USSR: PROSPECTS FOR REDUCED IMPORTS OF LARGE-DIAMETER PIPE

Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Directorate of Intelligence USSR: Prospects for Reduced Imports of Large-Diameter Pipe SOV 83-10190 IA 83-10119 November 1983 Copy 4 2 0 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Directorate of Intelligence USSR: Prospects for Reduced Imports of Large-Diameter Pipe A Research Paper This paper was prepared by nf the, Office, of Snyiet Ann] , and SOYA. Comments and queries are welcome and may be addressed to the Chief, Soviet Economy Division, SOVA Secret SOV 83-10190 IA 83-10119 November 1983 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 25X1 25X1 2 A11 25X1 25X1 25X1 25X1  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Secret USSR: Prospects for Reduced Imports of Large-Diameter Pipe F__] Key Judgments Information available as of I September 1983 was used in this report. Since the early 1960s imported large-diameter (1,020- to 1,420-mm) pipe has played a key role in Soviet construction of oil and gas pipelines. Many projects now under way, including the Siberia-to-Western Europe gas- export pipeline, rely almost exclusively on imported 1,420-mm pipe 1,420-mm gas pipelines. During 1981-85 we project that the Soviets will import about 2.2 million 25X1 tons of 1,420-mm pipe annually. In addition; domestic 1,420-mm pipe production (about 400,000 tons per year) will depend on imports of high- strength, low-alloy (HSLA) steel plate. Thus, at least through 1985, the USSR will be almost totally dependent on the West for an annual average of 2.6 million tons of 1,420-mm pipe and steel plate suitable for use in Some time after 1985, however, and probably no later than 1990, the USSR will be able to cut back on its imports of 1,420-mm pipe. It will need less foreign pipe because of a likely slowdown in the pace of construction of domestic oil and gas pipelines during 1986-90 and an increase in domestic capacity for manufacturing 1,420-mm pipe using a process that does not require high-quality steel plate. Our analysis indicates that, barring unexpected additions to the gas pipeline construction program, annual Soviet requirements for 1,420-mm pipe for gas pipeline construction will drop from 2.6 million tons during 1981-85 to about 1.8 million tons during 1986-90. At the same time, we be- lieve that Soviet production of 1,420-mm pipe suitable for use in gas pipelines may rise by roughly 900,000 tons to 1.3 million tons annually during 1986-90. The startup and expansion of output at a new pipe mill at Vyksa (near Moscow) should add some 500,000 tons to Soviet capacity for production of 1,420-mm pipe. In addition, capacity available for 1,420-mm pipe production at Khartsyzsk (in the Ukraine) will increase from 400,000 tons in 1982 to as much as 800,000 tons by the end of the decade. At Vyksa the Soviets already have started production of 1,420-mm multilayered pipe. This pipe does not require HSLA steel plate and is capable of operating at 75 atmospheres (about 1,102 pounds per square inch) of pressure. Soviet production technology is far behind state-of-the- art single-walled pipe-the technique used exclusively in the West. The increased metal, energy, and welding requirements of Soviet technology would make the process prohibitively expensive in the West. Nevertheless, iii Secret SOV 83-10190 IA 83-10119 November 1983 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 US metallurgical experts are convinced that the Soviet pipe will work as planned. We believe that the Soviet commitment to manufacture 1,420- mm pipe despite the high costs involved reflects Moscow's ongoing concern about possible vulnerability to Western sanctions and a desire to conserve hard currency. Pipe production at the Khartsyzsk mill, however, will require HSLA plate. Although the Soviets are currently building a rolling mill-which may be operational in 1985 or 1986-to provide HSLA steel plate for the pipe plant, the Soviet track record indicates that the Soviets will, at best, slowly develop a capability to produce HSLA steel plate for civilian consumers during 1986-90. Thus, with Moscow's requirements for 1,420-mm pipe projected at 1.8 million tons annually during 1986-90 and domestic production increasing to as much as 1.3 million tons during this period, imports of 1,420-mm pipe could decline by 1.7 million tons while imports of less expensive steel plate increase by 400,000 tons. We estimate that annual Soviet expenditures for 1,420-mm pipe and HSLA plate for manufacture of pipe could fall during 1986-90 to as little as $500 million compared with $1.3 billion during 1981-85. In a best case scenario from the Soviet viewpoint, if development of HSLA steel plate proceeds smoothly to support 1,420-mm pipe produc- tion at the Khartsyzsk mill, imports of steel plate could decline to negligible levels A substantial drop in Soviet imports of 1,420-mm pipe would most affect Japan and West Germany-the USSR's largest suppliers. Increased Soviet output of 1,420-mm pipe, however, will be phased in over a period of several years, giving Western suppliers some breathing room. The Soviets also would want to avoid the political consequences that would result from any sharp unexpected cuts in orders placed in countries with which the USSR is trying to improve political ties Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Secret Key Judgments Background The Role of Imports 1 Requirements Versus Production Capacity 3 Pipe Requirements During 1981-85 3 Pipe Requirements During 1986-90 4 Soviet Production Capacity During 1986-90 6 Implications 8 Hard Currency Impact 9 Impact on Western Suppliers 9 A. Methodology for Estimating Requirements for Soviet Gas Pipeline