CN104215507A - Hydraulic two-cylinder differential-load horizontal tensile test machine - Google Patents

Abstract

The invention relates to a hydraulic two-cylinder differential-load horizontal tensile test machine. The hydraulic two-cylinder differential-load horizontal tensile test machine consists of a loading oil cylinder I, a loading oil cylinder II, two pairs of reverse ejection rods, a reverse ejection beam I, a reverse ejection beam II, a large clamp crossbeam, a small clamp crossbeam, a large clamp and a small clamp, wherein after a test piece is fixedly installed on the clamp, oil is charged into a cylinder body part A of the loading oil cylinder I or the loading oil cylinder II, a piston is pushed to respectively drive the reverse ejection beam I or the reverse ejection beam II, the reverse ejection beam I or the reverse ejection beam II drives the large small clamp crossbeam or small clamp crossbeam through the reverse ejection rods, the large or small clamp crossbeam respectively drives the large clamp or the small clamp to move leftwards or rightwards, a purpose for stretching the test pieces with different measurement sizes on different workstations can be achieved, otherwise, the oil is charged into a cylinder part B of the loading oil cylinder I or the loading oil cylinder II, so that the piston is pushed to enable the large clamp crossbeam or the small clamp crossbeam to return.

Description

Hydraulic double cylinder difference loaded horizontal type cupping machine

Technical field

The invention belongs to metering quality inspection, rubber plastic, iron and steel metallurgy, machine-building, electronic apparatus, automobile production, textile chemical fiber, electric wire, wrappage and food, instrument and meter, medicine equipment, civilian nuclear energy, civil aviation, institution of higher learning, scientific experiment institute, commodity inspection is arbitrated, technical supervision department, building materials pottery, petrochemical complex, etc. the technical field of the Performance Detection of industry, to stretch the performance test to metal and nonmetallic materials in particular to a kind of application, as rubber, plastics, electric wire, optical fiber cable, securing band, safety belt, leather belt compound substance, plastic material, waterproof roll, steel pipe, copper material, section bar, spring steel, bearing steel, stainless steel (and other glass hard steel), foundry goods, steel plate, steel band, the stretching of non-ferrous metal metal wire rod, compression, bending, shear, peel off, tear, the machinery of the multiple tests such as 2 extensions (separately need join extensometer).

Background technology

Cupping machine is a kind of precision optical machinery measuring the mechanical property such as metal material, nonmetallic materials engineering structure under various condition, environment.In the process of research and probe new material, new technology, new technology and new construction, it is also a kind of indispensable important testing apparatus.Current cupping machine is divided into mechanical dynamometry and electronics dynamometry two kinds of modes by dynamometry mode; Non-follow control and microcomputer is divided into control two kinds of modes by control mode; Static and dynamic two kinds is divided into again by load mode.Cupping machine international and domestic is at present that one end is fixed, one end loads, and completes Performance Detection, not yet finds the investigation and application of the machinery and equipment of it being carried out to two-way stretch.And the present invention is the biaxial tensile test machine based on hydraulic pressure transfer, it is the Special test machine for colliery detection industry and the exploitation of non-coal mine detection industry.Vertical test is become horizontal test, which increases stretching space (can be increased to more than 20 meters, this is that vertical test is not accomplished).Meet the test of bulk specimen, full size bar.It is mainly used in the static tensile test of tool at the bottom of wire rope, cable wire, mine car, monocycle chain, ring chain, five rings chain, connecting pin etc.Also can be used for the stretching of various metal material, chain, hanging belt etc., extensively use the fields such as metallic article, building structure, ships, military project.

Summary of the invention

The object of this invention is to provide and a kind of overlap load cylinder by size two and complete each station difference respectively and carry and load, keep load to implement dynamic process, by means of load cylinder, drive jig crossbeam Precision Linear Moving, reach sample to be stretched, detect the fluid pressure type horizontal-type stretching testing machine of its deformation process and mechanical property object.

The technical solution adopted for the present invention to solve the technical problems is:

