CN219805312U - Numerical control horizontal gabion mesh machine - Google Patents

Abstract

The utility model discloses a numerical control horizontal gabion mesh machine which comprises a frame, wherein a wire twisting device is arranged at the top of the frame, a traction device is arranged at the front end of the frame, a flower twisting driving device for driving the wire twisting device to conduct a flower twisting action is arranged on one side of the frame, and a dislocation driving device for driving the wire twisting device to conduct a dislocation action is arranged on the other side of the frame. Compared with the prior art adopting a complex connecting rod transmission mechanism and a gear transmission mechanism, the utility model has the advantages of better controllability and adjustability, lower equipment cost, stable operation and smaller noise generated in the production process, and is suitable for the technical field of silk screen processing equipment.

Description

Numerical control horizontal gabion mesh machine

Technical Field

The utility model belongs to the technical field of silk screen braiding equipment, and particularly relates to a numerical control horizontal gabion mesh machine.

Background

The hexagonal net is also called soft edge net or twisting net, is an iron wire net made of angular net (hexagonal) woven by metal wires, and the used metal wire diameter is different according to the size of the hexagonal. The utility model patent with application number 202010092928.2 discloses a horizontal gabion mesh machine, the utility model patent with application number 202221856318.6 discloses a positive twisting hexagonal mesh machine, which comprises a frame, a wire twisting device is arranged at the top of the frame, a workbench and a winding device are arranged in front of the frame, a paying-off device is arranged at the rear of the frame, a driving device for enabling the wire twisting device to conduct wire twisting action is arranged at one side of the frame, the driving device comprises a driving part and a transmission part, the driving part is fixedly arranged on the frame and connected with the transmission part through an overload limiting mechanism and a driving shaft, and the transmission part is connected with the wire twisting device through a wire twisting stroke adjusting mechanism.

The two types of hexagonal mesh knitting equipment adopt connecting rods or gear transmission, have complex and heavy structures and have larger noise during operation.

Disclosure of Invention

The utility model provides a numerical control horizontal gabion mesh machine, which is used for solving the problems of complex and heavy structure and large noise during operation caused by the fact that hexagonal mesh braiding equipment in the prior art adopts a connecting rod or gear transmission.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

the utility model provides a horizontal gabion mesh machine of numerical control, includes the frame, the frame top is equipped with and screws up the silk device, and the front end is equipped with draw gear, frame one side is equipped with and is used for driving to screw up the silk device and twist the flower drive arrangement who twists the flower action, and the opposite side is equipped with and is used for driving to twist the dislocation drive arrangement that silk device misplaced the action.

Further, the twisting driving device comprises a twisting driving part, the twisting driving part is fixedly arranged on one side of the frame and connected with the twisting transmission part through a twisting synchronous belt assembly, the twisting transmission part is connected with a twisting shaft through a twisting angle adjusting mechanism, and the twisting shaft drives a twisting rack to conduct twisting action through a twisting gear.

Further, twist the two cylinder racks that the transmission portion set up including vertically, two cylinder racks one end is through twisting flowers supporting seat and frame sliding connection, the other end and twist the both sides wing fixed connection of flowers slide, twist the plate body of flowers slide through twisting flowers slide rail assembly and twist flowers slide and frame sliding connection, link to each other with twisting the flowers slide through twisting the silk pole transmission assembly simultaneously, twist the flowers drive portion and pass through twisting the silk pole transmission assembly and link to each other with twisting the silk pole transmission assembly, two cylinder racks pass through the intermediate gear and twist the rotation of flowers angle adjustment mechanism drive twist the flowers axle.

Further, twist angle adjustment mechanism includes the suit and twists the angle adjustment cover subassembly of twisting on twisting the colored axle, twists the angle adjustment cover subassembly and includes first adjusting sleeve and second adjusting sleeve, and first adjusting sleeve one end is equipped with the regulating plate of turning structure, and second adjusting sleeve one end is equipped with the adjustment platform with the regulating plate adaptation, realizes the adjustment of both rotation angle through adjusting the jackscrew between regulating plate and the adjustment platform, has seted up on the regulating plate with the top silk hole of adjusting the jackscrew adaptation.

