CN107350922B

CN107350922B - Middle riding wheel structure of horizontal glass double-sided edging machine

Info

Publication number: CN107350922B
Application number: CN201710688080.8A
Authority: CN
Inventors: 范漪
Original assignee: Guangdong Gaoliwei Machinery Technology Co ltd
Current assignee: Guangdong Gaoliwei Machinery Technology Co ltd
Priority date: 2017-08-12
Filing date: 2017-08-12
Publication date: 2023-04-21
Anticipated expiration: 2037-08-12
Also published as: CN107350922A

Abstract

The invention relates to a middle riding wheel structure of a horizontal glass bilateral edge grinder, which comprises a lathe bed assembly, a fixed edge assembly, a movable edge assembly, a middle riding wheel assembly and a driving mechanism for controlling the movable edge assembly to move left and right, wherein the fixed edge assembly and the movable edge assembly are respectively arranged at the left side and the right side of the lathe bed assembly, the fixed edge assembly and the movable edge assembly are used for supporting glass and conveying the glass forwards, the middle riding wheel assembly is arranged on the lathe bed assembly and is positioned between the fixed edge assembly and the movable edge assembly, the middle riding wheel assembly is linked with the movable edge assembly through a synchronous transmission device, and the left and right moving speed of the middle riding wheel assembly is smaller than the left and right moving speed of the movable edge assembly. The structure realizes electric adjustment by means of the power of the movable side assembly, and the adjustment and the movable side assembly are linked, so that the middle riding wheel assembly can be positioned at a reasonable position between the fixed side assembly and the movable side assembly, the working efficiency is improved, and the labor cost is greatly reduced.

Description

Middle riding wheel structure of horizontal glass double-sided edging machine

Technical Field

The invention relates to glass processing equipment, in particular to a middle riding wheel structure of a horizontal glass double-side edge grinding machine.

Background

Glass needs to be edging before using or tempering, and the glass moves on the conveying guide rails of the fixed edge structure and the movable edge structure, so that deformation of a glass plane is reduced, the grinding quality is influenced, and an intermediate riding wheel is used between the fixed structure and the movable structure to support the glass.

Referring to fig. 8 and 9, a horizontal glass double-sided edging machine with a manual middle riding wheel supporting structure comprises a lathe bed assembly 1, a fixed side assembly 2, a movable side assembly 4, a driving mechanism 8 and a middle riding wheel assembly 9, wherein a bracket beam 11 pointing left and right is arranged on the lathe bed assembly 1 (one end of the bracket beam 11 is fixed on the fixed side assembly 2, the other end of the bracket beam is fixed on the lathe bed assembly 1), the middle riding wheel assembly 9 is supported on the bracket beam 11, and a supporting roller 92 is arranged at the top of the middle riding wheel assembly 9. The fixed side assembly 2 and the movable side assembly 4 are respectively positioned on the left side and the right side of the lathe bed assembly 1, the fixed side assembly 2 comprises a first conveying guide rail 21 and a first driving box 22, the first conveying guide rail 21 is in transmission connection with the first driving box 22, and the fixed side assembly 2 is fixedly arranged on the lathe bed assembly 1; the movable edge assembly 4 comprises a second conveying guide rail 41 and a second driving box 44, the linear guide rail 43 is arranged on the lathe bed assembly 1 in a left-right pointing mode, the second conveying guide rail 41 is in transmission connection with the second driving box 44, the movable edge assembly 4 is arranged on the linear guide rail 43 and slides left and right along the linear guide rail 43, and therefore the distance between the second guide rail 41 and the first guide rail 21 can be adjusted to be suitable for glass 3 with different widths. The driving mechanism 8 comprises a motor and a reduction gearbox, and the motor is connected with the movable edge assembly 4 through the reduction gearbox and a screw transmission pair 81. When the prior art structure needs to change the width of the glass, two persons are required to move the middle riding wheel assembly 9 to the middle position of the glass along the bracket beam 11 at the same time. The manual intermediate riding wheel supporting structure has the following defects: (1) low processing efficiency: when the width of the glass is changed, the glass is required to be edged and stopped, and the middle riding wheel is installed and then grinded; (2) high labor cost: two operators are needed for each movement of the middle riding wheel; (3) extremely inconvenient in handling: other devices are arranged in the feeding and discharging directions of the general edge grinding machine, so that the feeding is very inconvenient, and people need to step on the machine body structure; (4) poor stability: when processing large-plate glass, especially when the glass enters a part of a feeding end, the bearing roller 92 is stressed in an unbalanced manner, so that the unstressed riding wheel post 91 of a discharging end is lifted up from the riding wheel beam 11, and the glass cannot move forwards; (5) inaccurate positioning: the randomness of manual movement is large and not accurate enough.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, and provides the middle riding wheel structure of the horizontal glass bilateral edge grinder, which has the advantages of reasonable structure, high working efficiency, reduction of the cost, good stability, high positioning precision and automatic operation.