A kind of hydraulic double cylinder difference loaded horizontal type cupping machine, primarily of main frame (framed structure), fixed cross beam, intermediate transverse girder, large and little two compositions such as cover load cylinder and control panel etc., it is characterized in that: fixed cross beam I 6, fixed cross beam II 13, intermediate beam 25, line slideway I 41 and line slideway II 27 are fixed in horizontal framed structure 20, load cylinder I cylinder body B portion 3 and load cylinder I cylinder body A portion 5 are fixed on fixed cross beam I 6, piston I 4 is arranged in load cylinder I, be connected with reverse ejection beam I 1 by piston axle I 2, reverse ejection beam I 1 connects reverse ejection bar I 7 and is connected with large jig crossbeam 8 with reverse ejection bar IV 42 again, large jig I 9 is fixed on large jig crossbeam 8, reverse ejection beam I 1 connects roller IV 32, roller IV 32 and line slideway I 41 and line slideway II 27 routing motion, large jig crossbeam 8 connects roller III 28 linearly guide rail I 41 and line slideway II 27 orbiting motion, load cylinder II cylinder body A portion 14 and load cylinder II cylinder body B portion 16 are fixed on fixed cross beam II 13, piston II 15 is arranged in load cylinder II, be connected with reverse ejection beam II 19 by piston axle II 18, reverse ejection beam II 19 connects reverse ejection bar II 12 and is connected with small fixture crossbeam 11 with reverse ejection bar III 40 again, small fixture I 10 is fixed on small fixture crossbeam 11, reverse ejection beam II 19 connects roller I 17, roller I 17 and line slideway I 41 and line slideway II 27 routing motion, small fixture crossbeam 11 connects roller II 23 linearly guide rail I 41 and line slideway II 27 orbiting motion, large jig II 26 and small fixture II 24 are separately fixed on intermediate beam 25, oil transportation hole I 35 is stretched out by fuel tank 36, and connected pipes I 29 communicates with oil hole I 21, oil transportation hole II 37 is stretched out by fuel tank 36, and connected pipes II 33 communicates with oil hole II 22, oil pipe III 38 communicates with oil hole III 30, oil pipe IV 39 communicates with oil hole IV 31, fuel tank control panel 34 is arranged on oil circuit control on fuel tank 36, control fuel tank control panel 34 and make oil transportation hole I 35 oil-feed, oil enters load cylinder II cylinder body B portion 16 through oil pipe I 29 and oil hole I 21 and promotes piston II 15, piston II 15 drives piston axle II 18 and reverse ejection beam II 19 to be moved to the left, reverse ejection beam II 19 drives reverse ejection bar II 12, reverse ejection bar III 40, small fixture crossbeam 11 and small fixture I 10 to be moved to the left, and small fixture I 10 has coordinated specimen clamping work with small fixture II 24, control fuel tank control panel 34 and make oil transportation hole II 37 oil-feed, oil enters load cylinder II cylinder body A portion 14 through oil pipe II 33 and oil hole II 22 and promotes piston II 15, piston II 15 drives piston axle II 18 and reverse ejection beam II 19 to move right, reverse ejection beam II 19 drives reverse ejection bar II 12, reverse ejection bar III 40, small fixture crossbeam 11 and small fixture I 10 to move right, and small fixture I 10 has coordinated sample stretching surveying work with small fixture II 24, control fuel tank control panel 34 makes oil enter load cylinder I cylinder body B portion 3 through oil pipe IV 39 and oil hole IV 31 and promotes piston I 4, piston I 4 drives piston axle I 2 and reverse ejection beam I 1 to move right, reverse ejection beam I 1 drives reverse ejection bar I 7, reverse ejection bar IV 42, large jig crossbeam 8 and large jig I 9 to move right, and large jig I 9 has coordinated specimen clamping work with large jig II 26, control fuel tank control panel 34 makes oil enter load cylinder I cylinder body A portion 5 through oil pipe III 38 and oil hole III 30 and promotes piston I 4, piston I 4 drives piston axle I 2 and reverse ejection beam I 1 to be moved to the left, reverse ejection beam I 1 drives reverse ejection bar I 7, reverse ejection bar IV 42, large jig crossbeam 8 and large jig I 9 to be moved to the left, and large jig I 9 has coordinated sample stretching surveying work with large jig II 26.

Beneficial effect of the present invention: control turnover oil by oil path control system, drive piston, piston axle, reverse ejection beam, reverse ejection bar drive large or small fixture crossbeam respectively and jig respectively to both sides or move toward one another, reach clamping sample, to the object that sample stretches, complete with an equipment, realize the function that difference carries detection experiment, reach the object that saving equipment takes up an area space and reduces costs.

accompanying drawing illustrates:

Fig. 1 is structural representation of the present invention;

Fig. 2 is the vertical view of Fig. 1.