Construction, 1986-90 11 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Secret USSR: Prospects for Reduced Imports of Large-Diameter Pip The bulk of the Soviet Union's petroleum resources are located in remote areas of Western Siberia. To transport oil and gas' from these areas to the western industrial regions of the country, the Soviets laid more than 90,000 km of large-diameter oil and gas trans- mission pipelines by the end of 1982.' Large-diameter pipelines transport oil and gas much more efficiently than smaller diameter pipelines and have played an important role in the exploitation of West Siberian and Central Asian oil and gas fields This paper discusses'the development of the Soviet large-diameter pipe industry since 1960 and the role of imported pipe in Soviet construction of oil and gas pipelines. It then examines Soviet plans to increase production of large-diameter pipe and estimates pipe requirements for Soviet oil and gas pipeline programs and the likely level of supply during 1986-90. The report assesses the USSR's potential to reduce large- diameter pipe imports after 1985 and the effect this reduction would have on overall Soviet hard currency balances. The paper closes with a discussion of some of the political factors that could affect the Soviet decision to reduce dependence on Western suppliers. Appendix A discusses the CIA methodology for esti- mating Soviet large-diameter pipe requirements dur- ing 1986-90. construction of less than 200 kilometers (km) of 1,020- 25X1 mm pipeline. Since then Soviet production has in- creased steadily to about 2.2 million tons in 1982 (see figure 1 and table 1). Although technically still behind the West, the Soviets have made steady gains both in 25X1 increasing the diameter of the pipe and in raising the 25X1 operating pressure these pipes can withstand (see the discussion below on the relationship between pipe 25X1 diameter, operating pressures, and annual capacity). 25X1 Trends in Production In 1962 Soviet production of large-diameter pipe was about 50,000 tons-an amount sufficient to support In 1962 NATO embargoed exports of large-diameter pipe to the USSR in an effort to delay construction of an oil pipeline to Eastern Europe on the grounds that ' "Large-diameter pipe" as defined in this paper has an outside diameter of 1,020 mm or more. The most common sizes are 1,020 mm, 1,220 mm, and .1 420 mm-40, 48, and 56 inches, respective- Figure 1 Soviet Union: Large-Diameter Pipe Production and Imports, 1962-82 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Table 1 Soviet Pipe Production: Chronology of Major Events 1961 Novomoskovsk Pipe Plant began production of 1,020- mm pipe. 1962 NATO embargo imposed on large-diameter pipe; Soviet production of 1,020-mm pipe was 50,000 tons. 1963 Two shops at Khartsyzsk Pipe Plant began 1,020-mm pipe production. Shop at Chelyabinsk Pipe Plant began 1,020-mm pipe production. 1964 Three shops at Zhdanov Pipe Plant began 1,020-mm pipe production. Shops at Chelyabinsk Pipe Plant modified to produce 1,220-mm pipe. Shops at Zhdanov Pipe Plant reconstructed to produce 1,220-mm pipe. 1970 USSR production of 1,020- and 1,220-mm pipe was about 1 million tons. 1971 Volzhskiy Pipe Plant began production. Technology and equipment provided by Czechoslovakia. 1972 Chelyabinsk Pipe Plant reconstructed to produce pipes with thicker walls. 1974 Soviets complete construction of a 1,020- to 1,420-mm pipe mill at Khartsyzsk. 1979 Shop at Khartsyzsk Pipe Plant began limited production of 1,420-mm pipe. 1982 First production of multilayer pipe at Vyksa Pipe Plant. Experimental two-layer 1,420-mm spiral seam success- fully produced at Novomoskovsk Pipe Plant. 1983 Soviets announce that production of 1,420-mm pipe will reach 250,000 tons at Vyksa in 1983. it enhanced Soviet military capabilities. The embargo probably delayed completion of the "Friendship" oil pipeline by about one year.' More importantly, the embargo also accelerated the modification of existing pipe mills and provided impetus to the construction of new, large-diameter pipe mills. By 1965 the USSR was producing about three times as much 1,020-mm pipe as the amount that would have been supplied under the Western contracts canceled by the embar- go. By 1966 the Novomoskovsk, Zhdanov, Chelyabinsk, and Khartsyzsk mills were producing 1,020-mm pipe. Combined output of these plants amounted to about 735,000 tons annually, almost 15 times as large as output in 1962. With memories of the NATO embargo still fresh, Soviet leaders continued their efforts to create domes- tic capacity for the production of 1,220-mm pipe. During 1966-70 the Soviets started to produce 1,220- mm pipe at a new mill at Chelyabinsk. In 1970 Soviet output of 1,020- and 1,220-mm pipe reached about 1 million tons. The Soviets completed mills capable of producing 1,020- to 1,420-mm pipe at Volzhskiy in 1971 and Khartsyzsk in 1974. They could not, however, pro- duce sufficient amounts of steel plate strong enough to operate at 75 atmospheres (atm) of pressure. By increasing the diameter and operating pressures of the pipe, the Soviets can greatly increase the amount of gas flowing through each pipeline and thereby reduce the number of pipelines needed to deliver a given amount of gas. The improvement in pipeline efficien- cy is also mirrored in reduced investment and operat- ing costs (see figure 2 and table 2). For example, a 1,020-mm line operating at 75 atm can handle about 12 billion cubic meters of gas per year, whereas a 1,420-mm line operating at the same pressure can handle 33 billion cubic meters per year. In other words the Soviets would have to build about three 1,020-mm lines running at 75 atm to match the capacity of one 1,420-mm line. In terms of steel requirements, one 1,420-mm line (4,000 km in length) would require about 2.6 million tons of steel pipe. Three 1,020-mm lines of the same length would require about 3.6 million tons of steel pipe. The strength and quality of the pipe also play an important role. For example, a 1,420-mm line at 75 atm can handle about 60 percent more gas than a 1,420-mm line at 55 atm, but it requires stronger, higher quality steel. Soviet production of large-diameter pipe increased steadily during the 1970s, reaching about 2 million tons per annum by the end of the decade. Most of the 25X1 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Secret Figure 2 Large-Diameter Gas Pipeline: Relationship Between Pipe Diameter, Operating Pressures, and Annual Capacity Billion cubic meters 50 1,420-mm pipe / / / / 0 1,220-mm pipe ? 