CN212780338U - Fabric wear test device - Google Patents

Abstract

The utility model discloses a fabric wear test device, which comprises a frame, be equipped with yarn motion module and lower yarn motion module in the frame, the solid upper Z axle step motor fixed plate that connects in the middle of the frame top, upper Z axle step motor fixed plate left end below solid connects upper Z axle step motor, cup joint upper Z axle initiative synchronous pulley in the upper Z axle step motor pivot, upper Z axle step motor fixed plate right-hand member below rigid coupling lower floor Z axle step motor, cup joint lower floor's Z axle initiative synchronous pulley in the lower floor Z axle step motor pivot, the problem that the wear test platform structure that exists is complicated among the prior art has been solved.

Description

Fabric wear test device

Technical Field

The utility model belongs to the technical field of the fabrics detects, a fabric wear test device is related to.

Background

The phenomenon of friction is widely present in our daily lives, where unnecessary friction causes wear, especially in some textile machinery. The frictional wear of fabrics in the weaving process can lead to the performance reduction of products after forming, especially some composite materials weave, and its frictional wear condition directly determines the quality and the performance of follow-up product, and frictional wear test platform is mostly imported product on the market at present, and its installation is loaded down with trivial details, the structure is complicated, the price is expensive, is difficult to satisfy market requirement.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a fabric wear test device has solved the problem that the wear test platform structure that exists is complicated among the prior art.

The utility model provides a technical scheme who adopts is, a fabric wear test device, which comprises a frame, be equipped with yarn motion module and lower yarn motion module in the frame, the solid upper Z axle step motor fixed plate that connects in the middle of the frame top, upper Z axle step motor fixed plate left end below solid upper Z axle step motor, overlap upper Z axle initiative synchronous pulley in the upper Z axle step motor pivot, upper Z axle step motor fixed plate right-hand member below rigid coupling lower floor's Z axle step motor, cup joint lower floor's Z axle initiative synchronous pulley in the Z axle step motor pivot of lower floor.

The utility model discloses a characteristics still lie in:

and supporting angle blocks are fixedly connected with the upper and lower corners of the rack.

The upper yarn motion module comprises an upper Z-axis moving device and an upper X-axis moving device;

the upper Z-axis moving device comprises an upper Z-axis ball screw and two upper Z-axis polished rods which are respectively arranged between supporting angle blocks which are vertically symmetrical on the left side, the upper ends of the front and rear upper Z-axis ball screws are respectively provided with an upper Z-axis second driven synchronous belt pulley and an upper Z-axis first driven synchronous belt pulley, and the upper Z-axis second driven synchronous belt pulley, the upper Z-axis first driven synchronous belt pulley and the upper Z-axis driving synchronous belt pulley are sleeved by an upper Z-axis synchronous belt; all cup jointed upper Z axle ball copper sheathing on the Z axle ball of upper strata, all cup jointed linear bearing a on the Z axle polished rod of upper strata, two pieces of upper Z axle ball copper sheathing rigid couplings are in the reservation hole about the guide block of upper strata, and linear bearing an cup joints at upper guide block assigned position on the Z axle polished rod of upper strata.

The upper layer X-axis moving device comprises two upper layer X-axis SGR high-speed linear slide rails which are fixedly connected in a groove at the front side of an upper layer guide block up and down, the front side of the right end of the upper layer guide block is fixedly connected with an upper layer X-axis stepping motor fixing plate, an upper layer X-axis stepping motor is fixedly connected to the upper layer X-axis stepping motor fixing plate, an upper layer X-axis single diaphragm coupler is sleeved on a rotating shaft of the upper layer X-axis stepping motor, one end of the upper layer X-axis single diaphragm coupler is sleeved on the rotating shaft of the upper layer X-axis stepping motor, the other end of the upper layer X-axis single diaphragm coupler is sleeved at the right end of an upper layer X-axis ball screw, a bearing is sleeved at the left end of the upper layer X-axis ball screw, the bearing is sleeved with an upper layer X-axis bearing support, the upper layer X-axis bearing support is fixedly connected with the front side of the left end of the upper layer guide block, an upper layer X-axis, the tail part of the upper line clamp fixing seat is fixedly connected to two upper layer X-axis SGR high-speed linear slide rail sliding tables, the right side of an upper layer X-axis bearing support at the front side of the left end of an upper layer guide block is fixedly connected with a T photoelectric sensor, the upper line clamp fixing seat is fixedly connected with an upper line clamp, and a first yarn is clamped on the upper line clamp.