In figure: 1. reverse ejection beam I, 2. piston axle I, 3. load cylinder I cylinder body B portion, 4. piston I, 5. load cylinder I cylinder body A portion, 6. fixed cross beam I, 7. reverse ejection bar I, 8. large jig crossbeam, 9. large jig I, 10. small fixture I, 11. small fixture crossbeams, 12. reverse ejection bars II, 13. fixed cross beams II, 14. load cylinder II cylinder body A portions, 15. pistons II, 16. load cylinder II cylinder body B portions, 17. roller I, 18. piston axles II, 19. reverse ejection beams II, 20. horizontal framed structures, 21. oil holes I, 22. oil holes II, 23. roller II, 24. small fixtures II, 25. intermediate beams, 26. large jigs II, 27. line slideways II, 28. rollers III, 29. oil pipes I, 30. oil holes III, 31. oil holes IV, 32. rollers IV, 33. oil pipes II, 34. fuel tank control panels, 35. oil transportation holes I, 36. fuel tanks, 37. oil transportation holes II, 38. oil pipes III, 39. oil pipes IV, 40. reverse ejection bars III, 41. line slideways I, 42. reverse ejection bars IV

Embodiment:

Below in conjunction with drawings and Examples, the present invention is further described.

As depicted in figs. 1 and 2, a kind of hydraulic double cylinder difference loaded horizontal type cupping machine, primarily of main frame (framed structure), fixed cross beam, intermediate transverse girder, large and little two compositions such as cover load cylinder and control panel etc., it is characterized in that: fixed cross beam I 6, fixed cross beam II 13, intermediate beam 25, line slideway I 41 and line slideway II 27 are fixed in horizontal framed structure 20, load cylinder I cylinder body B portion 3 and load cylinder I cylinder body A portion 5 are fixed on fixed cross beam I 6, piston I 4 is arranged in load cylinder I, be connected with reverse ejection beam I 1 by piston axle I 2, reverse ejection beam I 1 connects reverse ejection bar I 7 and is connected with large jig crossbeam 8 with reverse ejection bar IV 42 again, large jig I 9 is fixed on large jig crossbeam 8, reverse ejection beam I 1 connects roller IV 32, roller IV 32 and line slideway I 41 and line slideway II 27 routing motion, large jig crossbeam 8 connects roller III 28 linearly guide rail I 41 and line slideway II 27 orbiting motion, load cylinder II cylinder body A portion 14 and load cylinder II cylinder body B portion 16 are fixed on fixed cross beam II 13, piston II 15 is arranged in load cylinder II, be connected with reverse ejection beam II 19 by piston axle II 18, reverse ejection beam II 19 connects reverse ejection bar II 12 and is connected with small fixture crossbeam 11 with reverse ejection bar III 40 again, small fixture I 10 is fixed on small fixture crossbeam 11, reverse ejection beam II 19 connects roller I 17, roller I 17 and line slideway I 41 and line slideway II 27 routing motion, small fixture crossbeam 11 connects roller II 23 linearly guide rail I 41 and line slideway II 27 orbiting motion, large jig II 26 and small fixture II 24 are separately fixed on intermediate beam 25, oil transportation hole I 35 is stretched out by fuel tank 36, and connected pipes I 29 communicates with oil hole I 21, oil transportation hole II 37 is stretched out by fuel tank 36, and connected pipes II 33 communicates with oil hole II 22, oil pipe III 38 communicates with oil hole III 30, oil pipe IV 39 communicates with oil hole IV 31, fuel tank control panel 34 is arranged on oil circuit control on fuel tank 36, control fuel tank control panel 34 and make oil transportation hole I 35 oil-feed, oil enters load cylinder II cylinder body B portion 16 through oil pipe I 29 and oil hole I 21 and promotes piston II 15, piston II 15 drives piston axle II 18 and reverse ejection beam II 19 to be moved to the left, reverse ejection beam II 19 drives reverse ejection bar II 12, reverse ejection bar III 40, small fixture crossbeam 11 and small fixture I 10 to be moved to the left, and small fixture I 10 has coordinated specimen clamping work with small fixture II 24, control fuel tank control panel 34 and make oil transportation hole II 37 oil-feed, oil enters load cylinder II cylinder body A portion 14 through oil pipe II 33 and oil hole II 22 and promotes piston II 15, piston II 15 drives piston axle II 18 and reverse ejection beam II 19 to move right, reverse ejection beam II 19 drives reverse ejection bar II 12, reverse ejection bar III 40, small fixture crossbeam 11 and small fixture I 10 to move right, and small fixture I 10 has coordinated sample stretching surveying work with small fixture II 24, control fuel tank control panel 34 makes oil enter load cylinder I cylinder body B portion 3 through oil pipe IV 39 and oil hole IV 31 and promotes piston I 4, piston I 4 drives piston axle I 2 and reverse ejection beam I 1 to move right, reverse ejection beam I 1 drives reverse ejection bar I 7, reverse ejection bar IV 42, large jig crossbeam 8 and large jig I 9 to move right, and large jig I 9 has coordinated specimen clamping work with large jig II 26, control fuel tank control panel 34 makes oil enter load cylinder I cylinder body A portion 5 through oil pipe III 38 and oil hole III 30 and promotes piston I 4, piston I 4 drives piston axle I 2 and reverse ejection beam I 1 to be moved to the left, reverse ejection beam I 1 drives reverse ejection bar I 7, reverse ejection bar IV 42, large jig crossbeam 8 and large jig I 9 to be moved to the left, and large jig I 9 has coordinated sample stretching surveying work with large jig II 26.