0 25 50 75 100 Operating pressures (atmospheres) Note: The dashed line represents theoretical values. Currently 75 atmospheres is the highest operating pressure of LD gas pipelines. output consisted of 1,020- and 1,220-mm pipe. The information that is available suggests that nearly all of the pipe currently produced in the Soviet Union for high-pressure 1,420-mm gaslines uses steel plate im- ported from the West. The Role of Imports Despite impressive gains in the quantity and quality of their pipe, the Soviets have been highly dependent on the West for large-diameter pipe for the last 25 years. During the 1960s the Soviets imported about 2.8 million tons of pipe, almost all 1,020 to 1,220 mm in diameter. Imports accounted for about 40 percent of total Soviet pipe supply during this period. Table 2 USSR: Investment and Operating Costs for Large-Diameter Gas Pipelines. in the Central Regions a Capital Investment b (rubles/m'lkm) Operating Expense c (rubles) Throughput d (billion m'lyear) 17.5 2.46 12 1,220 mm 16.8 2.29 23 1,420 mm 12.4 2.25 33 a Information is extracted from Soviet energy transport monograph, Ekonomika transporta topliva i energii, Moscow, 1980. b Capital investment for 1 kilometer of pipeline in thousand rubles divided by the expected annual gas throughput (in billion cubic meters). For pipeline construction in the northern regions, capital investment nearly doubles. e Cost in rubles to transport 1 billion cubic meters of gas 1 kilometer. d At 75 atm. the USSR to build an integrated pipeline network connecting all major gasfields with important centers of industry and population Pipe Requirements During 1981-85 On the basis of Soviet media reports, we estimate that the Soviets will lay about 36,000 km of large-diameter oil and gas pipelines during 1981-85. Of this total, 20,000 km will be 1,420 mm in diameter and about 16,000 km will be 1,020 and 1,220 mm. To meet these goals the USSR will need about 13 million tons of 1,420-mm pipe and about 6-7 million tons of 1,020- and 1,220-mm pipe.3 During the 1970s the Soviets began to lay transconti- nental 1,420-mm gaslines. As noted, the Soviets were unable to produce high-quality plate for high-pressure gaslines and were totally dependent on the West, primarily Japan and West Germany, for 1,420-mm pipe as well as steel plate for domestic 1,420-rrim pipe production (see figure 3). During 1971-80, total Soviet pipe imports amounted to an estimated 15 million ' Calculated on the basis that 1 km of 1,420-mm pipe weighs 650 tons, and 1 km of 1,020- and 1,220-mm pipe weighs 300 and 450 25X1 25X1 25X1 25X1 25X1 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Figure 3 Stresses Created by 75-Atmosphere Line Pressure Although an internal line pressure of 75 atmospheres exerts a stress of 77.5 kg per cm2 (1,140 psi) perpendicular to the pipe wall, much larger stresses are created in the tangential direction. This may be visualized by focusing on the area of the pipe enclosed by the blue box. As illustrated in the inset, the internal forces perpendicular to the pipe wall are cumulatively trying to pull apart or "open" the pipe as indicated by the arrows. As the pipe's diameter is increased, maintaining the same operat- ing pressure creates additional stress, and the strength of the steel must be increased. In other words, higher grade steel is required to sustain 75 atmospheres in 1,420-mm pipe than in 1,220-mm pipe. For this reason, linepipe designed for operating at 77.5 kg per cm2 (1,140 psi) is required to have a minimum yield strength of nearly 5,000 kg per cm2. (Yield strength is defined as that maximum force per unit area at which the material returns to its original physical dimensions after the load is removed.) In addition to being unable to make 1,420-mm linepipe for high- pressure operation, the Soviets, until recently, were unable to pro- duce pipe that could be used in arctic conditions. Arctic-grade steels must be resistant to embrittlement caused by the extremely low temperatures, and to fracture propagation, which is enhanced by low temperature. purchases of 2.2 million tons in 1981-82. We anticipate that, to support their 1,420-mm pipe- line program, the Soviets will import about 11 million tons of 1,420-mm pipe and about 2 million tons of steel plate during 1981-85. The import bill for 1,420-mm pipe and steel plate probably will amount to roughly $7 billion (1982 prices) during the current five-year plan. Preliminary information suggests that Soviet imports of 1,420-mm pipe could reach 2.6 million tons in 1983, compared with average annual $60-75 million per year at 1982 prices. Imports of 1,020- and 1,220-mm pipe probably will remain at about 200,000 to 400,000 tons per annum. The combination of imports and domestic production should be more than adequate to cover Soviet require- ments for pipe of these sizes. The associated hard currency outlays