The lower yarn motion module comprises a lower layer Z-axis moving device, a lower layer X-axis moving device and a lower layer Y-axis moving device;

lower floor's Z axle mobile device includes lower floor's Z axle ball and two lower floor's Z axle polished rods of installation between the support angle piece of right side longitudinal symmetry, the No. four driven synchronous pulleys of lower floor's Z axle are installed respectively to two lower floor's Z axle ball upper ends in the front and back, No. three driven synchronous pulleys of lower floor's Z axle, No. four driven synchronous pulleys of lower floor's Z axle, cup joint with lower floor's Z axle hold-in range between No. three driven synchronous pulleys of lower floor's Z axle and the lower floor's Z axle initiative synchronous pulley, all cup joint lower floor's Z axle ball copper sheathing on the lower floor's Z axle ball, all cup joint linear bearing on the lower floor's Z axle polished rod, two piece of lower floor's Z axle ball copper sheathing rigid couplings are in the reservation about.

The lower layer X-axis moving device comprises two lower layer X-axis SGR high-speed linear slide rails which are fixedly connected in a groove at the front side of a lower layer guide block up and down, a lower layer X-axis stepping motor fixing plate is fixedly connected to the lower layer X-axis stepping motor fixing plate, a lower layer X-axis stepping motor rotating shaft is sleeved with a lower layer X-axis single diaphragm coupling, one end of the lower layer X-axis single diaphragm coupling is sleeved on the lower layer X-axis stepping motor rotating shaft, the other end of the lower layer X-axis single diaphragm coupling is sleeved with a lower layer X-axis ball screw, one end of the lower layer X-axis ball screw is sleeved with a lower layer X-axis single diaphragm coupling, the other end of the lower layer X-axis ball screw is sleeved with a bearing, the bearing is sleeved with a lower layer X-axis bearing support, the lower layer X-axis bearing support is fixedly connected to the front side of the left, the tail part of the transverse guide block is fixedly connected with a lower layer X-axis SGR high-speed linear slide rail.

The lower layer Y-axis moving device comprises a lead screw supporting plate fixedly connected with the bottom of a transverse guide block, a bearing a is sleeved on the lead screw supporting plate, a lower layer Y-axis ball screw is sleeved on the bearing a, one end of the lower layer Y-axis ball screw is sleeved on the bearing a, the bearing a is sleeved on the other end of the lower layer Y-axis ball screw, a lower layer Y-axis single-diaphragm coupling is sleeved on one end of the lower layer Y-axis single-diaphragm coupling, a lower layer Y-axis stepping motor rotating shaft is sleeved on the other end of the lower layer Y-axis single-diaphragm coupling, a lower layer Y-axis stepping motor fixing plate is fixedly connected with the lower layer Y-axis stepping motor fixing plate, a slide rail-motor connecting plate is fixedly connected on the horizontal plane of the lower layer Y-axis stepping motor fixing plate, the slide rail-motor connecting plate is fixedly connected with one end of a lower, two ends of the longitudinal guide block are fixedly connected with two sliding blocks on the lower-layer Y-axis SGR high-speed linear sliding rail.

