in the Soviet Union is carried out mainly on the basis of natural gas. When designing town gas distribution systems a complex solution of all problems of gas supply of utility consumers and industrial enterprises etc. is achieved. Socialist economic system, lack of private pro- perty of land and mineral wealth make it possible, when designing gas distribution systems, to solve problems, connected with gas transport to towns, routes of mains, placing of structures of town gas facilities and organization of their construction etc. in the most rational and economic way. Designing of town gas distribution systems is car- ried out by specialized organizations which solve the problems of gas transport from a gas distribution station to town and by town gas grids to the con- sumer. Gas supply designs are worked out on tht? basis of approved general plans of town planning and building taking into account. their long-term development. This makes it possible to choose the scheme of gas supply correctly and economically and to establish priorities in construction of gas pipe lines and other gas facilities. Designing of-town gas distribution_systems is car- ried out in two stages: design plan with summary estimate-financial calculation of construction cost and working drawings with estimates defining the cost of separate structures. In the project plan the whole complex of pro- blems connected with the construction of gas distri- bution system is solved. These problems include a rational direction of gas utilization combined with other kinds of power supply (electrification and introduction of district heating plants), the choice of a type of the system suitable for the town as a whole and for its various building districts, the choice of types of facilities included by the system and their spacing in the town territory, volume and cost of work, sequence and economy of construction and operation of facilities etc. The following systems are used for town gas distribution depending on pressure: a) single-stage system gas distribution and transport to consumers only by gas pipe lines of one (usually low) pressure; b) two-stage system - gas distribution and trans- port to consumers by gas pipe lines of two pressures (mean and low or high and low) c) three-stage system - gas distribution and trans- port to consumers by gas pipe lines of three pres-, sures (high, mean and low) ; (1) multistage system - gas distribution and trans- port to consumers by gas pipe lines of four or more pressures. 'I'he following vatuus of gas pressure are pernrillecl for town gas pipe lines by the approvers technical standards: a) low pressure gas pipe lines --- up to 300 11,111. \\'(; or tit) to 500 nisi. WC, on condition that it local pressure regulator is installed on every inlet to a building, flat etc.; h) mean pressure gas pipe lines - above 0.05 kg/cni2 and up to 3.0 kg/em2; c) high pressure gas pipe l:g/cut= and up to (i.0 kg/cn-l; (1) high pressure gas Pipe lines - above 0.0 Rg/cin'2 and ill) to 12 kg/C1112; e) gas pipe lines of higher pressures - on condi- tion of their necessity and in accordance with a per- mission of the technical supervision in every indi- vidual case. Gas is supplied to dwelling houses, public build- ings, municipal service buildings and industrial en- terprises from town distribution gas pipe lines of low, mean and high pressure (tip to 6.0 kg/cm2 in- clusive). Gasholder stations, town gas regulation stations and industrial enterprises requiring high pressure gas (gas turbine power plants, chemical and metallurgical plants and plant units equipped with high pressure burners etc.) are connected with town gas pipe lines with pressure above 6.0 kg/cm2 and up to 12 kg/cm2. Gas pipe lines of different pressures are connected only by means of gas regulation stations equipped with pressure regulators and safety devices prevent- ing pressure increase beyond permissible value. The choice of gas distribution system and its pres- sure is determined by the project depending on the area and planning of the town, gas supply sources, Physical and chemical gas parameters, volume of gas consumption, location of municipal services and industrial enterprises to be supplied and gas-holders. This choice is based on corresponding technical- economic calculations.. When designing town gas grids one provides for reliability and regularity of town gas supply, safe operation, easy and simple service, possibility of cutting-off separate town districts or microdistricts, possibility of construction and putting in operation by stages, uniformity of structures and assembly units, minimum material and capital investments and operating costs. Town gas distribution system is calculated for maximum hour consumption