will be comparatively minor, about Pipe Requirements During 1986-90 We estimate that annual Soviet requirements for large-diameter pipe will fall during 1986-90, the result of a slowdown in the construction of gas pipelines and a halt in construction of new oil pipe- lines (see table 3). We believe that annual Soviet requirements for 1,420-mm pipe will drop to about 1.8 million tons per annum during 1986-90, compared with about 2.6 million tons per annum during 1981-85. Similarly, annual requirements for 1,020- and 1,220-mm pipe probably will fall to about 1 million tons per year during 1986-90, compared with about 1.3 million tons per annum during the current five-year plan. (Appendix A discusses the basis for the estimates of requirements for pipe for new lines and for replacing pipe in old lines.) would be imported. Our estimate for annual Soviet requirements of 1,420- mm pipe during 1986-90 assumes no additional gas- export pipeline construction during this period. If the Soviets were to build a second gas-export pipeline in the late 1980s, similar to the Siberia-to-Europe line now nearing completion, an additional 3 million tons of pipe would be required-most of which probably Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 becret Table 3 USSR: Installation of Large-Diameter Pipeline Oil (1,020-1,220 mm) 1,300 3,400 8,000 6,900 3,200 NEGL Gas (1,020-1,220 mm) 6,635 14,082 16,103 12,474 13,200 14,000 a Gas (1,420 mm) 0 0 3,708 11,000 20,000 14,000 Total 7,935 17,482 27,811 30,374 36,400 28,000 Oil Pipelines. On the basis of previous analysis, we believe that the USSR will construct no large-diame- ter oil pipelines during 1986-90.` Oil production is increasing at less than 1 percent per year and proba- bly will peak and begin to fall later in the 1980s.s If this estimate is correct, major additions to the pipeline network will not be required. (In any event, because the pipe used for main oil pipelines weighs less than linepipe for gas transmission and the operating pres- sures are not as great, the Soviets can construct long- distance, main transmission oil pipelines entirely with domestic technology:) The pace of construction of large-diameter crude oil pipelines has already slowed from a high of 8,000 km during 1971-75 and 6,900 km during 1976-80 to an estimated 3,200 km during 1981-85; in large part this reflects the slowdown in the growth of oil production. West Siberia currently accounts for more than 50 percent of Soviet crude oil production. Five large- diameter lines currently transport crude oil out of this region, and construction of a sixth line is under way. If this pipeline is placed in service during 1986-90, we estimate that the usable throughput of the West Siberian oil pipeline network will be 8.2 to 8.9 million barrels per day (b/d). This capacity should be more than enough to transport the 7 to 8 million b/d that CIA estimates will be produced in this region in 1990. Although East Siberia and offshore basins in the Kara Sea and Barents Sea may contain abundant oil re- sources, we believe that technological constraints, the absence of economic infrastructure, and the remote- ness of these areas will prevent significant oilfield development until at least 1990 and probably later. Thus, we believe that no oil transmission pipelines will be required from these areas during 1986-90. About 75 percent of the existing large-diameter oil pipelines were built during 1970-80 and probably will remain fundamentally sound until at least 1990. Thus, we believe that the amount of large-diameter pipe needed for replacement of oil pipelines in 1986-90 will be very small, mainly limited to the replacement of short segments. Gas Pipelines. In contrast to oil pipeline construction, Soviet gas pipeline construction has averaged about 30,000 km per five-year period since 1965. The plan for 1981-85 is 48,000 km, including 20,000 km of 1,420-mm pipeline. (We estimate, on the basis of actual construction in 1981 and 1982, that the Soviets will lay about 42,000 km of gaslines during 1981-85.) The growth in the total length of the gas pipeline network was needed to support the steep rise in gas production-from 128 billion cubic meters in 1965 to 501 billion cubic meters in 1982. We estimate that gas production will continue to increase, to about 25X1 25X1 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 595 billion cubic meters in 1985 and to roughly 710 billion cubic meters in 1990. Thus, the need for new gas pipelines will remain great through 1990 The level of gas production in the late 1980s will depend heavily on Soviet success in substituting gas for other fuels in industrial processes, electric power generation, and space heating. How far substitution proceeds will in turn depend on the rate of expansion of the distribution grid carrying gas from the main pipelines to industrial enterprises and to power and heating plants. Underlying this estimate are assump- tions about the absorptive capacity of the market. We think that the ability to market the gas rather than the availability of gas reserves will govern the rate of increase in gas output. The share of large-diameter pipelines in total Soviet gas pipeline construction climbed sharply in the past two decades-from about 30 percent during 1961-65 to 75 percent during 1976-80. For 1,420-mm gas pipelines, the share has increased from nearly 12 percent during 1971-75 to a planned 40 percent in the 1981-85 period. We believe that the trend toward the use of 1,420-mm pipe will continue We estimate that the Soviets will need to lay roughly 25,000 km of new, large-diameter gas pipelines during 1986-90, of which 14,000 km will be 1,420 mm in diameter. We also estimate that the Soviets will lay