The front and the back of the longitudinal guide block are respectively and fixedly connected with a lower clamp fixing seat, the upper parts of the two lower clamp fixing seats are fixedly connected with lower clamps, the left and the right side holes of the lower clamps are respectively and rotatably connected with yarn tension adjusting bolts, the upper holes of the yarn tension adjusting bolts are respectively and rotatably connected with yarn clamping bolts, and two bosses of the lower clamps are respectively sleeved with threading rings. The second yarn passes through the threading ring, and the two ends of the second yarn are clamped in left and right yarn tension adjusting bolt holes on the lower wire clamp and are clamped by yarn clamping bolts.

The rear side of the longitudinal guide block is fixedly connected with a rear side light blocking sheet of a lower layer Y shaft, the left side of the screw rod supporting plate is fixedly connected with a left side light blocking sheet of a lower layer X shaft, and the right side of the screw rod supporting plate is fixedly connected with a right side light blocking sheet of a lower layer X shaft.

The frame is provided with a fastening bolt.

The utility model has the advantages that: the utility model relates to a fabric wear test device has solved the loaded down with trivial details and complicated, the with high costs problem of laboratory bench structure of wear test platform installation that exists among the prior art, and the action that the fabric longitude and latitude interweaved has been realized in the simulation, realizes the wear test of fabric simultaneously under each mobile device's cooperation.

Drawings

FIG. 1 is a front view of a fabric wear test apparatus of the present invention;

FIG. 2 is a left side view of a fabric wear test apparatus of the present invention;

fig. 3 is a top view of the fabric wear test apparatus of the present invention.

In the figure, 1, a frame, 2, a fastening bolt, 3, an upper Z-axis first driven synchronous pulley, 4, T45 photoelectric sensors, 5, an upper X-axis ball screw, 6, an upper Z-axis stepping motor fixing plate, 7, an upper Z-axis driving synchronous pulley, 8, an upper X-axis ball screw copper bush, 9, an upper Z-axis synchronous belt, 10, an upper X-axis SGR high-speed linear slide rail, 11, an upper Z-axis second driven synchronous pulley, 12, a supporting angle block, 13, an upper X-axis single diaphragm coupling, 14, an upper X-axis stepping motor fixing plate, 15, an upper X-axis stepping motor, 16, an upper Z-axis ball screw, 17, a lower Y-axis single diaphragm coupling, 18, a lower Y-axis ball screw, 19, an upper Z-axis polished rod, 20, an upper wire clamping fixing seat, 21, an upper guide block, 22, an upper X-axis bearing support, 23, an upper Z-axis ball copper bush, 24. an upper Z-axis stepping motor, 25. a lower Z-axis stepping motor, 26. a second yarn, 27. a threading ring, 28. a lower clamp, 29. a yarn clamping bolt, 30. a yarn tension adjusting bolt, 31. a lower X-axis stepping motor, 32. a lower Z-axis ball screw copper bush, 33. a lower X-axis stepping motor fixing plate, 34. a lower Y-axis ball screw copper bush, 35. a lower Y-axis rear light blocking plate, 36. a lower guide block, 37. a lower Z-axis polished rod, 38. a lower Z-axis ball screw, 39. a lower Z-axis fourth driven synchronous pulley, 40. a lower X-axis ball screw, 41. a lower Z-axis synchronous belt, 42. a screw support plate, 43. a lower Z-axis driving synchronous pulley, 44. a lower Z-axis third driven synchronous pulley, 45. a lower X-axis left light blocking plate, 46. a lower X-axis bearing support, 47. a transverse guide block, 48. a longitudinal guide block, 49. the lower line clamp fixing seat comprises a lower line clamp fixing seat, 50 parts of an upper line clamp, 51 parts of first yarns, 52 parts of a lower layer X-axis single-diaphragm coupler, 53 parts of a lower layer Y-axis SGR high-speed linear slide rail, 54 parts of a slide rail-motor connecting plate, 55 parts of a lower layer X-axis right light blocking sheet, 56 parts of a lower layer Y-axis stepping motor, 57 parts of a lower layer Y-axis stepping motor fixing plate and 58 parts of a lower layer X-axis SGR high-speed linear slide rail.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings and specific embodiments.