determined by means of the combined maximum daily schedule of gas con-' sunsption by all kinds of consumers. Hydraulic calculations of low pressure town gas pipe lines as well as branches and inlets are made to provide for operation of domestic gas apparatuses in the range between nominal and maximum heat loads. It is. assumed that the maximum heat load of domestic gas apparatuses cannot exceed the nominal one more than by 20%c, and decrease of heat load with regard to nominal value can be permitted only for a short term and cannot exceed 20% either. Ihydraulic calculations of mean and high pressure town gas pipe lines, branches and inlets are made to provide for reliable operation of town and industrial gas regulation slatio ns as well as burners of utility FOR OFF1Ci; USE OHL . Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246A016600230001-2 services and industrial enterprises g al7lely Ilie l,rol,lcnis of seasonal regu- within FOP quired range of heat load changes. Town gas pipe lines, irrespective of their purpose and the pressure of transported gas are laid at the depth not less than 11.9 in. from ground surface to the top of the pipe. Crossings of rivers, canals and outer water obstacles are made underwater. When crossing ri- vers with unstable channel and banks, with high velocity flow (above 2 iii/sec), arched crossings, as well as crossings by suspension and specially con- structed bridges are used. In individual cases open layout or suspension of gas pipe lines (with gas pressure up to 3 kg/emm2) to reliable constructions of existing metal and rein= forced concrete motor highway bridges and foot- bridges are used too. In the USSR only steel pipes are used for town gas pipe lines. At present research institutes are investigating the problems of using non-metallic pipes. The construction of town gas pipe ried out by specialized organizations. The technical supervision of the quality of con- struction and assembly work is carried out by a town gas board which is established as soon as the construction of town gas distribution system begins. The same board examines' the objects whose con- struction is finished and later on runs them. The large share of industry in gas consumption in the towns of the USSR makes it comparatively easy to level off daily fluctuations of gas consumption by domestic and utility consumers. When designing town gas supply with natural gas, construction of gas-holder stations is not planned as a rule. It is more difficult to level off weekly fluctuations because on Sundays gas consumption by industrial enterprises and power stations sharply decreases. At present in the towns of the USSR the regulation of week fluctuations is carried out by means of a number of methods depending on local conditions. When towns are supplied with natural gas and are situated near gas fields, gas transport is done according to a schedule corresponding to daily and weekly working conditions of. gas consumption. When towns are situated far from fields, weekly fluctuations are levelled off using the accumulating capacity of gas mains (final section of gas main). In individual cases levelling off is carried out by means of alternating gas supply to large industrial boiler houses or power stations equipped with com- bined gas-oil fuel or gas-coal dust burners. Levelling off considerable monthly fluctuations of gas consumption during the year presents a very complicated problem for town gas system. At present the most widespread method of seasonal regulation of town gas consumption is the method of gas supply to large gas consumers for levelling off gas con- sumption for 5-8 months a year. The rest of time these enterprises work on solid or liquid fuel. A number of drawbacks of this method of seasonal regulation make it necessary in sonic towns to construct special installations for regasification of L.P.G. (propane and butane) using them for peak shaving in winter time. However even these measures of levelling off sea- sonal fluctuations of gas consumption in towns can- lat.ion. For this purpose at l,resenl in the USSR prepara- tions are made to construct underground gas storages near large industrial centres. The method of accumulation of summnmer' gas sur- pluses in underground storages and utilization of these surpluses in winter period ])takes it possible to solve better the problem of levelling off the sea- sonal fluctuations of gas consumption by town con- sumers. The economy of construction of town gas distribu- tion systems varies within wide ranges. This is accounted for by the variety of town planning and building, of the structure of gas consumption, i.e. the share of industrial gas load, of engineering geolo- gical conditions of gas pipe line laying etc. in towns