Further, the first adjusting sleeve and the adjusting plate are fixedly connected with the twisting shaft in a coaxial mode, the second adjusting sleeve and the intermediate gear are connected with the twisting shaft in a rotating mode, and the twisting shaft is installed on the frame in a rotating mode through the twisting supporting seat and the bearing assembly.

Further, the dislocation driving device comprises a dislocation driving part which is fixedly arranged on the other side of the frame and connected with a dislocation transmission part through a dislocation synchronous belt assembly, the dislocation transmission part is connected with a dislocation swing rod through a dislocation gap adjusting mechanism, and the dislocation swing rod drives the washboard to perform dislocation motion through a dislocation gear.

Further, the traction device comprises a traction driving part and a thorn shaft, wherein the thorn shaft rotates in front of the frame through a bearing assembly and is positioned at a net outlet position of the wire twisting device, the traction driving part is fixedly arranged on the other side of the frame, and the traction driving part is in transmission connection with the thorn shaft through a sprocket transmission assembly.

Further, the thread twisting device comprises a thread twisting wheel, an upper thread twisting rack, a lower thread twisting rack, an upper thread rolling plate and a lower thread rolling plate, wherein the upper thread twisting rack, the lower thread twisting rack, the upper thread rolling plate and the lower thread rolling plate are used for driving the thread twisting wheel to conduct thread twisting action, the upper thread twisting rack, the lower thread twisting rack, the upper thread rolling plate and the lower thread rolling plate are slidably arranged at the top of the frame, the thread twisting driving device drives the upper thread twisting rack and the lower thread twisting rack to conduct thread twisting action, and the dislocation driving device drives the upper thread rolling plate and the lower thread rolling plate to conduct left-right dislocation action, so that the thread twisting wheel is driven to rotate to twist a thread woven net.

Compared with the prior art, the utility model adopts the structure, and the technical progress is that:

the machine frame is provided with a twisting driving device for driving the twisting device to conduct twisting, the other side of the machine frame is provided with a dislocation driving device for driving the twisting device to conduct dislocation, the twisting driving device and the dislocation driving device are respectively arranged on two sides of the machine frame, the driving structure is simple and light, debugging is convenient, excessive connecting rods or gears are not needed for transmission, and meanwhile operation noise is low.

Drawings

The accompanying drawings are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate the utility model and together with the embodiments of the utility model, serve to explain the utility model.

In the drawings:

FIG. 1 is a schematic diagram of an embodiment of the present utility model;

FIG. 2 is a schematic perspective view of an embodiment of the present utility model;

FIG. 3 is a schematic diagram of the overall structure of an embodiment of the present utility model;

FIG. 4 is a schematic structural view of a dislocation driving portion according to an embodiment of the present utility model;

FIG. 5 is another angular schematic view of the overall structure of an embodiment of the present utility model;

fig. 6 is a schematic structural view of a twisting transmission part according to an embodiment of the present utility model;

fig. 7 is a schematic structural diagram of a connection between a cylindrical rack and a twisting gear according to an embodiment of the present utility model;

fig. 8 is a schematic structural view of a twisting angle adjusting mechanism according to an embodiment of the present utility model.

Marking parts: the device comprises a 01-twisting driving device, a 10-twisting supporting seat, a 11-cylindrical rack, a 12-twisting slide plate, a 13-twisting slide rail assembly, a 14-twisting synchronous belt assembly, a 15-twisting shaft, a 151-twisting gear, a 152-twisting angle gear, a 16-twisting angle adjusting mechanism, a 161-first adjusting sleeve, a 162-adjusting plate, a 163-adjusting platform, a 164-second adjusting sleeve, a 165-top wire hole, a 17-cylindrical rack supporting slide sleeve, a 18-twisting screw rod transmission assembly, a 19-twisting slide seat, a 20-twisting servo motor, a 02-traction device, a 21-piercing shaft, a 22-double row sprocket, a 23-traction servo motor, a 03-dislocation driving device, a 30-dislocation slide seat, a 31-dislocation slide rail assembly, a 32-dislocation slide plate, a 33-dislocation pull rod, a 34-dislocation screw rod support assembly, a 35-dislocation synchronous belt assembly, a 36-dislocation screw rod transmission assembly, a 37-dislocation, a 371-swing rod support assembly, a 372-dislocation gear, a 38-dislocation gap adjusting mechanism, a 39-dislocation servo motor, a 04-frame, a 05-dislocation screw rod transmission assembly, a 05-swing rod, a 52-lower screw plate and a 52-twisting screw plate.