about 3,000 km of replacement gaslines. Our estimate of planned 1,420-mm gas pipeline con- struction during 1986-90, some 14,000 km, is about 30 percent less than planned construction for the first half of the decade. Some Soviet economists have already commented that the growth of gas production in West Siberia may slow because: ? The cost of pipeline construction in Western Siberia is so great. According to the Soviet pipeline con- struction minister, the total cost of the gas-export pipeline will amount to about 15 billion rubles (about $20 billion). ? The Soviets face limits on the amount of gas that can be absorbed in the domestic economy. Construc- tion of storage and distribution systems is lagging, slowing the substitution of gas for other energy sources. Moreover, the Soviets cannot step up sales of gas to other Communist countries and Western Europe at will. In Eastern Europe, the high proportion of oil used in agriculture and transportation limits possibili- ties for substitution of gas for oil.' According to East European economists, Soviet gas imports may in- crease from 32 billion cubic meters in 1983 to 41-45 billion cubic meters in 1990. Future West European energy import demands may be affected increasingly by energy security considerations Nonetheless, even if Soviet construction of 1,420-mm pipelines slows as we expect, the pace of construction will still be rapid. During 1986-90 the Soviets may build four or five pipelines, each about 3,000 km in length, compared with six such lines during 1981- 85-a pace of pipeline construction unmatched else- where in the world. Soviet Production Capacity During 1986-90 At the same time that Soviet requirements for large- diameter pipe will be falling, domestic production capacity will be increasing. We believe that Soviet production of 1,420-mm pipe suitable for use in gas pipelines may rise by as much as 900,000 tons, to 1.3 million tons per annum some time during 1986-90. The startup and expansion of output at a new pipe mill at Vyksa should add some 500,000 tons to Soviet capacity for production of 1,420-mm pipe. In addi- tion, the capacity available for 1,420-mm pipe pro- duction at Khartsyzsk will increase from 400,000 tons to as much as 800,000 tons. Production at Khart- syzsk, however, may continue to depend on imports of steel plate from the West. Multilayered Pipe at Vyksa. The new mill being built at Vyksa (near Moscow) to produce 1,420-mm pipe will produce a multilayered 1,420-mm pipe, in con- trast to the single-walled pipe imported from the West. The multilayered pipe will be produced from ordinary low-carbon steel sheet-which the Soviets can manufacture-in contrast to the high-strength, low-alloy (HSLA) steel plate used in single-walled Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Secret pipe for high-pressure gasline service. The multilayer technology is far behind the Western state of the art. Because of increased metal, energy, and welding requirements (the pipe is about 50 percent heavier than Western pipe), this kind of pipe would be prohibitively expensive to manufacture in the West.' Nevertheless, US metallurgical experts are certain that the Soviet pipe will work as planned.' (See appendix B for details.) Moreover, it has the impor- tant advantage of not requiring high-quality HSLA steel plate. Construction at Vyksa has proceeded rapidly and should be completed by 1985. The Soviets have announced that the plant will produce 250,000 tons of pipe in 1983 and 500,000 tons in 1985. We estimate that the plant could be operating at full capacity as early as 1986. Production of 1,420-mm Pipe at Khartsyzsk. We estimate that the Soviets will have a requirement for 1.4 million tons per, year of 1,020- and 1,220-mm pipe during 1986-90, 1 million tons for 1,020- and 1,220- mm gas pipeline construction, and a residual require- ment of 400,000 tons for irrigation systems and water mains. Combined output of this pipe in the Chelya- binsk, Zhdanov; Novomoskovsk, and Volzhskiy pipe plants is projected at 1.45 million tons per year (see figure 4). Until recently, the Khartsyzsk plant produced mostly 1,020- and 1,220-mm pipe because the demand for pipe of this size was so great. The Soviets laid about 24,000 km of 1,020- and 1,220-mm oil and gas lines during 1971-75 and 19,500 km during 1976-80. (See appendix A for more details.) We foresee that, with a decline in demand for 1,020- and 1,220-mm pipe, Khartsyzsk may be able to devote some, if not most, of its capacity (about 800,000 tons) to production of 1,420-mm pipe. The Khartsyzsk plant has the fabrica- tion equipment to produce 1,420-mm pipe. It only needs the steel plate with the requisite strength and ductility. ' Because multilayered pipe is heavier than conventional pipe, we have expressed annual production at Vyksa in terms of an equiva- lent weight corresponding to the amount of pipeline that could be laid if conventional, single-layered Western pipe were used 8 The Soviets claim that the pipe produced at Vyksa will be capable of operating at 120 atm of pressure. Although we cannot rule out this claim entirely, most of the evidence suggests that this pipe will According to media reports, the Soviets intend to expand production of 1,420-mm pipe at Khartsyzsk using domestically produced steel plate and strip during 1986-90. The Soviets are adding new steel- making capacity to supply the large amounts of steel sheet and plate the pipe mills will require. most of the sheet and plate will be supplied by new facilities at Novyy Lipetsk, Cherepo- vets, Zhdanov, and by existing facilities at Azovstali. These plants are also 25X1 25X1 equipped with continuous casting equipment which, 25X1 according to our earlier analysis, is another