GOST 26802-86
GOST 26802−86 antifriction powder Materials based on iron. Stamps (Change No. 1)
GOST 26802−86
Group 56
STATE STANDARD OF THE USSR
ANTIFRICTION POWDER MATERIALS BASED ON IRON
Brand
Iron-based powder antifriction materials. Types
AXTU 1479
Valid from 01.01.87
before 01.01.92*
_______________________________
* Expiration removed by resolution
Gosstandart of the USSR from
(IUS N 9, 1991). -
Note the manufacturer’s database.
DEVELOPED by the Academy of Sciences of the Ukrainian SSR
PERFORMERS
V. N. Klimenko, M. Simonovic, I. M. Fedorchenko, L. I. Pugina, A. E. Kushchevsky, A. T. Pekarík, L. D. Bernatsky
INTRODUCED by the Academy of Sciences of the Ukrainian SSR
Vice-President I. K. pokhodnya
APPROVED AND put INTO EFFECT by Decision of the USSR State Committee on standards of January 20, 1986 N 149
The Change N 1, approved and put into effect by the Decree of the USSR State Committee on management of quality and standards from
Change No. 1 made by the manufacturer of the database in the text IUS N 3, 1990
1. This standard applies to antifriction powder materials based on iron, designed for parts of friction units of machines and mechanisms.
The standard does not apply to powder materials after heat treatment.
The standard corresponds to the international standard ISO 5755/1 in part brands PA-F and PA-R.
(Changed edition, Rev. N 1).
2. Brand chemical composition and physico-mechanical properties of antifriction powder materials based on iron shall be as given in the table.
| Brand |
Mass fraction of elements, % |
Physico-mechanical properties | ||||||||||
| Same- Le zo |
Nickel |
Copper |
Foz Fort |
Molyb- den |
Carbon rod |
Sulfur |
Other compo- substrates |
Poris- toast, % |
Solid ness of HB, MPa, not less |
The maximum tensile radial- |
Microstructure | |
| PA-W |
OS- tal Noah |
- |
- |
- |
- |
Not more than 0.3 |
- |
- |
17−34 |
200 |
120 170 (with a porosity of not more than 22%) |
Ferrite, pores, allowed the perlite to 20% |
| PA-ZHD |
« |
- |
2,5−3,5 |
- |
- |
Not more than 0.3 |
- |
- |
12−28 |
450 |
225 | The same |
| PA-ЖД5 |
« |
- |
4,8−10,0 |
- |
- |
Not more than 0.5 | - |
- |
16−27 |
500 |
270 | The same permitted individual inclusions of copper and cementite to 10% |
| PA-LCD |
« |
- |
- |
- |
- |
Not more than 0.3 | 0,1−0,5 |
- |
17−22 |
400 |
155 | Ferrite, inclusions of sulfides, pore, allowed the perlite to 20%, a separate on cement to 5% |
| PA-ZHDK |
« |
- |
2,3−3,5 |
- |
- |
Not more than 0.5 |
0,2−0,4 |
- |
15−23 |
450 |
225 | Ferrite, inclusions of sulfides, pore, allowed the perlite to 20%, a separate on cement to 5% |
| PA-HUD |
« |
- |
- |
- |
- |
0,5−1,2 |
- |
- |
15−25 |
500 |
125 | Perlite, pores allowed ferrite to 40%, on and the torn mesh of cementite to 10% inclusions of graphite |
| PA-ЖГр2 |
« |
- |
- |
- |
- |
1,4−2,0 |
- |
- |
15−25 |
500 |
100 | Perlite, graphite, the pores allowed ferrite to 40% inclusions of cementite to 10% |
| PA-ЖГр3 |
« |
- |
- |
- |
- |
2,2−3,2 |
- |
- |
15−25 |
450 |
100 | The same |
| PA-Ggrd |
« |
- |
2,3−3,5 |
- |
- |
0,5−1,2 |
- |
- |
15−25 |
600 |
225 |
Perlite, pores, allowed ferrite to 40%, on and the torn mesh of cementite to 10% inclusions of graphite |
| PA-ЖГр2Д |
« |
- |
2,5−3,0 |
- |
- |
1,5−2,8 |
- |
- |
13−23 |
600 |
180 |