The utility model relates to a fabric wear test device, as shown in fig. 1 to fig. 3, including frame 1, be equipped with yarn motion module and lower yarn motion module in the frame 1, solid upper Z axle step motor fixed plate 6 in the middle of the 1 top in frame, upper Z axle step motor fixed plate 6 left end below solid grafting upper Z axle step motor 24, upper Z axle step motor 24 cup joints upper Z axle initiative synchronous pulley 7 in the pivot, upper Z axle step motor fixed plate 6 right-hand member below rigid coupling lower floor's Z axle step motor 25, cup joints lower floor's Z axle initiative synchronous pulley 43 in the pivot of lower floor's Z axle step motor 25.

The upper and lower corners of the frame 1 are fixedly connected with supporting corner blocks 12.

The upper yarn motion module comprises an upper Z-axis moving device and an upper X-axis moving device;

the upper Z-axis moving device comprises an upper Z-axis ball screw 16 and two upper Z-axis polished rods 19 which are respectively arranged between supporting angle blocks 12 which are vertically symmetrical on the left side, the upper ends of the front and rear upper Z-axis ball screws 16 are respectively provided with an upper Z-axis second driven synchronous pulley 11 and an upper Z-axis first driven synchronous pulley 3, and the upper Z-axis second driven synchronous pulley 11, the upper Z-axis first driven synchronous pulley 3 and an upper Z-axis driving synchronous pulley 7 are sleeved by an upper Z-axis synchronous belt 9; all cup jointed upper Z axle ball copper sheathing 23 on the Z axle ball 16 of upper strata, all cup jointed linear bearing a on the Z axle polished rod 19 of upper strata, two pieces of upper Z axle ball copper sheathing 23 rigid couplings are in the reservation hole about upper guide block 21, and linear bearing an cup joints at upper guide block 21 assigned position on the Z axle polished rod 19 of upper strata, and linear bearing a both ends are stopped the position with the jump ring.

The upper layer X-axis moving device comprises two upper layer X-axis SGR high-speed linear slide rails 10 which are fixedly connected in a groove at the front side of an upper layer guide block 21 up and down, an upper layer X-axis stepping motor fixing plate 14 is fixedly connected at the front side of the right end of the upper layer guide block 21, an upper layer X-axis stepping motor 15 is fixedly connected on the upper layer X-axis stepping motor fixing plate 14, an upper layer X-axis single diaphragm coupler 13 is sleeved on a rotating shaft of the upper layer X-axis stepping motor 15, one end of the upper layer X-axis single diaphragm coupler 13 is sleeved on the rotating shaft of the upper layer X-axis stepping motor 15, the other end of the upper layer X-axis single diaphragm coupler 13 is sleeved at the right end of an upper layer X-axis ball screw 5, a bearing is sleeved at the left end of the upper layer X-axis ball screw 5, an upper layer X-axis ball copper sleeve 8 penetrates through the upper layer X-axis ball copper sleeve 8 and is fixedly connected with an upper layer fixing seat 20, the tail of the upper line clamp fixing seat 20 is fixedly connected to two sliding tables of the upper layer X-axis SGR high-speed linear sliding rail 10, the right side of the upper layer X-axis bearing support 22 at the front end of the upper layer guide block 21 is fixedly connected with a T45 photoelectric sensor 4, the upper line clamp fixing seat 20 is fixedly connected with an upper line clamp 50, and a first yarn 51 is clamped on the upper line clamp 50.