indication of the Soviet Union's potential to produce steel plate of uniformly high quality.' Nonetheless, the Soviet track record indicates that the Soviets will, at best, develop the capability to produce HSLA plate for civilian consumers slowly over the 1986-90 period (see inset). Analysis of open-source Soviet technical journals indicates that limited pro- duction of high-strength, low-alloy plate for use in pipelines began in 1978 at the Azovstal' Steel Works. The Soviets, however, are still importing steel plate for pipe production, suggesting that they have not worked out all the problems in large-scale production of HSLA steel plate. According to a Soviet pipeline construction journal, the Khartsyzsk plant is currently producing about 400,000 tons per year of 1,420-mm pipe. We believe that most of the pipe is produced using plate imported from the West. During 1986-90 about 800,000 tons of capacity will be available at Khartsyzsk for 1,420-mm pipe production. If unable to produce adequate amounts of high-quality HSLA steel plate during 1986-90, the Soviets will have to increase steel plate imports substantially from the current level of 400,000 tons per year to meet the requirements for 1,420-mm pipe production at Khartsyzsk. 25X1 25X1 25X1 25X1 25X1 25X1 25X1 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Figure 4 Soviet Large-Diameter Pipe Plants Baltic Sea ~r} Zhda v 'Khartsy To summarize, we estimate annual Soviet production of 1,420-mm pipe during 1986-90 at 1.3 million tons (500,000 from Vyksa and 800,000 at Khartsyzsk). The steel requirement for manufacture of multilayer pipe at Vyksa can be met readily from Soviet-produced steel sheet. The pipe production at Khartsyzsk, how- ever, may depend to a substantial degree on imported Western plate if the Soviets are unable to produce adequate amounts of HSLA steel plate themselves (see figure 5) Kilometers 1_C? As noted above, Moscow's requirements for 1,420- mm pipe are likely to amount to about 1.8 million tons annually during 1986-90. Soviet production will prob- ably increase from 400,000 tons to about 1.3 million tons per annum during this period, suggesting an import requirement of 500,000 tons of pipe and up to The United States Government has not recognized the incorporation of Estonia, Latvia, and Lithuania into the Soviet Union. Other boundary representation is not necessarily authoritative. Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Secret Steel Plate for Large-Diameter High-Pressure Pipe According to analysis of Soviet technical journals and a report delivered at a metals symposium by a Soviet metallurgist, the Soviet Union was not produc- ing high-strength, low-alloy (HSLA) steel plate strong enough to be used for pipe in gasline service at an operating pressure of 75 atm until the late 1970s (for pipe production). The Soviet military probably pre- empted the vast majority of the HSLA steel plate that was produced. During the late 1970s, the Soviets developed a limit- ed capability for the Khartsyzsk plant. The Soviets had to develop a steel with a composition that was strong enough to permit operation at 75 atm and ductile enough to be used in Arctic conditions with- out additions of molybdenum. (Molybdenum, the primary additive used by Western pipe manufacturers to limit brittleness, is in short supply in the Soviet Union.) We believe that West German involvement in construction of the'new pipe-coating mill at Khart- syzsk indicates the increased importance of this plant. 800,000 tons of steel plate. This estimated require- ment for steel plate imports is based on our assess- ment that the Soviet steel industry still faces many hurdles before it can achieve large-scale production of HSLA steel plate of consistently high quality. In a best case scenario from the Soviet viewpoint, if devel- opment of HSLA steel plate proceeds smoothly to support 1,420-mm pipe production at the Khartsyzsk mill, imports of steel plate could decline to negligible levels. This could reduce the annual import require- ment to as little as 500,000 tons of 1,420-mm pipe and little if any plate by 1990, compared with 2.2 million tons of pipe and 400,000 tons of plate per annum during 1981-85. Hard Currency Impact A cutback in imports of large-diameter pipe and steel plate would clearly help Moscow meet other priority import requirements.10 We estimate that annual Figure 5 Soviet Union: Projected Annual Imports of Steel Plate and 1,420-mm Pipe 0 1981-85a a Projected. b Estimated. Soviet expenditures for 500,000 tons of 1,420-mm pipe and 800,000 tons of steel plate for manufacture of 1,420-mm pipe during 1986-90 could drop to as little as $500 million compared with $1.3 billion during 1981-85. The substitution, of purchases of steel plate for imports of pipe is attractive because the price of steel plate per ton is only about half the price per ton of 1,420-mm pipe. Since our estimates indicate that the USSR will be able to increase hard currency imports little, if at all, in the second half of the decade without a sizable increase in its debt service ratio, a cut in its steel imports would help Moscow significant- Impact on Western Suppliers A substantial drop in Soviet imports of 1,420-mm pipe would most affect Japan and West Germany-the USSR's largest suppliers. Presently, about half of Japanese and virtually all of West German production 25X1 25X1 25X1 25X1 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 of 1,420-mm pipe is earmarked for the Soviet market. Several of the largest West German mills, employing thousands of workers, are currently producing solely for the Soviet market. An abrupt cut in Soviet purchases after 1985 would be especially hard to manage, because it is highly