Perlite, graphite, the pores allowed ferrite to 40% inclusions of cementite to 10% |
| PA-ЖГрД5 |
« |
- |
4,8−10,0 |
- |
- |
0,7−1,3 |
- |
- |
16−27 |
500 |
225 | Perlite, pores allowed ferrite to 40%, on and the torn mesh of cementite to 10% inclusions of graphite and copper |
| PA-Ggrc |
« |
- |
- |
- |
- |
0,6−1,2 |
0,6−1,0 |
- |
17−23 |
500 |
125 | Perlite, inclusions of sulfides, pore, allowed ferrite to 40%, on and torn mesh cementite to 15% inclusions of graphite |
| PA-ЖГр2К |
« |
- |
- |
- |
- |
2,0−2,8 |
0,6−1,0 |
- |
17−25 |
600 |
135 | Perlite, graphite, inclusions of sulfides, pore allowed ferrite to 40%, individual inclusions of cementite to 15% |
| PA-Ghrdc |
« |
- |
2,3−3,5 |
- |
- |
0,8−1,5 |
0,2−0,5 |
- |
15−25 |
600 |
180 | Perlite, inclusions of sulfides, pore allowed ferrite to 40%, on and the torn mesh of cement to 15% and the inclusion of graphite |
| PA-ЖГрДК1 |
« |
- |
2,3−3,5 |
- |
- |
0,5−1,2 |
0,6−1,0 |
- |
17−25 |
600 |
180 | The same |
| PA-ЖГрДК6 |
« |
- |
2,7−3,5 |
- |
- |
0,6−1,5 |
1,6−6,0 |
- |
18−25 |
600 |
200 | Granular perlite, a solid solution of copper in iron, sulfides, pore, allowed the inclusion and torn mesh cementite and inclusion of graphite |
| PA-Ggrl |
« |
- |
12,0−15,0** |
- |
- |
0,4−1,5 |
- |
Zn 5,0−7,0** |
Not more than 18 |
600 |
- | Perlite, brass allowed ferrite to 40%, on and the torn mesh of cement to 15% and the inclusion of graphite |
| PA-Igrss |
« |
- |
- |
- |
- |
0,6−1,4 |
0,4−1,1* |
Zn not more than 2.7* |
15−20 |
500 |
160 | Perlite, sulfides, pore, allowed ferrite to 30% on and torn mesh cementite to 15% inclusions of graphite |
| PA-ЖГр3Цс |
« |
- |
- |
- |
- |
2,2−3,2 |
0,6−1,3* |
Zn not more than 2.7* |
10−20 |
600 |
145 | Perlite, sulfides, and graphite, the pores are allowed ferrite to 30% and the inclusion of cement up to 15% |
| PA-IGRAC |
« |
- |
- |
- |
- |
0,7−1,4 |
1,5−1,9* |
Zn «2,7* Sn 0,8−1,2 |
14−20 |
500 |
160 | Pearlite, ferrite 30−60%, sulfides, and graphite, the pores |
| PA-Gghc |
« |
- |
- |
0,3−0,7 |
- |
0,6−1,2 |
0,8−1,2 |
- |
Up to 20 |
1100 |
- | Perlite, sulfides, phosphide eutectics, the pores are allowed ferrite to 40%, graphite |
| PA-ЖГрФ1К |
« |
- |
- |
0,8−1,2 |
- |
0,6−1,2 |
0,8−1,2 |
- |
Not more than 20 |
1200 |
- | The same |
| PA-Iggfc |
« |
- |
2,5−3,5 |
0,1−0,5 |
- |
0,2−0,6 |
0,1−0,4 |
- |
17−25 |
600 |
- | Perlite, sulfides, phosphide eutectics, the pores allowed ferrite to 40% |
| PA-Ggnfs |
« | - |
2,5−3,5 |
0,1−0,5 |
1,5−2,0* |
0,2−0,6 |
0,6−1,5* |
- |
18−23 |
500 |
180 | The cementite to 10% |
| PA-Igrams |
« |
Not more than 1.5 |
2,5−3,5 |
- |
1,5−3,6* |
0,6−1,3 |
1.5 to 2.4* |
- |
15−25 |
700 |
200 | Perlite, sulfides, pore, allowed ferrite to 40%, on and the torn mesh of cementite to 10% inclusions of graphite |
| PA-ЖГр3М |
« |
- |
- |
- |
13,0−16,0 |
1,8−3,0 |
- |
- |
15−23 |
600 |
One hundred thirty five | Perlite, graphite free, separate inclusions of carbides up to 15%, ferrite of up to 30%, pore |
| PA-ЖНГр3М |
« |
39,0−43,0 |
- |
- |
13,0−16,0 |
1,8−3,0 |
- |
- |
12−23 |
700 |
225 | A solid solution with areas of pearlite and martensite — like structures, a separate on carbide, free graphite, the pores |
| PA-ЖНГр10Цс |
« |
40,0−44,0 |
- |
- |
- |
7,5−11,0 |
0,4−1,2* |
Zn, not more than 1.9*; Mn is not more than 2.2 |