with a large share of industrial gas load and dense spacing of industrial enterprises specific metal and capital investments are considerably less than those in towns with a small share of industrial gas load and sparseness of enterprises throughout the town area. The systems of gas distribution for towns with dense multistory building have more economic tech- nical-economic indices. For towns with sparse few- storeyed building these indices are worse. VII GAS SUPPLY ON THE BASIS OF LIQUEFIED GASES In recent years liquefied petroleum gases (pro- pane, normal butane, izo-butane, propylene, butylene and their mixtures) obtained in processing casing- head gases at gasoline plants, in oil processing and stabilization of oil and gas condensate in fields acquire an ever-growing importance for gas supply of the country. Rapid development of oil and gas industry as well as the fact that there is a wide field for using these gases favour wider utilization of L.P.G. These gases can be used as raw materials for chemical industry, fuel of high calorific value for public utility services, as motor fuel for internal combustion engines (trans- port and stationary ones), as power and technologi- cal fuel in various branches of industry, in agricul- ture, for metal cutting and in other branches of national economy and domestic use. In pre-revolutionary Russia there was no pro- cessing of casing-head oil gas. In 1924 in the town of Grozny the first gasoline plant was put into opera- tion. At present the construction of gasoline plants has considerably gained in sCQpe. Gasoline plants have been constructed in the fields of Bashkiria, Tataria, Kuibishev Region, Azerbaijan and the Ukraine. The seven-year plan of development of national economy of the country envisages a vast program of further construction of such plants. It is planned to construct both powerful stationary plaits for pro- cessing hundreds of millions of cubic metres of gas a year and small mobile units of low capacity for processing up to several millions of cubic metres of gas at year. These plants and units are completely automatized and provide for high recovery of gas fractions in- cluding such gases as propane and ethane. 11 FOR O;I FiC ftiL U'3' Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246A016600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 L; k1i As a. result of realization of planned construction the centre capacity is chosen depending on the local of plants and units, the volume of gas processing will consumers. increase in 1965 by 4 times as compared with 1960. In the USSR work is carried out on construction At present in the USSR it is necessary to improve of liquefied gases (Indergroinul storages in various technological schemes of liquefied gases recovery geological structures (in salt dollies, clays, exhausted to increase gas recovery of the final products in oil and gas reservoirs). connection with rapid development of chemical in- The construction of such storages will make it dustry requiring large quantities of liquefied gases possible to solve problems of levelling off seasonal and with considerable growth of liquefied gases fluctuations of liquefied gas consumption, to satisfy consumption for domestic purposes and for motor better the increased demand of domestic consumers transport. during the cold period of the year, as well as to or- New technological processes with application of ganize more regular railway transportation of lique- cold (low-temperature separation) are being de- fied gases. veloped and used in new-constructed plants. Liquefied gases conversion of motor transport is Continuous method of hydrocarbons recovery by of great importance for the national economy. means of activated carbon permitting to recover all In the nearest future it is planned to convert to propane and 60-70% of ethane is being mastered. L.P.G. a great number of motor cars in Moscow, Le- Besides it is also planned to reconstruct the operat- ningrad, Sverdlovsk, Kuibishev and many other ing gasoline plants. cities. Besides improving technical-economic indices Taking into account the rapidly growing demand this will clear the air of the cities from exhaust of the national economy of the USSR for liquefied gases. gases high rates of their production growth are Liquefied gases exceed high grades of gasolines planned providing for an increase of production in in many indices, namely: 1965 by 38 times as compared with 1958. Liquefied gases are transported by special tank cars or by pipe lines. This latter means of trans- port is growing more and more. A design of a tanker for liquefied gases transportation by water is de- 'eloped. Liquefied gases utilization by utility and domestic Maximum compression Octane ratio number Propane . . . . . . . . . . . . . . 