Detailed Description

Preferred embodiments of the present utility model will be described below with reference to the accompanying drawings. It should be understood that the preferred embodiments described herein are presented for purposes of illustration and explanation only and are not intended to limit the present utility model.

The utility model discloses a numerical control horizontal gabion mesh machine, which is shown in fig. 1, and comprises a frame 04, wherein a wire twisting device 05 is arranged at the top of the frame 04, a traction device 02 is arranged at the front end of the frame 04, a twisting driving device 01 for driving the wire twisting device 05 to conduct twisting action is arranged on one side of the frame 04, and a dislocation driving device 03 for driving the wire twisting device 05 to conduct dislocation action is arranged on the other side of the frame 04; the twisting driving device 01 comprises a twisting driving part which is fixedly arranged on one side of the frame 04 and is connected with a twisting transmission part through a twisting synchronous belt assembly 14, the twisting transmission part is connected with a twisting shaft 15 through a twisting angle adjusting mechanism 16, and the twisting shaft 15 drives a twisting rack to conduct twisting action through a twisting gear 151; the dislocation driving device 03 comprises a dislocation driving part which is fixedly arranged on the other side of the frame 04 and is connected with a dislocation transmission part through a dislocation synchronous belt assembly 35, the dislocation transmission part is connected with a dislocation swing rod 37 through a dislocation gap adjusting mechanism 38, and the dislocation swing rod 37 drives the rubbing plate to perform dislocation motion through a dislocation gear 372. The screw twisting device 05 comprises a screw twisting wheel, an upper screw twisting rack, a lower screw twisting rack 53, an upper washboard 51 and a lower washboard 52, wherein the upper screw twisting rack, the lower screw twisting rack 53, the upper washboard 51 and the lower washboard 52 are used for driving the screw twisting wheel to conduct screw twisting, the upper screw twisting rack, the lower screw twisting rack 53, the upper washboard 51 and the lower washboard 52 are slidably arranged at the top of the frame 04, the screw twisting driving device 01 and the dislocation driving device 03 are controlled to operate through a control system, the screw twisting driving device 01 drives the upper screw twisting rack and the lower screw twisting rack 53 to conduct screw twisting, and the dislocation driving device 03 drives the upper washboard 51 and the lower washboard 52 to conduct left-right dislocation movement, so that the screw twisting wheel is driven to rotate to twist a silk-woven net. In the present embodiment, only the lower wire twisting rack 53 is shown, and the upper wire twisting rack is omitted. The module of the teeth on the screw rack is determined according to the mesh size, and the general module size is selected as follows: 3.5, 4, 4.5, 5.

As a specific embodiment, as shown in fig. 5-6, the twisting transmission part includes two longitudinally arranged cylindrical racks 11, one ends of the two cylindrical racks 11 are slidably connected with the frame 04 through a twisting support seat 10, a cylindrical rack support sliding sleeve 17 slidably matched with the cylindrical racks 11 is arranged on the twisting support seat 10, the other ends of the two cylindrical racks are fixedly connected with two side wings of the twisting slide plate 12, a plate body of the twisting slide plate 12 is slidably connected with the frame 04 through a twisting slide rail assembly 13 and a twisting slide seat 19, and is simultaneously connected with the twisting slide seat 19 through a twisting screw transmission assembly 18, and the twisting driving part is connected with the twisting screw transmission assembly 18 through a twisting synchronous belt assembly 14, and the two cylindrical racks 11 drive a twisting shaft 15 to rotate through a twisting angle gear 152 and a twisting angle adjusting mechanism 16.