The lower yarn motion module comprises a lower layer Z-axis moving device, a lower layer X-axis moving device and a lower layer Y-axis moving device;

the lower Z-axis moving device comprises a lower Z-axis ball screw 38 and two lower Z-axis polished rods 37 which are arranged between the right-side vertically-symmetrical supporting angle blocks 12, a lower Z-axis fourth driven synchronous pulley 39 and a lower Z-axis third driven synchronous pulley 44 are respectively arranged at the upper ends of the front and rear lower Z-axis ball screws 38, a lower Z-axis fourth driven synchronous pulley 39, a lower Z-axis third driven synchronous pulley 44 and a lower Z-axis driving synchronous pulley 43 are sleeved with each other through a lower Z-axis synchronous belt 41, a lower Z-axis ball screw copper bush 32 is sleeved on the lower Z-axis ball screw 38, linear bearings are sleeved on the lower Z-axis polished rods 37, the two lower Z-axis ball screw copper bushes 32 are fixedly connected in left and right reserved holes of the lower guide block 36, the linear bearings are sleeved on the lower Z-axis polished rods 37, and the two ends of the linear bearings are stopped through clamp springs.

The lower layer X-axis moving device comprises two lower layer X-axis SGR high-speed linear slide rails 58 which are fixedly connected in a groove at the front side of a lower layer guide block 36 up and down, a lower layer X-axis stepping motor fixing plate 33 is fixedly connected at the front side of the right end of the lower layer guide block 36, a lower layer X-axis stepping motor 31 is fixedly connected at the lower layer X-axis stepping motor fixing plate 33, a lower layer X-axis stepping motor 31 is sleeved at the rotating shaft of the lower layer X-axis stepping motor 31, a lower layer X-axis single diaphragm coupling 52 is sleeved at the rotating shaft of the lower layer X-axis stepping motor 31, one end of the lower layer X-axis single diaphragm coupling 52 is sleeved at the other end of the lower layer X-axis single diaphragm coupling 52, a bearing is sleeved at one end of the lower layer X-axis ball screw 40, a lower layer X-axis bearing support 46 is sleeved at the other end of the lower layer X-axis, the copper sleeve penetrates through and is fixedly connected to the transverse guide block 47, and the tail of the transverse guide block 47 is fixedly connected with the lower-layer X-axis SGR high-speed linear slide rail 58.

The lower layer Y-axis moving device comprises a lead screw supporting plate 42 fixedly connected with the bottom of a transverse guide block 47, a bearing a is sleeved on the lead screw supporting plate 42, a lower layer Y-axis ball screw 18 is sleeved on the bearing a, one end of the lower layer Y-axis ball screw 18 is sleeved on the bearing a, the other end of the lower layer Y-axis ball screw 18 is sleeved on the lower layer Y-axis single diaphragm coupling 17, one end of the lower layer Y-axis single diaphragm coupling 17 is sleeved on the lower layer Y-axis ball screw 18, the other end of the lower layer Y-axis single diaphragm coupling 17 is sleeved on a rotating shaft of a lower layer Y-axis stepping motor 56, the lower layer Y-axis stepping motor 56 is fixedly connected with a lower layer Y-axis stepping motor fixing plate 57, the horizontal plane of the lower layer Y-axis stepping motor fixing plate 57 is fixedly connected with a slide rail-motor connecting plate 54, the, the lower Y-axis ball screw 18 is sleeved with a copper sleeve, the copper sleeve is sleeved with a longitudinal guide block 48, and two ends of the longitudinal guide block 48 are fixedly connected with two sliding blocks on a lower Y-axis SGR high-speed linear sliding rail 53.

The longitudinal guide block 48 is fixedly connected with a lower clamp fixing seat 49 respectively at the front and the rear, the two lower clamp fixing seats 49 are fixedly connected with a lower clamp 28, the left and right side holes of the lower clamp 28 are respectively screwed with a yarn tension adjusting bolt 30, the upper hole of the yarn tension adjusting bolt 30 is screwed with a yarn clamping bolt 29, and the two bosses of the lower clamp 28 are respectively sleeved with a threading ring 27. The second yarn 26 passes through the threading ring 27, is held at both ends in the left and right yarn tension adjusting bolts 30 holes of the lower clamp 28, and is clamped by the yarn clamping bolts 29. The second yarn 26 passes through the threading ring 27, is held at both ends in the left and right yarn tension adjusting bolts 30 holes of the lower clamp 28, and is clamped by the yarn clamping bolts 29.