Claims (1)

1. a hydraulic double cylinder difference loaded horizontal type cupping machine, primarily of main frame (framed structure), fixed cross beam, intermediate transverse girder, large and little two compositions such as cover load cylinder and control panel etc., it is characterized in that: fixed cross beam I (6), fixed cross beam II (13), intermediate beam (25), line slideway I (41) and line slideway II (27) are fixed in horizontal framed structure (20), load cylinder I cylinder body B portion (3) and load cylinder I cylinder body A portion (5) is fixed on fixed cross beam I (6), piston I (4) is arranged in load cylinder I, be connected with reverse ejection beam I (1) by piston axle I (2), reverse ejection beam I (1) connects reverse ejection bar I (7) and is connected with large jig crossbeam (8) with reverse ejection bar IV (42) again, large jig I (9) is fixed on large jig crossbeam (8), reverse ejection beam I (1) connects roller IV (32), roller IV (32) and line slideway I (41) and line slideway II (27) routing motion, large jig crossbeam (8) connects roller III (28) linearly guide rail I (41) and line slideway II (27) orbiting motion, load cylinder II cylinder body A portion (14) and load cylinder II cylinder body B portion (16) is fixed on fixed cross beam II (13), piston II (15) is arranged in load cylinder II, be connected with reverse ejection beam II (19) by piston axle II (18), reverse ejection beam II (19) connects reverse ejection bar II (12) and is connected with small fixture crossbeam (11) with reverse ejection bar III (40) again, small fixture I (10) is fixed on small fixture crossbeam (11), reverse ejection beam II (19) connects roller I (17), roller I (17) and line slideway I (41) and line slideway II (27) routing motion, small fixture crossbeam (11) connects roller II (23) linearly guide rail I (41) and line slideway II (27) orbiting motion, large jig II (26) and small fixture II (24) are separately fixed on intermediate beam (25), oil transportation hole I (35) is stretched out by fuel tank (36), and connected pipes I (29) communicates with oil hole I (21), oil transportation hole II (37) is stretched out by fuel tank (36), and connected pipes II (33) communicates with oil hole II (22), oil pipe III (38) communicates with oil hole III (30), oil pipe IV (39) communicates with oil hole IV (31), fuel tank control panel (34) is arranged on the upper oil circuit control of fuel tank (36), control fuel tank control panel (34) and make oil transportation hole I (35) oil-feed, oil enters load cylinder II cylinder body B portion (16) through oil pipe I (29) and oil hole I (21) and promotes piston II (15), piston II (15) drives piston axle II (18) and reverse ejection beam II (19) to be moved to the left, reverse ejection beam II (19) drives reverse ejection bar II (12), reverse ejection bar III (40), small fixture crossbeam (11) and small fixture I (10) are moved to the left, small fixture I (10) has coordinated specimen clamping work with small fixture II (24), control fuel tank control panel (34) and make oil transportation hole II (37) oil-feed, oil enters load cylinder II cylinder body A portion (14) through oil pipe II (33) and oil hole II (22) and promotes piston II (15), piston II (15) drives piston axle II (18) and reverse ejection beam II (19) to move right, reverse ejection beam II (19) drives reverse ejection bar II (12), reverse ejection bar III (40), small fixture crossbeam (11) and small fixture I (10) move right, small fixture I (10) has coordinated sample stretching surveying work with small fixture II (24), control fuel tank control panel (34) makes oil enter load cylinder I cylinder body B portion (3) through oil pipe IV (39) and oil hole IV (31) and promotes piston I (4), piston I (4) drives piston axle I (2) and reverse ejection beam I (1) to move right, reverse ejection beam I (1) drives reverse ejection bar I (7), reverse ejection bar IV (42), large jig crossbeam (8) and large jig I (9) to move right, and large jig I (9) has coordinated specimen clamping work with large jig II (26), control fuel tank control panel (34) makes oil enter load cylinder I cylinder body A portion (5) through oil pipe III (38) and oil hole III (30) and promotes piston I (4), piston I (4) drives piston axle I (2) and reverse ejection beam I (1) to be moved to the left, reverse ejection beam I (1) drives reverse ejection bar I (7), reverse ejection bar IV (42), large jig crossbeam (8) and large jig I (9) to be moved to the left, and large jig I (9) has coordinated sample stretching surveying work with large jig II (26).