8−18 |
230 |
45 | Solid solution with inclusions of areas of pearlite and carbides, graphite, sulfides, pore |
| PA-JFK |
« |
- |
- |
0,3−0,7 |
- |
- |
0,8−1,2 |
- |
Not more than 20 |
950 |
- | Ferrite with inclusions of sulfides, phosphide eutectics, the pores |
| PA-ЖФ1К |
« |
- |
- |
0,8−1,2 |
- |
- |
0,8−1,2 |
- |
Not more than 20 |
700 |
- | The same |
| PA-GFCM |
« |
- |
- |
1,0−1,2 |
2,4−2,6 |
- |
0,8−1,2 |
- |
Not more than 20 |
600 |
- | « |
| PA-ЖХ20КБ |
« |
- |
- |
- |
0,2−0,5* |
0,2−0,8 |
0,3−1,5 |
Cr 17−23; In 0,02−0,80 |
20−30 |
700 |
145 | Doped with chromium and boron ferrite, inclusions of sulfides, carbides, borides, and pores |
| PA-ЖХ18Н15КБ |
« |
12,0−16,0 |
- |
- |
0,2−0,5* |
0,5−1,5 |
0,3−1,5 |
Cr 16−20; In 0,02−0,15 |
18−26 |
600 |
270 | Heterogeneous structure on the basis of alloyed austenite, inclusions protobranch type, carbides, sulfides, pore |
________________
* Components are introduced in the form of sulfides of metals.
** Elements of the impregnating alloy of brass Л69.
Notes:
1. The index of tensile strength in radial compression
2. The minimum acceptable hardness value of the material items (
where is the minimum value of the hardness according to the table, MPa;
— a correction factor characterizing the change of hardness from porosity. Correction factor for material grades shall not be less than: 8,0 — PAS-Igrams, PA-ЖХ20КБ; 10,0 — PAS-ЖГр3Цс, PA-Iggfc, PA-ЖГр3М, PA-ЖНГр3М, PA-ЖНГр10Цс, ЖХ18Н15КБ; 16,6 — PAS-Ghrd; 17,1 — PA-W; 17,5 — PAS-railway; 18,0 — PAS-Ghrdc; 20,0 — PA-HUD, PA-ЖГрДК1; 29,3 — PAS-ЖГр3; 32,0 — PAS-ZHDK; 33,3 — PAS-ЖГр2К; A 37.5 — PAS-ЖГр2; 40,0 — PAS-ЖД5; 54,5 — PAS-ЖГрД5; 63,6 — PAS-ЖГр2Д;
— the maximum value of the porosity of the material according to the table, %;
the maximum porosity value for a prescribed interval porosity of the material in the normative-technical documentation for specific products, %.
3. By agreement between manufacturer and consumer, the microstructure should be:
for brand PA-HUD — perlite, perlite-ferrite, ferrite-perlite (pearlite is not less than 40%), torn mesh cementite to 15% inclusions of graphite;
for brand PA-Ggrd — perlite, perlite-ferrite, ferrite-perlite (pearlite is not less than 40%), torn mesh cementite to 15%, a separate small inclusions of graphite and copper;
for brand PA-Ggrc — perlite, perlite-ferrite, ferrite-perlite (pearlite is not less than 40%), the inclusion of sulphides, torn mesh cementite to 15% of graphite, the pores;
for brand PA-Ghrdc — perlite, perlite-ferrite, ferrite-perlite (pearlite is not less than 40%), inclusion and torn mesh cementite to 15% inclusions of graphite and copper;
for brand PA-ЖГрДК6 — perlite, perlite-ferrite, ferrite-perlite (pearlite is not less than 40%), sulfides, pore, allowed the inclusion and torn mesh cementite to 10% inclusions of graphite.
(Changed edition, Rev. N 1).
3. The limit of Flexural strength, tensile strength and tensile impact strength antifrictional powder materials in the reference Appendix 1.
4. Conditions of work and the scope of the materials is given in recommended Appendix 2.
5. Compliance notation antifriction powder materials based on iron, formerly used in the normative-technical documentation in the reference enclosure 3.