The rear side of the longitudinal guide block 48 is fixedly connected with a lower Y-axis rear side light blocking sheet 35, the left side of the screw rod supporting plate 42 is fixedly connected with a lower X-axis left side light blocking sheet 45, and the right side of the screw rod supporting plate 42 is fixedly connected with a lower X-axis right side light blocking sheet 45.

The frame 1 is provided with a fastening bolt 2.

The utility model relates to a socks packagine machine, the theory of operation specifically as follows:

the utility model provides a fabric wear test device divide into yarn motion module and lower yarn motion module, goes up yarn motion module and includes upper Z axle mobile device and upper X axle mobile device, and lower yarn motion module includes lower floor's Z axle mobile device, lower floor's X axle mobile device, lower floor's Y axle mobile device.

The upper layer Z-axis moving device, the upper layer X-axis moving device, the lower layer Z-axis moving device, the lower layer X-axis moving device and the lower layer Y-axis moving device all adopt a stepping motor to drive double ball screws, and the upper guide block moves up and down, left and right and forwards and backwards linearly through the screw transmission of the screw screws and nuts, wherein the Z-axis direction utilizes double guide rods to perform auxiliary guiding, and the X, Y-axis direction utilizes an SGR high-speed linear slide rail to perform auxiliary guiding. And each mobile device acts according to the system requirement, simulates yarn interweaving action and performs a yarn abrasion test.

The utility model relates to a socks packagine machine, application method specifically as follows:

a first yarn and a second yarn are pre-installed on the fabric wear experiment table, after installation is completed, the upper layer X-axis moving device drives the upper yarn clamp to move, so that the first yarn moves to the middle in the X-axis direction, the lower layer X-axis moving device drives the lower yarn clamp to move, so that the second yarn moves to the middle in the X-axis direction, and then the lower layer Y-axis moving device moves, so that the second yarn moves to the middle in the Y-axis direction. After the first and second yarns are in the middle of the X, Y axes, the upper Z-axis moving device moves downwards linearly, and the lower Z-axis moving device moves upwards until the two yarns are in orthogonal contact. After two yarns are contacted, the Z shaft is locked and fixed, the upper layer X shaft moving device moves to drive the first yarn to do reciprocating linear motion, the lower layer Y shaft moving device moves to drive the second yarn to do reciprocating linear motion, and the first yarn and the second yarn are orthogonally contacted to simulate yarn interweaving abrasion action to perform an abrasion test.

The utility model relates to a fabric wear test device has solved the loaded down with trivial details and laboratory bench structure complicacy of wear test platform installation that exists among the prior art, problem with high costs, and the action that the fabric longitude and latitude interweaved has been realized in the simulation, realizes the wear test of fabric simultaneously under each mobile device's cooperation.

Claims (10)

1. The utility model provides a fabric wear test device, its characterized in that, includes frame (1), be equipped with yarn motion module and lower yarn motion module in frame (1), frame (1) top middle solid upper Z axle step motor fixed plate (6) that connects, upper Z axle step motor fixed plate (6) left end below solid upper Z axle step motor (24) that connects, upper Z axle step motor (24) cup joints upper Z axle initiative synchronous pulley (7) in the pivot, upper Z axle step motor fixed plate (6) right-hand member below rigid coupling lower floor Z axle step motor (25), cup joint lower floor Z axle initiative synchronous pulley (43) in lower floor Z axle step motor (25) pivot.

2. A fabric wear test device according to claim 1, characterized in that the supporting corner blocks (12) are fixedly connected to the upper and lower corners of the frame (1).