unlikely that any other country will be buying 1,420-mm pipe in the volume the USSR currently imports. The Soviets are unlikely to make sudden and sharp cuts in pipe purchases. We expect that increased Soviet output of 1,420-mm pipe will be phased in over a period of several years, giving Western suppliers some breathing room. Moreover, Western companies are aware of Soviet efforts to produce 1,420-mm pipe and thus are unlikely to be caught by surprise when the Soviets begin to reduce pipe purchases. The Soviets also would want to avoid political conse- quences resulting from any sharp unexpected cuts in orders placed in countries with which the USSR is trying to improve political ties. Political Versus Economic Trade-Offs US experts who have studied the multilayer technol- ogy employed at Vyksa have commented that, if this process were used in a Western plant, costs might be at least double current Western levels because of increased metal and energy requirements. Moreover, each weld in the field will take longer to perform and more pipelayers will be required to handle the heavier pipe sections. We believe that the Soviet commitment to manufac- ture 1,420-mm pipe on a large scale, even at substan- tial economic costs, reflects Moscow's ongoing concern about possible vulnerability of its energy program to Western economic sanctions. Analysis of public statements reveals mounting Soviet skepticism over the benefits of expanded East-West trade and technology transfer from 1977 onward. The recent embargoes probably rekindled earlier Soviet concerns of the vulnerability of Moscow's energy program to Western pressure. Such factors probably reinforced the decision to develop 1,420-mm pipe production capacity despite the high economic costs involved 25X1 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Secret Appendix A Methodology for Estimating Requirements for Soviet Gas Pipeline Construction, 1986-90 The Soviets have not yet published the target for gas pipeline construction during 1986-90. We have esti- mated the requirement by using the past relationship between gas production and the length of the large- diameter gas pipeline network and our estimate of future gas production. The almost complete integration of the gas pipeline network through pipeline interconnections between the gas-producing fields and industrial areas in the Soviet Union tends to minimize the need for new transmission pipelines. Additional capacity in the trunkline system will be concentrated along the corri- dors from West Siberia to regional distribution cen- ters where the new transmission pipelines will tie into the existing network. By 1985 most industrial areas will have access to West Siberian gas via the new transmission pipelines presently operational or under construction and the, existing regional pipeline net- Table 4 USSR: Relationship Between Gas Production and Length of Gas Pipeline Network Year Gas Production (billion m) (a) Length of Network (1,000 km) (b) Ratio (a)-(b) 1965 127.7 41.8 3.05 1970 197.9 67.5 2.93 1975 289.3 99.2 2.90 1980 435 129.7 3.35 1985 595 a 172.2 b 3.45 e CIA estimate. b On the basis of the amount of gas pipeline laid during 1981 and 1982, 17,000 km, we estimate that pipeline construction during 1981-85 will be 42,500 km. This would bring the total length of the gas pipeline network to 172,200 km in 1985. work. If, for example, Central Asia should become a net importer of gas from other regions in the USSR, a new transmission pipeline probably would not have to be built into Central Asia. The reversal of flow in the Central Asia-Urals gas pipeline system would allow Urengoy gas to reach Central Asia (see figure 6). If production from the Orenburg gasfields decreases and is no longer adequate to supply the needed volume of gas to the "Soyuz" gas pipeline (the major pipeline for supply of gas to Eastern Europe), then the recently completed Urengoy-to-Novopskov pipeline could pro- vide gas to the "Soyuz" system, which passes through Novopskov. Alternatively, Urengoy or Central Asian gas could feed the Soyuz gasline via a 1,220-mm gasline, which connects Dombarovskiy on the Central Asian-Urals system with the Orenburg gasfields. According to Soviet media reports, this gasline was built explicitly to link the Orenburg and Central large-diameter pipe requirements will not involve exclusively 1,420-mm pipe and that a substantial requirement for 1,020- and 1,220-mm pipe will exist during 1986-90. During 1971-75 and 1976-80, about 16,000 and 12,500 km of pipeline 1,020 and 1,220 mm in diameter, respectively, were laid. The ratio between annual gas production and the cumulative length of the gas pipeline network in 1980 is now somewhat higher than during 1965-75, and in 1985 it will probably be about 3.45 (see table 4). Using an estimate of 710 billion cubic meters for gas production in 1990, combined with the 1985 ratio of 3.45 billion cubic meters for each 1,000 km of gas pipeline, we estimate that 33,600 km of new gas pipeline may be needed during 1986-90. Asian gasfields. The implementation of large programs to substitute gas for other forms of energy will require additional construction of lateral pipelines for intraregional dis- tribution. For this reason, we believe that the Soviet 25X1 25X1 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Figure 6 Major Gas Pipeline Corridors in the Soviet Union r-y.. Baltic Sea Yeningrad esY crna i rvn-e-S `a ~ Alexsandrov Gay Chelyabinsk Orenburg Orenburg gasfield Dombarovskiy Aral Sea ~)Gazfi gasfield Cer7 ic.I f',S/E Lake Balkhash Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 The United States Government has not recognized the incorporation of Estonia, Latvia, and Lithuania into the Soviet