6. The symbol consists of letters and numbers. The letters indicate: P — belonging to the powder material, And assign material — antifriction, after the dash — based material and alloying elements: W — iron, D — copper, tin, Gr — graphite, X — chrome, N — Nickel, p — phosphorus, B — boron, sulfur, MS — molybdenum sulphide, CA — sulphide zinc, L — brass, M — molybdenum.
The figures after the letters indicate the content of a particular element in materials of similar compositions, different percentages of the same elements.
Example of designation antifriction powder material based on iron, alloyed with carbon according to GOST 26802−86
PA-HUD GOST 26802−86.
7. Control methods
7.1. The porosity is determined according to GOST 18898−73*.
_______________
* Standards 18898−89. — Note the manufacturer’s database.
7.2. The hardness is determined according to GOST 25698−83*.
_______________
* Standards 25698−98. — Note the manufacturer’s database.
7.3. Tensile strength in radial compression is determined according to GOST 26529−85.
7.4. The tensile bending strength is determined according to GOST 18228−85*.
_______________
* Standards 18228−94. — Note the manufacturer’s database.
7.5. Ultimate resistance in tension is determined according to GOST 18227−85*.
_______________
* Standards 18227−98 (ISO 2740−86). — Note the manufacturer’s database.
7.6. Impact strength is determined according to GOST 26528−85*.
_______________
* Standards 26528−98. — Note the manufacturer’s database.
6, 7. (Added, Rev. N 1).
ANNEX 1
Reference
| Material grade |
Tensile strength at bending, MPa |
Yield strength tensile, MPa |
Impact strength, kJ/m |
| not less than | |||
| PA-W |
130 |
85 |
30 |
| PA-ZHD |
250 |
120 |
39 |
| PA-ЖД5 |
300 |
150 |
40 |
| PA-LCD |
170 |
120 |
- |
| PA-ZHDK |
250 |
120 |
30 |
| PA-HUD |
140 |
120 |
30 |
| PA-ЖГр2 |
110 |
100 |
20 |
| PA-ЖГр3 |
110 |
70 |
15 |
| PA-Ggrd |
250 |
150 |
30 |
| PA-ЖГр2Д |
200 |
150 |
25 |
| PA-ЖГрД5 |
250 |
150 |
30 |
| PA-Ggrc |
140 |
100 |
30 |
| PA-ЖГр2К |
150 |
100 |
20 |
| PA-Ghrdc |
200 |
150 |
25 |
| PA-ЖГрДК1 |
200 |
150 |
20 |
| PA-ЖГрДК6 |
220 |
- |
- |
| PA-Ggrl |
- |
300 |
150 |
| PA-Igrss |
180 |
140 |
- |
| PA-ЖГр3Цс |
160 |
100 |
20 |
| PA-IGRAC |
180 |
- |
- |
| PA-Gghc |
- |
180 |
70 |
| PA-ЖГрФ1К |
- |
240 |
60 |
| PA-Iggfc |
- |
200 |
20 |
| PA-Ggnfs |
200 |
200 |
20 |
| PA-Igrams |
220 |
200 |
40 |
| PA-ЖГр3М |
150 |
60 |
10 |
| PA-ЖНГр3М |
250 |
180 |
20 |
| PA-ЖНГр10Цс |
50 |
50 |
8 |
| PA-JFK |
- |
150 |
70 |
| PA-ЖФ1К |
- |
180 |
60 |
| PA-GFCM |
- |
200 |
20 |
| PA-ЖХ20КБ |
160 |
- |
- |
| PA-ЖХ18Н15КБ |
300 |
- |
- |
APPENDIX 2 (recommended)
ANNEX 2
Recommended
| Mark |
Working conditions |
Scope |
| PA-W PA-LCD |
Working with abundant lubrication at pressures up to 2.5 MPa and sliding velocities of 1−2 m/s. In the mode of self-lubrication the load up to 1.5 MPa, the coefficient of friction of 0.03−0.06. The presence of sulfur increases the lifespan and improves the machinability of the material |
Precision bearings appliances, household equipment, computing machines, textile machinery |
| PA-train PA-ЖД5, PA-ZHDK, PA-HUD, PA-ЖГр2, PA-ЖГр3, PA-Ggrd, PA-ЖГрД5, PA-ЖГр2Д |