3. The fabric wear test device of claim 2, wherein the upper yarn movement module comprises an upper Z-axis movement device and an upper X-axis movement device;

the upper Z-axis moving device comprises an upper Z-axis ball screw (16) and two upper Z-axis polished rods (19) which are respectively arranged between supporting angle blocks (12) which are vertically symmetrical on the left side, the upper ends of the front and rear upper Z-axis ball screws (16) are respectively provided with an upper Z-axis second driven synchronous pulley (11) and an upper Z-axis first driven synchronous pulley (3), and the upper Z-axis second driven synchronous pulley (11), the upper Z-axis first driven synchronous pulley (3) and an upper Z-axis driving synchronous pulley (7) are sleeved by an upper Z-axis synchronous belt (9); all cup jointed upper Z axle ball copper sheathing (23) on upper Z axle ball (16), all cup jointed linear bearing an on upper Z axle polished rod (19), two pieces of upper Z axle ball copper sheathing (23) rigid couplings are in the reservation hole about upper guide block (21), linear bearing an cup joints at upper guide block (21) assigned position on upper Z axle polished rod (19).

4. The fabric wear test device according to claim 3, wherein the upper layer X-axis moving device comprises two upper layer X-axis SGR high-speed linear slide rails (10) which are fixedly connected with the front side of a slot of the upper layer guide block (21) up and down, the front side of the right end of the upper layer guide block (21) is fixedly connected with an upper layer X-axis stepping motor fixing plate (14), an upper layer X-axis stepping motor (15) is fixedly connected onto the upper layer X-axis stepping motor fixing plate (14), an upper layer X-axis single diaphragm coupling (13) is sleeved on a rotating shaft of the upper layer X-axis stepping motor (15), one end of the upper layer X-axis single diaphragm coupling (13) is sleeved on the rotating shaft of the upper layer X-axis stepping motor (15), the other end of the upper layer X-axis single diaphragm coupling (13) is sleeved on the right end of the upper layer X-axis ball screw (5), and a bearing is sleeved on the left end of the upper layer X-axis ball screw (, the bearing has cup jointed upper X axle bearing (22), upper X axle bearing (22) rigid coupling has upper guide block (21) left end front side, upper X axle ball copper sheathing (8) have been cup jointed on upper X axle ball (5), upper X axle ball copper sheathing (8) run through and the rigid coupling has last line clamp stationary seat (20), last line clamp stationary seat (20) afterbody rigid coupling is on two high-speed linear slide rails of upper X axle SGR (10) slip tables, upper guide block (21) left end front side upper X axle bearing (22) right side rigid coupling T45 photoelectric sensor (4), last line clamp stationary seat (20) rigid coupling has last fastener (50), the centre gripping has yarn (51) No. one on last fastener (50).

5. The fabric wear test device of claim 2, wherein the lower yarn motion module comprises a lower layer Z-axis moving device, a lower layer X-axis moving device and a lower layer Y-axis moving device;

the lower Z-axis moving device comprises a lower Z-axis ball screw (38) and two lower Z-axis polished rods (37) which are arranged between support angle blocks (12) vertically symmetrical on the right side, the upper ends of the front and rear lower Z-axis ball screws (38) are respectively provided with a lower Z-axis fourth driven synchronous pulley (39) and a lower Z-axis third driven synchronous pulley (44), the lower Z-axis fourth driven synchronous pulley (39), the lower Z-axis third driven synchronous pulley (44) and a lower Z-axis driving synchronous pulley (43) are sleeved by a lower Z-axis synchronous belt (41), the lower Z-axis ball screw (38) is sleeved with a lower Z-axis ball screw copper sleeve (32), the lower Z-axis polished rod (37) is sleeved with linear bearings, and the two lower Z-axis ball copper sleeves (32) are fixedly connected in left and right holes of a lower guide block (36), and a linear bearing on the lower Z-axis polished rod (37) is sleeved on the lower guide block (36).