8 -12 112 Buta i -Butane .............. 7 - 8.5 7 - 9 94 103 Ethylated gasoline 6.5-- 7.5 91 The work on increasin < gas A design of lank trucks having the capacity from il g development reserves, improving 4 io 14.5 cu.nn. has , been worked out and their file methods of prospecting, development and opcra- 4 ouction has been organized. tion of gas and gas-condensate fields. and wells, building of gasoline plants, construction of wide gas The produced cylinders for liquefied gases trans- mains network, increasing the production of facili- portation have tl le capacity from 1 to 112 litres. ties for liquefied gases transportation, carried on A system of L.P.G. distribution centres for packing in the USSR, makes it possible to solve successfully up and retail trade of liquefied gases is being the problem of gas supply not only of large industrial created. centres, towns and workmen's settlements, but also L.P.G. distribution centres and group storages be- of a considerable part of-rural regions of the USSR ing constructed have various capacity - from 3 and thus to contribute to the further flowering of thousand to 100 thousand tons a year. In every case our great Motherland. consumers is developing faster than by other con- This makes it possible to raise compression ratio sumers. Liquefied gases consumption for utility and of the engine and correspondingly to increase its domestic use will increase in 1965 by 30 times as power. An increased compression ratio diminishes compared with 1958. specific fuel consumption per power unit, therefore There will be priority development of the group new-constructed engines or engines modernized for system of gas supply of flats. The share of this operation on L.P.G. have higher economic indices of system in the total volume will increase from 10% operation than gasoline engines. Besides, engine ope- in 1960 to 35% in 1965. ration on L.P.G. makes it possible to decrease the The construction of a great number of group stor- consumption of lubricating oils and to increase the ages for L.P.G. to supply rural regions with liquefied engine run between repairs by 100-150%. gases began in the Moscow Region, Byelorussia, Liquefied gases are utilized more and more widely Kasakhstan and its virgin lands, in the Altai terri- in rural regions not only as domestic and utility fuel tory and in some other regions. but also as motor fuel for the engines of agricultural To provide for liquefied gases transportation to machines. utility and domestic consumers mass production of ` Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 STAT Next 2 Page(s) In Document Denied Iq Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 FQR OFFICIAL USE ONLY The construction of gas pipelines in the USSR is expanding year by year. They are built all over the vast territory, in different geographic and climatic environments, and there is a trend towards further increase in their length and size. Standards and specifications regulating pipeline construction are systematically revised to keep them abreast of current developments in construction technique. Pipeline design has been modified to make tensile rather than yield strength of steel the main criterion of pipe quality. The physical characteris- tics of pipes have been improved, resulting in a saving of metal. Gas pipelines in the USSR are built by specialized contractors working under the guidance of the State Gas Industry Department a>GLAVGAS>, and involve assembly line production methods. The various operations involved in laying a pipeline are highly mechanized. Clearing and grading of rights-of-way are accomplished by means of specialized equipment. During the winter construction season, at sub-zero temperatures, special techniques and machinery are used. The field welding of pipelines is accomplished by automatic machines employing the submerged-arc or CO,-shielded are technique. To cut down welding over ditches, pipes are triple-jointed on semi-station- ary yards. The quality of welds is controlled by magnetographic flaw detectors or by gamma-ray radio- graphy. Pipelines are coated mainly with asphalt-based enamels, and, not long since, self-adhesive plastic-tapes became available. Extensive experiments are made in mill coating pipes with silicate enamels and plas- tics. Coating is supplemented by cathodic protection and electric drainage. Rivers, railroads and highways are crossed by carrying pipelines underground, or underwater, or by aerial suspension. Compressor station buildings are constructed of prefabricated frame and cladding sections. Thanks to standardization of constructional sections, and of whole buildings, the general layout of compressor stations has been