Work in conditions of limited and copious lubrication at pressures up to 4 and 10 MPa, respectively, and sliding speed up to 3 m/s; in self-lubricating mode up to 2 MPa. The coefficient of friction 0,035−0,125 depending on the amount of grease and composition of the material. Materials with increased graphite content work at the upper limit of the specified loads, sliding velocities up to 5 m/s have a greater service life, lower wear and coefficient of friction. The presence of sulfur increases the durability and improves the machinability of the material |
Bearings and friction components of tractors, agricultural machinery, machine tools, devices, appliances home appliances, automobiles, for example, details of telescopic shock absorbers, gearboxes, winches, etc. |
| PA-Ggrc, PA-ЖГр2К, PA-Ghrdc, PA-ЖГрДК1, PA-ЖГрДК6, PA-Igrss |
Work in a mode of self-lubrication and limited lubrication at pressures up to 12 MPa and at sliding velocities in the range of 3−8 m/s, at elevated temperatures up to 250 °C Coefficient of friction-0,01−0,1 |
Bearings and other parts of friction units of vehicles, machines, various machines and mechanisms For example, the sleeve of the valve guide, compressor refrigerator, etc. |
| PA-Ggrl |
Works in conditions of limited lubrication at a pressure of 8 MPa, sliding speed 2−5 m/s and a temperature of minus 60 plus 100 °C; has a coefficient of friction of not more than 0.1, and improved retirement compared to brass |
Tube valves for air, water, promaslennyh and other systems, for example, valves of brake systems of locomotives, wagons, etc. |
| PA-ЖГр3Цс |
Operates in the mode of self-lubrication, limited lubrication at sliding velocities up to 100 m/s; pressures up to 20 MPa at a speed of 5−10 m/s. Works in conjunction with hardened steel has a high wear resistance (up to 8 times greater than that of bronze, babbit, roller bearings, cast iron), low coefficient of friction (0,02−0,2), the value of which depends on the friction conditions |
Bearings, bushings, liners, mechanical seals for rotating shafts of various machines, engines, elektrowarme, devices, etc. |
| PA-IGRAC |
Operates in the mode of self-lubrication and limited lubrication in the range of sliding speeds 5−75 m/s at pressures from 0.1 to 10 MPa, decreasing with increasing speed. Works in tandem with tempered and normalized steels, has high durability (2.5 times the durability of porous bronzegraphite), has a coefficient of friction of 0.03−0,1 |
The friction finches spindles, bearings activator washing machine etc. household appliances, textile machinery, etc. |
| PA-Jghk, PA-ЖГрФ1К |
Works in conditions of limited lubrication at pressures up to 20 MPa; sliding speed from 0.5 to 12 m/s. friction Coefficient of 0.01−0.05. Cake mix low-porous materials are used for operation without lubrication at pressures up to 3 MPa. Working temperature up to 200 °C, the coefficient of friction of about 0.19 to 0.33 |
Bearings and other parts of friction units of machines, machines and mechanisms |
| PA-Iggfc, PA-Ggnfs, PA-Igrams |
Work in conditions of limited lubrication and without lubrication at pressures up to 2.5 MPa. Have low wear and friction coefficient of 0,08−0,12 |
Details of vehicles (washers, biscuits, bushings), for example, bushing idler arm front suspension of the car GAZ-14 etc. |
| PA-ЖГр3М, PA-ЖНГр3М |