Specifically, the twisting driving part comprises a twisting servo motor 20 and a speed reducer, the twisting screw transmission assembly 18 comprises a twisting screw rod, the twisting screw rod is rotatably installed on the twisting slide seat 19 through a bearing assembly, the twisting synchronous belt assembly 14 comprises two synchronous pulleys and a synchronous belt, the twisting servo motor 20 is fixedly arranged on the inner side of one side of the frame 04, an output shaft of the twisting servo motor is connected with an input shaft of the speed reducer, and the two synchronous pulleys are respectively installed on the twisting screw rod and the output shaft of the speed reducer and are connected through the synchronous belt.

Twisting working principle: the control system controls the twisting servo motor 20 to rotate, the twisting servo motor 20 drives the twisting screw rod to rotate through the speed reducer by virtue of the synchronous belt, the twisting screw rod rotates to drive the twisting slide plate 12 to slide up and down, the cylindrical racks 11 of the two wings of the twisting slide plate 12 slide up and down, meanwhile, the twisting angle gear 152 is driven to rotate, the twisting shaft 15 is driven to rotate by the twisting angle gear 152 through the twisting angle adjusting mechanism 16, the twisting gear 151 at the end part of the twisting shaft 15 rotates along with the twisting shaft, the twisting gear 151 drives the upper and lower twisting racks 53 to slide, and the upper and lower twisting racks 53 slide to drive the twisting wheels on the rack 04 to rotate to conduct twisting.

The number of rotations of the twisting servo motor 20 and the twisting screw rod can be changed through the control system, so that the up-down sliding stroke of the twisting slide plate 12 and the cylindrical rack 11 is changed, the number of rotations of the twisting angle gear 152, the twisting shaft 15 and the twisting gear 151 is changed, the sliding distance of the upper and lower twisting racks 53 is changed, the adjustment of twisting the hexagonal net is realized, through the structure, 3 flowers and 5 flowers of changing the hexagonal net can be randomly adjusted according to production needs or customer needs, simplicity and convenience are realized, the 3 flowers are twisting rotation for 2 circles, and the 5 flowers are twisting rotation for 3 circles.

As a specific embodiment, as shown in fig. 7-8, the twisting angle adjusting mechanism 16 includes a twisting angle adjusting sleeve assembly sleeved on the twisting shaft 15, the twisting angle adjusting sleeve assembly includes a first adjusting sleeve 161 and a second adjusting sleeve 164, one end of the first adjusting sleeve 161 is provided with an adjusting plate 162 with a corner structure, one end of the second adjusting sleeve 164 is provided with an adjusting platform 163 adapted to the adjusting plate 162, an adjusting angle between the adjusting plate 162 and the adjusting platform 163 is adjusted by adjusting a jackscrew, and a jackscrew hole 165 adapted to the adjusting jackscrew is formed in the adjusting plate 162. The first adjusting sleeve 161 and the adjusting plate 162 are coaxially and fixedly connected with the twisting shaft 15, the second adjusting sleeve 164 and the twisting angle gear 152 are rotatably connected with the twisting shaft 15, and the twisting shaft 15 is rotatably installed on the frame 04 through the twisting support seat 10 and the bearing assembly.

The gap is arranged between the adjusting plate 162 and the adjusting platform 163, the gap is controlled by adjusting the jackscrew, the cylindrical rack 11 is driven to rotate by a certain angle in the up-and-down motion process, the twisting angle gear 152 is driven to rotate by a certain angle through the second adjusting sleeve 164, the second adjusting sleeve 164 drives the first adjusting sleeve 161 and the twisting shaft 15 to rotate together to twist after rotating by the gap angle, and the fine adjustment of the effective stroke can be adjusted by adjusting the gap (namely the size of the idle stroke), so that the adjustment of the twisting angle is realized.