Union. Other boundary representation  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Secret Table 5 USSR: Share of Large-Diameter Gas Pipelines in New Gas Pipeline Construction 1,020-1,220 31.9 54.9 50.8 40.9 NA mm Large-Diameter Gas Pipelines Since 1961-65 the proportion of large-diameter pipe- lines added to the network has more than doubled (see table 5). We believe that the percentage attained during 1976-80, about 75 percent, will probably be maintained throughout the 1980s. Further, during 1981-85 about 40 percent, or 20,000 km, of the planned new pipelines are to be 1,420 mm in diame- ter, and we believe that this percentage will remain as high during 1986-90. In estimating the 1986-90 gas pipeline requirements, we have used the 1981-85 ratio because we believe that the regional patterns of gas production and pipeline construction will be similar during the two periods: ? West Siberia will provide nearly all of the increase in Soviet gas production. New transmission pipe- lines will have to be built from the developing Urengoy gasfield. The Soviet media already have reported that at least three new pipelines will be needed to transport increases in West Siberian gas production during 1986-90 and that another gas- export pipeline may be laid. ? Central Asian gas production as a whole will remain relatively constant. New production from the Daule- tabad fields will supplement declining production from the Gazli and Shatlyk fields. However, the construction of another major transmission pipeline from this area probably will not be required. The Central Asian system includes six transmission pipelines (two to the, Urals region and four to the European USSR). ? Although gas production in the older gasfields of the Ukraine and the Caucasus will continue to decline, new transmission pipelines from Urengoy will offset the effects of those regional production decreases. During 1981-85, according to Soviet media, two gaslines will be built to the Ukraine, one to Kharkov and the other to Kiev. These reports also indicate that one of the lines is already under construction. Because of the large industrial base in the Ukraine, some large-diameter lateral transmission gaslines (1,020 and 1,220 mm) probably will be required for this area. Therefore, 75 percent of the estimated 1986-90 re- quirement of 33,600 km yields some 25,000 km of new large-diameter gas pipeline of which 14,000 km (40 percent of 33,600 km) will be 1,420 mm in diameter. The estimated 14,000 km of 1,420-mm gasline would enable the Soviets to build four or five gaslines from the Urengoy gasfields to the European USSR with an average length of about 3,000 km. This estimate is generally consistent with the frag- mentary Soviet media reports on gasline construction planned for 1986-90. Replacement Requirements. Most pipelines built in the United States have a planned life expectancy of 20 years, although they usually last longer than this. In contrast, the replace- ment-free life for steel pipe in temperate areas of the USSR is 11 years when bituminous coated and 17 years when wrapped with tape, according to a 1982 Petrostudies estimate. some gas roes in the harsh climate of West Siberia and in the acidic soil of Central Asia have required replacement of lengthy segments after only 10 years of operation. Accordingly, we estimate that the replacement-free life for most Soviet gas pipelines is about 15 years (compared with 20 years for oil pipelines), and that subsequent replacement of pipeline segments is required at the rate of about 1 percent a year. We believe that, at least until 1985, Soviet replace- ment requirements for gas pipelines will be small. About 80 percent of the Soviet Union's 1,420-mm gas pipelines were laid after 1975 and probably are, with 25X1 25X1 25X1 25X1 25X1 25X1 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Secret Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Table 6 Soviet Large-Diameter Pipe Production Plants Method Millimeters Floorspace (m') Production, 1985 In 1975 1976-83 Expansion, 1984-85 (tons) Chelyabinsk Longitudinal (two seam) 1,020 1,220 168,509 0 0 700,000 Khartsyzsk Longitudinal (two seam) 1,020 1,220 1,420 87,293 0 0 820,000 Volzhskiy Longitudinal (two seam) Spiral 1,020 1,220 1,420 306,665 150,321 0 450,000 Vyksa Multilayer 1,420 0 126,540 126,540 500,000 b Zhdanov Spiral 1,020 132,846 0 60,000 Total 791,651 298,454 178,284 2,710,000 a Large-diameter pipe production includes 30,000 tons expected to come on line by 1985. b Because the multilayered pipe at Vyksa is about 50 percent heavier than conventional pipe, we have equated estimated annual production at Vyksa to an equivalent weight corresponding to the amount of pipeline that could be laid if conventional single-layer Western pipe were used. the exception of some individual small segments, still already been replaced. Therefore, we estimate a total in good order. The Soviets, however, laid some 16,000 requirement of large-diameter pipe for 1986-90 of km of 1,020- and 1,220-mm gas pipelines during about 28,000 km, of which 25,000 km will be for new 1971-75. Of these, we believe that at least 5 percent, construction and some 2,800 km for replacement of or 800 km, will require replacement during 1986-90. older lines. We also estimate that 10 percent, or about 2,000 km, of the pipeline built during 1961-70 will also require replacement-indeed, some segments probably have Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Iq Next 8 Page(s) In Document Denied 25X1 25X1 25X1 25X1 Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7  Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7 Secret Secret Sanitized Copy Approved for Release 2011/08/03: CIA-RDP84T00926R000200020004-7