Work in conditions of limited lubrication and without lubrication in a wide range of sliding velocities from 0.1 to 100 m/s; allowable pressure up to 18 MPa, temperature up to 450 °C in air. Have a coefficient of friction of 0.03 to 0.20, increased wear resistance compared to other iron based materials. The introduction of Nickel increases the corrosion resistance of the material allows to use it in friction in the presence of moisture and its vapors |
Bearings the upper bearings of the spindle reels of cotton pickers, electric motors, seals, lubricant-free compressors, equipment, etc. |
| PA-ЖНГр10Цс |
Designed for operation in water, steam and other fluids namasivaya; works on hardened and unhardened surfaces. Permissible pressure 10 MPa, sliding speed up to 50 m/s, temperature up to 250 °C; the coefficient of friction of 0.03−0.3 mm depending on the friction regime. Has 2−6 times higher wear resistance compared to antegmit, PCB, and PTFE elastographic |
Mechanical seal pumps installations for processing milk, butter and dairy products; bearings bearings washing baths, dyeing and finishing and drying machines, textile industry, etc. |
| PA-ZHFK, PA-ЖФ1К, PA-GFCM |
Work in conditions of limited lubrication at pressures up to 20 MPa, in the range of sliding speeds of 0.5−6.0 m/s; working temperature up to 200 °C; the coefficient of friction of 0.009−0,030. Cake mix low-porous materials capable of operating without lubrication at pressures up to 3.5 MPa and sliding speed of 0.8 m/s Coefficient of friction to 0.19 and 0.30. |
Bearings and other parts of friction units of machines; machines and mechanisms |
| PA-ЖХ20КБ, PA-ЖХ18Н15КБ |
Designed to operate without lubrication in water and other aggressive environments at temperatures up to 600 °C, sliding velocities up to 60 m/s. Have a higher wear resistance in the presence of abrasive material than hardened steel 40X13. |
The concrete sleeve is water lifting, pumps, bearings, chemical equipment, engines, appliances, etc. |
ANNEX 3 (informative)
APPENDIX 3
Reference
| Marking stamps according to GOST 26802−86 |
The previously used notation in NTD |
| PA-W |
Gpor; ЖГр0,5; W-6,0; ЖГр0,1 |
| PA-ZHD |
ЖД2,5; ЖД3; ЖД3,5; ЖГр0,1Д2,5 |
| ЖГр0,5Д2,5 | |
| PA-ЖД5 |
ЖД5; ЖД10; ЖГр0,25Д5; ЖД10−6,0 |
| PA-LCD |
ЖК0,3; ЖК0,4 |
| PA-ZHDK |
ЖД3К0,3; ЖДК0,27; ЖГр0,5Д3Д3К0,3; ЖГр0,5Д3К0,4 |
| ЖГр0,5Д2,5К0,3; ЖГр0,5Д2,5К0,4 | |
| PA-HUD |
ЖГр1; ЖГр1,2; ЖГр1,5; Ж40−59; ЖГр1−60; Ж20−62 |
| PA-ЖГр2 |
ЖГр2; ЖГр2−20; Ж50−58 |
| PA-ЖГр3 |
ЖГр3−20; ЖГр3−5,5; ЖГр3; Ж60−57 |
| PA-Ggrd |
ЖГр0,5Д2,5; ЖГр0,8Д3; HUD (1−1,5) |
| D (2,7−3,3); ЖГр1Д2,5; Ж40Д3−58 | |
| PA-ЖГр2Д |
ЖГр2Д2,5; ЖГр3Д3; ЖГр3Д3 To 5.5 |
| PA-ЖГрД5 |
ЖГр1,5Д10; МЖГ1; ЖГр1,5Д5 |
| PA-Ggrc |
ЖГр1К0,8; ЖГр1К1; ЖГр1,2К0,8; Ж20Н1,5К1−59; Ж30К1−58 |
| PA-ЖГр2К |
ЖГр3К0,8; ЖГр3К1; ЖГр2К1 |
| PA-Ghrdc |
ЖГр1Д2,5К0,4; ЖГр1,2Д2,5К0,4; ЖГр1,5Д2,5К0,4; ЖГр2,5Д2,5К0,3; ЖГр1,5Д3К0,4; ЖГр1,5Д3К0,4; ЖГр1,5Д3К0,3; Ж30Д3К0,4−60; ЖГр1,5Д2,5К0,5 |
| PA-ЖГрДК1 |
ЖГр0,5Д3К0,8; ЖГр1Д2,5K; ЖГр1,2Д2,5 |
| K0,8 | |
| ЖГр2Д2,5К0,8; Ж20Н1,5Д1,5К1−59 | |
| PA-ЖГрДК6 |
ЖГр1,5Д3 impregnated with sulphur (no brand) |
| PA-Ggrl |
ЖГр1,5L; Ж40Л-69 |
| PA-Igrss |
HUD (1,0−1,5)Цс4 |
| PA-ЖГр3Цс |
ЖГрЦс4У; ЖГр3Цс4 |
| PA-IGRAC |
ЖГр1,5Цс401К1 |
| PA-Gghc |
ЖФ0,5К1Гр0,8 |
| PA-ЖГрФ1К |
ЖФ1К1Гр0,8 |
| PA-Iggfc |
ЖГр0,6Д2,8К0,3Ф0,3 |
| PA-Ggnfs |
- |
| PA-Igrams |
- |
| PA-ЖГр3М |
ЖГр3М15 |
| PA-ЖНГр3М |
ЖНГр3М15 |
| PA-ЖНГр10Цс |
МГ30ЖН1К |
| PA-JFK |
ЖФ0,5К1 |
| PA-ЖФ1К |
ЖФ1К1 |
| PA-GFCM |
ЖФ1К1М2,5 |
| PA-ЖХ20КБ |
Х20КБ |
| PA-ЖХ18Н15КБ |
Х18Н15КБ |