6. The fabric wear test device according to claim 5, wherein the lower layer X-axis moving device comprises two lower layer X-axis SGR high-speed linear slide rails (58) which are fixedly connected with the lower layer guide block (36) up and down in a front groove of the lower layer guide block, a lower layer X-axis stepping motor fixing plate (33) is fixedly connected with the front side of the right end of the lower layer guide block (36), the lower layer X-axis stepping motor fixing plate (33) is fixedly connected with the lower layer X-axis stepping motor (31), a lower layer X-axis single diaphragm coupling (52) is sleeved on a rotating shaft of the lower layer X-axis stepping motor (31), a lower layer X-axis single diaphragm coupling (40) is sleeved at the other end of the lower layer X-axis single diaphragm coupling (52), a lower layer X-axis single diaphragm coupling (52) is sleeved at one end of the lower layer X-axis ball screw (40), the bearing is cup jointed to lower floor's X axle ball (40) other end, lower floor's X axle bearing (46) is cup jointed to the bearing, lower floor's X axle bearing (46) rigid coupling is in lower floor's guide block (36) left end front side, the copper sheathing has been cup jointed on lower floor's X axle ball (40), the copper sheathing runs through and the rigid coupling on horizontal guide block (47), horizontal guide block (47) afterbody rigid coupling lower floor's X axle SGR high-speed linear slide rail (58).

7. The fabric wear test device according to claim 6, wherein the lower Y-axis moving device comprises a lead screw support plate (42) fixedly connected to the bottom of the transverse guide block (47), the lead screw support plate (42) is sleeved with a bearing a, the bearing a is sleeved with a lower Y-axis ball screw (18), one end of the lower Y-axis ball screw (18) is sleeved with the bearing a, the other end of the lower Y-axis ball screw (18) is sleeved with a lower Y-axis single diaphragm coupling (17), one end of the lower Y-axis single diaphragm coupling (17) is sleeved with the lower Y-axis ball screw (18), the other end of the lower Y-axis single diaphragm coupling (17) is sleeved with a rotating shaft of a lower Y-axis stepping motor (56), the lower Y-axis stepping motor (56) is fixedly connected to a lower Y-axis stepping motor fixing plate (57), a slide rail-motor connecting plate (54) is fixedly connected to the horizontal plane of the lower Y-axis stepping motor, the sliding rail-motor connecting plate (54) is fixedly connected with one end of a lower-layer Y-axis SGR high-speed linear sliding rail (53), the other end of the lower-layer Y-axis SGR high-speed linear sliding rail (53) is fixedly connected with the upper portion of a transverse guide block (47), a copper sleeve is sleeved on a lower-layer Y-axis ball screw (18), the copper sleeve is sleeved with a longitudinal guide block (48), and two sliding blocks are fixedly connected with two ends of the longitudinal guide block (48) on the lower-layer Y-axis SGR high-speed linear sliding rail (53).

8. The fabric wear test device according to claim 7, wherein the longitudinal guide block (48) is fixedly connected with a lower clamp fixing seat (49) respectively at the front and the back, the two lower clamp fixing seats (49) are fixedly connected with a lower clamp (28), the left and right side holes of the lower clamp (28) are respectively screwed with the yarn tension adjusting bolts (30), the upper holes of the yarn tension adjusting bolts (30) are screwed with the yarn clamping bolts (29), and two bosses of the lower clamp (28) are respectively sleeved with the threading rings (27).

9. The fabric wear test device according to claim 8, wherein the rear side of the longitudinal guide block (48) is fixedly connected with a lower Y-axis rear side light blocking sheet (35), the left side of the screw rod supporting plate (42) is fixedly connected with a lower X-axis left side light blocking sheet (45), and the right side of the screw rod supporting plate (42) is fixedly connected with a lower X-axis right side light blocking sheet (55).

10. A fabric wear test device according to claim 1, characterized in that the machine frame (1) is provided with fastening bolts (2).

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