When the sliding stroke of the screw rack is finished and the dislocation starts, the joint surfaces of the upper half screw wheel and the lower half screw wheel of the screw wheel are required to be kept horizontal, so that the dislocation operation can be ensured to be smoothly carried out, otherwise, the clamping phenomenon is easy to occur, equipment is damaged, the adjusting jackscrew is fine-tuned, the fine-tuning of the screw angle of the screw wheel can be carried out by arranging the screw angle adjusting mechanism 16, in particular, when the stroke of the screw rod and the cylindrical rack 11 is larger, the clearance can be slightly larger, otherwise, the clearance can be slightly smaller, the joint surfaces of the two half screw wheels of the screw gear are ensured to be kept horizontal by arranging the clearance, the screw rack is required to be synchronously carried out with the dislocation of the upper screw plate 52 and the lower screw wheel when the screw rack is misplaced, the clearance is required to be kept horizontal when the upper screw plate 52 and the lower screw plate 52 are misplaced, the clearance drives the screw rack to synchronously move, the point fault tolerance is increased when the screw servo follows the dislocation, and the dislocation operation is ensured to be smoothly carried out after the screw.

As a specific embodiment, as shown in fig. 3-4, the dislocation transmission part includes a dislocation pull rod 33, the top end of the dislocation pull rod 33 is connected with a dislocation swing rod 37 through a dislocation gap adjusting mechanism 38, the bottom end is movably connected with the dislocation slide plate 32, the plate body of the dislocation slide plate 32 is connected with the frame 04 through a dislocation slide rail assembly 31 and a dislocation slide seat 30 in a sliding manner, and meanwhile, the dislocation transmission part is connected with the dislocation slide seat 30 through a dislocation lead screw transmission assembly 36, the dislocation driving part is connected with the dislocation lead screw transmission assembly 36 through a dislocation synchronous belt assembly 35, and the dislocation pull rod 33 drives the dislocation swing rod 37 to swing through the dislocation gap adjusting mechanism 38. The dislocation swing rod 37 is rotatably arranged at the top of the frame 04 through a swing rod supporting component 371.

Specifically, the dislocation driving part includes dislocation servo motor 39 and speed reducer, dislocation lead screw drive assembly 36 includes dislocation lead screw, dislocation lead screw passes through bearing assembly and dislocation lead screw supporting component 34 and rotates and install on dislocation slide 30, dislocation hold-in range subassembly 35 includes two synchronous pulleys and hold-in range, dislocation servo motor 39 sets firmly in frame 04 opposite side inboard, its output shaft links to each other with the input shaft of speed reducer, two synchronous pulleys are installed respectively on dislocation lead screw and the output shaft of speed reducer to link to each other through the hold-in range.

Working principle of dislocation: the control system controls the dislocation servo motor 39 to rotate, the dislocation servo motor 39 drives the dislocation screw rod to rotate through the speed reducer by virtue of the synchronous belt, the dislocation screw rod drives the dislocation slide plate 32 to slide up and down, the dislocation slide plate 32 drives the dislocation swing rod 37 to swing through the dislocation pull rod 33 by virtue of the dislocation gap adjusting mechanism 38, and the dislocation gear 372 at the end part of the dislocation swing rod 37 drives the upper washboard 52 to dislocation.

The control system can change the rotation number of the dislocation servo motor 39 and the dislocation screw rod, thereby changing the up-and-down sliding stroke of the dislocation slide plate 32, further changing the swing amplitude of the dislocation gap adjusting mechanism 38 pulled by the dislocation pull rod 33, changing the swing angle change of the dislocation swing rod 37, and realizing the adjustment of the dislocation distance of the upper and lower rubbing plates 52. And simultaneously, the size of the net hole can be adjusted randomly by matching with the thorn shaft 21 to pull the net.

As a specific embodiment, as shown in fig. 4, the dislocation pull rod 33 is a threaded telescopic rod structure, and includes a threaded rod and two threaded sleeves, wherein the two threaded sleeves are disposed at two ends of the threaded rod and are in threaded connection with the threaded rod, and the two threaded sleeves are threads in opposite directions, and the two threaded sleeves are respectively in rotational connection with the dislocation slide plate 32 and the dislocation gap adjusting mechanism 38.