improved and the number of station buildings lessened. Extensive panels having alu- minum-alloy frames covered with asbestos-cement sheets and stuffed with mineral wool are used as wall sections. Increases in the scale of pipeline construction call for uninterrupted progress of engineering tech- niques. To this end, scientific, planning and constructional organizations are working on a great num- ber of technical, managerial and economic problems in striving for improvements in the quality of steels, in methods of pipeline welding and the prevention of corrosion. for new and better designs and building techniques, with the ultimate objective of raising the level of mechanization of pipeline construction and reducing the cost thereof. FOR OFFICIAL USE ONLY Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 TECIINIQUE OF GAS LINE AND COMPRESSOR Vassilq S. Tnrkin Corresponding Member of 1/re U.S.S.R. Academy of Conslr?rrclion and Archileclare and Alexell N. Yurysheu Engineer, U.S.S.R. Natural gas production and consumption greatly rose in importance for the U.S.S.R. national economy during the last few years. Only three years ago in 1958 natural gas production did not exceed 30 mil- liard cubic meters. In 1965 its production will amount to 150 milliard cubic meters. Intensive growth of the natural gas industry predetermine he steady expansion' of the gas transmission lines con- struction. More than 26 000 km of gaslines will be built in 1959-1965, their total network will rise to 35 000 km. Gas transmission lines construction was started soon after the end of the World War II. No later than in 1947 840 km long, 325 mm diameter Saratov - Moscow gas line was put in service. Since then there was built a number of pipelines extending from gas fields in the Ukraine, Volga area, Stavropol re- gion, Bashkiria and other parts of the country. In 1951 1300 km, 529 mm Dashava-Kiev-Moscow gas line was completed, and in 1958 - 1 300 km Stavro- pol-Moscow gas line made up of two parallel lines 720 mm and 820 mm in size. In 1959-1960 there were put into service such gas lines as Serpukhov-Leningrad, 813 km long and Karadag-Tbilisi, 510 kin long (both - of 720 mm diameter); Dashava-Minsk, 622 km long and Kras- nodar-Serpukhov, 637 km long (both - of 820 mm diameter); Shebelinka-Ostrogozhsk, 246 km long, 1 020 mm in size. A number of other gas lines are under construction at present. Seven-year national economic plan of the U.S.S.R. calls for the construction of two parallel 2 160 km, 1 020 mm gas lines from gas field Gazli, Uzbekistan to Chelyabinsk and Svedrlovsk, Ural. In addition Sverdlovsk will receive gas from newly discovered Berezovo gas field in West Siberia. There will be built a new gas line in East Siberia too, from Ustj-Vilujskoje to Yakutsk. The Kerch strait connecting Black and Azov seas will be crossed by the subwater pipeline destined for transmission of gas from Kuban fields to Crimea. A branchy network of transmission gas lines (fig. 1) will connect all the Union republics of the country. Construction is to be carried in different geographic regions with diverse climatic conditions, including deserts of Central Asia, mountains of the Ural and the Caucasus, peat-bogs of Byelorussia and the Baltic Republics, Siberian taiga with its eternal congelation, and so on. Pipeline construction is characterized by conti- nuous shift of working site and by great saturation with machines and equipment. Gas lines construction impending will differ from that in previous years not only quantitatively but qualitatively too. The lengths of pipelines and their diameters are increasing year by year. It may be worth mentioning that by 1960, 300 mm gas lines constituted only 18 per cent of total mileage, 529 mm - 23 per cent, 720 mm - 27 per cent, and gas lines of larger than 720 min diameter - about 38 per cent. Volume of gas transported via pipelines taken in rela- tion to one kilometer of their length amounts in the U.S.A. to 990 000 cubic meters. In the U.S.S.R. it is already 2 080 000 cubic meters and by the end of 1965 it will exceed 4 200 000 cubic meters. Construction of larger diameter pipelines is econo- mically very advantageous. If to take the cost of construction and operation of 300 mm diameter pipe- line for unity, index for 500 mm pipeline will be 0.46, for 700 mm - 0.29, for 800 mm - 0.23 and for 1 020 mm pipeline - only 0.17. It is intended to commence by 1965 the construction of 1 220 mm gas lines. From time to time Codes for gas transmission and distribution piping systems governing their design and construction are revised to keel) them abreast of current developments in engineering and fabrication techniques. In 1960 a new draft of the Code was pre- pared with a special attention to