The distance between the dislocation slide plate 32 and the dislocation gap adjusting mechanism 38 can be changed by rotating the threaded rod, so that the approach or the separation between the two threaded sleeves can be realized, and the fine adjustment of the angle of the dislocation swing rod 37 is realized, and meanwhile, the installation and the debugging of equipment are convenient.

As a specific implementation manner, the dislocation gap adjusting mechanism 38 is similar to the threading stroke adjusting mechanism, and comprises a connecting sleeve and a swinging sleeve, wherein the connecting sleeve is connected with one dislocation swing rod 37 through a tensioning sleeve, the swinging sleeve is sleeved on the other dislocation swing rod 37 and is provided with a connecting lug, the connecting lug is rotationally connected with the top end of the dislocation pull rod 33, a protruding part is constructed on the swinging sleeve, the connecting sleeve is provided with a groove part matched with the protruding part, and the top of the groove part is provided with an adjusting screw for adjusting the swinging angle of the dislocation swing rod 37. The protruding part is in large clearance fit with the groove part, the clearance between the protruding part and the groove part can be adjusted through the adjusting screw, fine adjustment of the dislocation clearance is carried out, fine adjustment of the swinging angle of the dislocation swinging rod 37 is carried out, and fine adjustment of the dislocation distance of the upper washboard 52 and the lower washboard 52 is further realized.

When the dislocation motion is carried out, the stress of the front washboard and the rear washboard of the frame 04 are different, the load of the front washboard is larger, the stress of the rear washboard is smaller, and the stress of the rear washboard is smaller, so that when the dislocation motion is carried out in actual use, the stroke of the rear washboard is overlarge when the stroke of the front washboard is adjusted, and the front washboard and the rear washboard can be ensured to be consistent when the load of the front washboard and the rear washboard are different through adjusting the dislocation gap.

As a specific embodiment, as shown in fig. 2, the traction device 02 includes a traction driving portion and a spindle 21, the spindle 21 rotates in front of the frame 04 through a bearing assembly and is located at a net outlet position of the wire twisting device 05, the traction driving portion is fixedly arranged at the other side of the frame 04, and the traction driving portion is in transmission connection with the spindle 21 through a sprocket transmission assembly.

The traction driving part comprises a traction servo motor 23 and a speed reducer, the chain wheel transmission assembly comprises two double-row chain wheels 22 and double-row chains, the traction servo motor 23 is fixedly arranged on the other side of the frame 04, an output shaft of the traction servo motor is connected with an input shaft of the speed reducer, and the two double-row chain wheels 22 are fixedly arranged at the end part of the output shaft of the speed reducer and one end of the thorn shaft 21 respectively and are connected through the double-row chains.

The traction servo motor 23 drives the double-row chain wheel 22 on the output shaft to rotate through the speed reducer, and the double-row chain wheel 22 drives the double-row chain wheel 22 at the end part of the thorn shaft 21 to rotate through the double-row chain, so that the thorn shaft 21 rotates to carry out net traction work. The rotation number of the traction servo motor 23 is adjusted through the control system, so that the rotation angle of the thorn shaft 21 for each traction net can be changed, the size of the woven meshes is changed, and the size of the woven meshes can be doubled.

To sum up, the power of this silk screen braiding equipment uses three servo motor drive, realizes twisting the adjustable controllable operation of flower, dislocation and jacquard weave respectively, drives the stroke change between slide and the slide through hold-in range drive assembly and ball drive assembly, realizes twisting the operation action of flower and dislocation, concrete work flow: left offset-positive twisting-right offset-reverse twisting, and one jacquard is performed while twisting each time, i.e. the thorn shaft 21 rotates by a certain angle. The device has simple and compact structure, better controllability and adjustability, lower device cost, stable operation and smaller noise generated in the production process compared with the prior art by adopting a complex connecting rod transmission mechanism and a gear transmission mechanism.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the scope of the claims of the present utility model.