the problems of strength and safety and that of determination of the optimal diameter. As the long distance gas lines construction requires big quantities of steel its spar- ing becomes especially important. This draft envisages a substantial change of the pipeline design procedure officially approved five years ago was substancially changed. According to the original rules pipelines were designed proceeding from the carrying capacity of pipes determined by the yield strength. As the yield strength was made the main criterion of pipes quality it was very na- turale that the pipe industry aimed at raising yield strength by all technically conceivable means first of all by cold expansion. As was clearly shown by theoretical research and experimental studies cold expansion not contributing to raising of pipes carry- ing capacity in effect led to deterioration of their plasticity and ductility. It was shown that actual be- FOR OFFICIAL USE QNLJ Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 PMrA /R.}ro/ ~)I i n f~ I/ } KNEE < ,Jlrislol>. tapes made of asphalt, asbestos pow- der, plasticizers and crushed rubber used as a filling agent (10---50 per cent of weight). In normal condi- tions enamel is applied in one coat 3 trim thick and wrapped by craft paper. In highly aggressive media coating system is strengthened. Before 1959 such heavy coating system consisted of two coats of as- phalt each 3 mm thick, the first of which was wrapped by asphalt-saturated asbestos felt and the second - by. craft paper. At present coating system applied in critical media consists of one coat of rubberized asphalt enamel, 3 mm thick, wrapped by ?Brisol>, 1.5 mm thick and by 'craft paper. For extra heavy coating use is made of 2.5 nrm thick > Brisola all other components being the same as in heavy coating. The modification of heavy and extra heavy VI COATING OF THE GAS LINES coating systems design made coating operation less labour-consuming and facilitated its mechanization. All the buried gas lines are protected from soil In the present-day practice of pipeline construe- and stray currents corrosion by coatings and ca- lion the following method is finding ever wider thodic installations. Nowadays pipe cleaning, coating application. Welded continuous string of pipe is laid and wrapping are performed directly on the right- on ledgers not further than 2 m from the ditch. The of-way. Pipes are cleaned by line-mounted self- first side-boom tractor accompanying pipe cleaning travelling machines, of which most commonly used machines transfers the pipe to the ditch edge, and are one-and-two-rotor machines OML (fig. 14) pow- other pipelayers located in the section where the ered by 110 h.p. engines. As cleaning instruments coating machine operates line the string up with scrapers, ball and flat brushes secured on the rotors the ditch axis and lay it down onto the ditch floor are used. When cleaning 720 rnm pipes productivity (fig. 15). Continuity of the coating is controlled by of the one-rotor machine amounts to 550-600 in per a flaw detector and its thickness -- by a magnetic device. FOR OFFICIAL USE ONLY Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 ran UMWii" Asphalt base enamel is applied by self-travelling A technique of clr?ctrostalic?pipe painting with line-mounted machines spraying it through the ring silicate enamels Incited as painted by high frequen- nozzle or simply pouring the enaiuel on the upper cy current is being tested on the mills. part of the pipe and spreading in with brushes or Soil corrosion prevention of buried pipelines with slings. When applying one-coat heavy coating ura- the organic coatings is supplemented by electric chines are provided with elastic cap helping to re- protection by means of cathodic and sacrificial gulate the thickness of the enamel applied. Thanks anodic; installations. Capacity of the cathodic sta- to high efficiency of the coating machines coaling lions is determined by the pipeline size and organic crew goes ahead at a pace of up to 2000 in per shift coating qualify. At present stations rated for 150, (when laying a 820 nun pipeline). 300 and 600 watts are manufactured (fig. 17). If Enamel is manufactured directly in the field on such a station lays far from outside power sources, special yards having the melting pots and cony- electric power required is obtained from wind- pounding equipment. Sometimes factory made rub- driven or thermoelectric generators and galvanic bermzes asphalt enamel is used which qualities makc anodes. it acceptable for widely divergent climatic condi- tions. Not rarely for corrosion protection of pipelines self-adhesive PVC tapes are used which are wrapped on the previously cleaned pipe by a relatively light machine (fig. 10). Its qualities make one coat of PVC tape 0.3 mm thick at least equivalent to a nor- mal type coating system on a base of rubberized as- phalt enamel. Heavy and extra heavy coatings are made with 50 per cent overlap providing the double coat of tape. Labour productivity when using this tape coating material increases two-fold. Pipe coating directly on the right-of-way though almost completely mechanized still requires move- ment along the route of a great quantity of equip- nrent and material. Sometimes weal her presents serious difficulties not rarely causing interruption of the work. This stimulated the organization of se- mi-stationary coating yards where the 36 in long triple-jointed sections of pipe are coaled with rub- berized asphalt enamel and wrapped with fiber- glass fabric or ?llrisoh>. Still the steady expansion of pipeline construc- tion makes it prerequisite to organize mill-coaling of the pipes. For this purpose a technique of mill coating of pipes heated in the process of their m;inu- facture with PVC powder is elaborated. According to the econonlic estimates such it coaling will he cheaper and better than traditional ones. Coating operation becomes considerably less labour-eonsit nr- ing. For pipeline protection against stray currents di- rect or polarized drainage installations, insulated joints etc. are used. They oppose the stray currents flow to the pipeline and drain off currents which had reached the pipe. Polarized drainage installa- tions are rated for 100 (fig. 18) and 500 amperes. Pipeline routes cross different natural and uaan- micole obstacles which call forth different designs and construction techniques. Cold handing of pipes for making changes ill tile . FOR O FaC 106L ~ Qs ~_ Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 direction of pipeline, is performed by special pipe- bending machines (fig. 19). 't'hese machines are de- signed for bending definite sizes of pipe with the curvature radius of 6 in - for 219, 27:3 and 325 mm pipes, 7 in -- for 426 nun, 12 in - for 524 mm, 30 in - for 720 and 820 mm, and 40 in - for 1020 mm pipes. Railroad and highway crossings of pipelines are usually made underground either by driving or by horizontal boring (fig. 20). Narrow rivers and ravines are crossed aerially on trestles (fig. 21). Across the wider rivers suspended aerial crossings are made. For instance crossing Aniu-Daria river by two parallel 1020 mm gas lines is designed as suspended bridge. Major river, lake, bay and strait crossings are laid mainly in floorbed. Subwater ditches are made by special equipment, in rock and heavy consolidated clay the blasting method is used. Fig. 19. Machine for bending 1020 nun pipes On the navigable rivers dredgers capable of mak- ing ditched in 4.5-16.0 m deep waters are used. On the innavigable watercourses subwater trenches are excavated by draglines, by blasting etc. Laying a pipeline into subwater trench is per- formed by pulling the whole welded string of pipe, by lengthwise welding and drowning from barges and so on. Very often the negative buoyancy of pipelines is enlarged by reinforced concrete weights. For this job in many instances helicopters are used. VIII CONSTRUCTION OF COMPRESSOR AND PRESSURE REGULATING STATIONS Cost of compressor and pressure reducing stations, and other aboveground structures constitutes about 23-27 per cent of total initial cost of gas lines. Compressor stations are equipped with centrifugal gas turbine or electric motor driven compressors, and reciprocating turbocharged gas engine driven compressors. Type of compressor aggregate (com- pressor+prime mover) determines the general lay- out not only of the compressor building but of the station as a whole too. Compressor station buildings are typified and erected of prefabricated elements. According to a standard layout scheme each station has two main buildings: technological and administrative (fig. 22). If on the technical reasons a certain item of equip- ment cannot be blocked with other machines build- ing which houses this equipment may be erected separately. Still the total number of such separate buildings is not to exceed two or three for a station. As a rule these are small buildings incomparable in size with main ones. Blocking of the buildings and equipment permitted to diminish considerably sta- tion territory and length of station piping and other buried structures, and roads. Water cooling towers are substituted by air cool- ing installations, vertical type dust separators give way to oil filters. Compressor room together with personal ac- comodations is usually a two-span industrial-type building. Foundations for building frames and engin- es are made of cast-in-situ concrete. For columns, floor beams and