Claims (8)

1. The utility model provides a horizontal gabion of numerical control net machine, includes the frame, the frame top is equipped with twists silk device, and the front end is equipped with draw gear, its characterized in that: one side of the frame is provided with a twisting driving device for driving the twisting device to conduct twisting action, and the other side of the frame is provided with a dislocation driving device for driving the twisting device to conduct dislocation action.

2. A numerically controlled horizontal gabion mesh machine as claimed in claim 1, wherein: the twisting driving device comprises a twisting driving part, the twisting driving part is fixedly arranged on one side of the frame and connected with the twisting transmission part through a twisting synchronous belt component, the twisting transmission part is connected with a twisting shaft through a twisting angle adjusting mechanism, and the twisting shaft drives a twisting rack to conduct twisting action through a twisting gear.

3. A numerically controlled horizontal gabion mesh machine as claimed in claim 2, wherein: the flower twisting transmission part comprises two longitudinally arranged cylindrical racks, one ends of the two cylindrical racks are connected with the frame in a sliding manner through a flower twisting supporting seat, the other ends of the two cylindrical racks are fixedly connected with two side wings of a flower twisting sliding plate, a plate body of the flower twisting sliding plate is connected with the frame in a sliding manner through a flower twisting sliding rail assembly and a flower twisting sliding seat, meanwhile, the flower twisting driving part is connected with the flower twisting sliding seat through a flower twisting screw transmission assembly, and the flower twisting driving part is connected with the flower twisting screw transmission assembly through a flower twisting synchronous belt assembly.

4. A numerically controlled horizontal gabion mesh machine according to claim 3, wherein: the twisting angle adjusting mechanism comprises a twisting angle adjusting sleeve assembly sleeved on a twisting shaft, the twisting angle adjusting sleeve assembly comprises a first adjusting sleeve and a second adjusting sleeve, one end of the first adjusting sleeve is provided with an adjusting plate of a corner structure, one end of the second adjusting sleeve is provided with an adjusting platform matched with the adjusting plate, adjustment of rotation angles of the adjusting plate and the adjusting platform is achieved through adjusting jackscrews, and jackscrew holes matched with the adjusting jackscrews are formed in the adjusting plate.

5. The numerical control horizontal gabion mesh machine of claim 4, wherein: the first adjusting sleeve and the adjusting plate are coaxially and fixedly connected with the twisting shaft, the second adjusting sleeve and the intermediate gear are rotationally connected with the twisting shaft, and the twisting shaft is rotationally installed on the frame through the twisting supporting seat and the bearing assembly.

6. A numerically controlled horizontal gabion mesh machine as claimed in claim 1, wherein: the dislocation driving device comprises a dislocation driving part which is fixedly arranged on the other side of the frame and connected with a dislocation transmission part through a dislocation synchronous belt assembly, the dislocation transmission part is connected with a dislocation swing rod through a dislocation gap adjusting mechanism, and the dislocation swing rod drives the rubbing plate to perform dislocation motion through a dislocation gear.

7. A numerically controlled horizontal gabion mesh machine as claimed in claim 1, wherein: the traction device comprises a traction driving part and a thorn shaft, the thorn shaft rotates in front of the frame through a bearing assembly and is positioned at a net outlet position of the wire twisting device, the traction driving part is fixedly arranged on the other side of the frame, and the traction driving part is in transmission connection with the thorn shaft through a sprocket transmission assembly.

8. A numerically controlled horizontal gabion mesh machine as claimed in claim 1, wherein: the twisting device comprises a twisting wheel, an upper twisting rack, a lower twisting rack, an upper washboard and a lower washboard, wherein the upper twisting rack, the lower twisting rack, the upper washboard and the lower washboard are used for driving the twisting wheel to conduct twisting action, the upper twisting rack, the lower twisting rack, the upper washboard and the lower washboard are slidably arranged at the top of the frame, the twisting driving device drives the upper twisting rack and the lower twisting rack to conduct twisting action, and the dislocation driving device drives the upper washboard and the lower washboard to conduct left-right dislocation action, so that the twisting wheel is driven to rotate to twist a wire mesh.