crane runways prefabricated ele- ments are used. It is planned to use prefabricated elements for foundations either. For, curtain walls use is made of light panels with aluminum alloy carcass covered with asbestos-cement sheets and stuffed with mineral wool thermal insulating materi- al (fig. 23). Typified panels are 6 x 1.2 in, their unit weight approximates 50 kg/m2. Concrete foundations P 111 i! ,':~, r; ~.. FOB Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 p,~~ l 2 - "21- MR Fig. 22. Artist's view of 12 reciprocating compressors' station Fig. 23. Erection of frames and curtaining walls of com- pressor building are cast in multiple-use inventory forms with con- duits fixing wells for anchor bolts. All t1 he building and installation works are done in accordance with a schedule fixing the exact dates of starting and finishing certain stages of operations. Use of the prefabricated elements considerably speeds up the compressor stations construction. Gas lines construction in the USSR is a scene of steady expansion. Total length of pipelines built in 1959 in comparison to 1950 increased six-fold. 3853 km of transmission gas lines were 'put in service in 1959, while in 1950-1955 length of the gas lines built amounted to only 3024 km. Labour consumption in relation to 1 km of gas line considerably diminished, while outpup per worker increased. If in 1955 building 1,000,000 roubles worth of pipelines demanded 26 fulltime workers, in 1959 corresponding figure was only 15. Raising the normal 7-hour day progress of the spread to 1.5-2.0 km demands modernization of building equipment. Construction of 1020 mm gas lines in particular stipulates the development of new machinery and new building techniques. Systematic growth of pipeline construction makes it possible and advantageous to typify all the above- ground structures and buildings and line compo- nents (elbows, bends, valves, fittings etc.). Full rea- lization of this typification program will result in still more considerable growth of labour producti- vity in the pipe line construction. Quantitative and qualitative changes in gas line construction make it prerequisite to solve all the technical, organizational and economical problems in their interconnections as a unity. The main task of the research, design, industrial and building organizations is to speed up development and in- troduction into practice of more advanced tech- niques characterized by use of new better materials, machines and mechanisms, of better designs, and more rational organizational forms of construction leading to improving its economy. Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2 1. Code for design and construction of gas transmission lines. VNIIST of the USSR GLAVGAS, Moscow, 1960. 2. Standards of acceptability of gas transmission lines. SN 83-60. Gosstrojizdat, Moscow, 1960. 3. Magazine ?Pipcline construction)) for 1959 and 1960. Moscow, Gostoptechizdat. 4. Actual working conditions of pipeline and reservoir constructions ))Transactions of the VNIISTROJNEFTs, v. IX, Moscow, 1957. 5. Gas industry in 1960. A. K. Kortunov. Magazine > Gas industry?, N 1, Gostoptechizdat, Moscow 1960. 6. Technical advance and cheapening of the pipeline construction. A. K. Kortunov, Transzheldorizdat, Mos- cow 1958. 7. Development of the Soviet gas industry. Yu. I. Boxer- man, Gostoptechizdat, Moscow, 1958. 8. On the carrying capacity of the steel pipelines. V. S. Turkin, Magazine ))Construction Technique and Engineering Design)), Gosstrojizdat, Moscow, 1960. 9. Scientific and technical problems of pipeline con- struction. V. S. Turkin, ?Gas technique publication N 2s, GOSINTI, Moscow, 1959. 10. Bending of pipes in elastic-plastic stage. V. S. Turkin, Magazine ?Pipcline Construction)), Gostoptechizdat, Moscow, 1960. 11. Field testing of buried steel thin-walled large-dia- meter piping for strength and stability. S. V. Vino- gradov and Yu. M. Kruzhalov, VNIIST, Moscow, 1959. 12. Pipe bending. A. I. Galperin, Gosstrojizdat, Moscow, 1958. 13. Industrialization of pipeline construction. O. M. Ivantzov, Gostoptechizdat, Moscow, 1960. 14. Pipeline construction in the mine workings areas. A. G. Kamershtejn, Gosstrojizdat, Moscow, 1957. 15. Subwater pipeline construction. S. I. Levin, Gostop- techizdat, Moscow, 1957. 16. Pipeline welding technology. V. D. Taran, Gostop- techizdat, Moscow, 1960. 17. Welding of transmission and refinery pipelines. A. S. Falkenvich, Gostoptechizdat, Moscow, 1958. 18. Automatic C02-sheldcd are welding of unrolled pipes. VNIIST of the USSR GLAVGAS, Moscow, 1960. 19. Advanced methods of pipeline constructions. Gostop- techizdat, Moscow, 1960. Declassified in Part - Sanitized Copy Approved for Release 2011/12/13: CIA-RDP80T00246AO16600230001-2