The purpose of the invention is realized in the following way:

the utility model provides a bilateral edging machine intermediate riding wheel structure of horizontal glass, includes lathe bed assembly, fixed limit assembly, removes limit assembly, intermediate riding wheel assembly and is used for controlling the actuating mechanism who removes about the limit assembly, and fixed limit assembly and removal limit assembly set up respectively in the left and right sides of lathe bed assembly, and fixed limit assembly and removal limit assembly are used for holding glass and carry glass forward, and intermediate riding wheel assembly sets up on the lathe bed assembly and is located between fixed limit assembly and the removal limit assembly, characterized by, intermediate riding wheel assembly passes through synchronous transmission device and removes limit assembly linkage, and the left and right movement speed of intermediate riding wheel assembly is less than the left and right movement speed of removal limit assembly.

The aim of the invention can be also solved by adopting the following technical measures:

as a more specific scheme, the middle riding wheel assembly is positioned in the middle of the straight line distance between the fixed side assembly and the movable side assembly, and the left-right movement speed of the middle riding wheel assembly is half of the left-right movement speed of the movable side assembly. That is, the intermediate idler assembly is always in an intermediate position, supporting the middle of the bottom surface of the glass that spans between the fixed and moving edge assemblies, and the stress on the glass supported is averaged, regardless of how the moving edge assemblies are adjusted.

As a further scheme, the synchronous transmission device is a synchronous belt transmission device.

The synchronous belt transmission device comprises a driving belt pulley mechanism, a tensioning large belt pulley mechanism and a tensioning small belt pulley mechanism. The driving belt wheel mechanism comprises a driving large belt wheel, a first driven small belt wheel, a driving synchronous belt and a driven synchronous belt, wherein the driving large belt wheel and the first driven small belt wheel are coaxially arranged and simultaneously rotatably arranged on the lathe bed. The tensioning large belt wheel mechanism comprises a driven large belt wheel and a first tensioning adjustment seat, the driven large belt wheel is rotatably arranged on the first tensioning adjustment seat, the first tensioning adjustment seat is connected with the lathe bed assembly, the driving synchronous belt is arranged outside the driving large belt wheel and the driven large belt wheel in a tensioning mode, and the movable edge assembly is provided with a driving carriage which is fixedly connected with the driving synchronous belt. The tensioning small belt pulley mechanism is located between the driving belt pulley mechanism and the tensioning large belt pulley mechanism and comprises a second driven small belt pulley and a second tensioning adjustment seat, the second driven small belt pulley is rotatably arranged on the second tensioning adjustment seat, the second tensioning adjustment seat is connected with the lathe bed assembly, the driven synchronous belt is tensioned and arranged outside the first driven small belt pulley and the second driven small belt pulley, the middle riding wheel assembly is provided with a driven carriage, and the driven carriage is fixedly connected with the driven synchronous belt. The number of teeth of the driving large belt pulley is twice that of the first driven small belt pulley.

As a further scheme, the edge of the driving synchronous belt connected with the driving belt carriage is parallel to the upper plane of the linear guide rail of the lathe bed assembly, and the edge of the driven synchronous belt connected with the driven belt carriage is parallel to the upper plane of the linear guide rail of the lathe bed assembly, so that the moving distance of the synchronous belt and the moving distance of the moving edge assembly can be kept consistent.

The driving belt wheel mechanism further comprises a fixing seat, a first pin shaft, a first bearing and a first framework sealing ring, the fixing seat is fixedly connected with the lathe bed assembly, one end of the first pin shaft is connected with the fixing seat, the driving large belt wheel is provided with a center hole, the first driven small belt wheel is arranged at the outer end of the driving large belt wheel and covers the center hole, the center hole is sleeved outside the other end of the first pin shaft, the first bearing is located between the inner wall of the center hole and the outer wall of the first pin shaft, and the first framework sealing ring is sleeved outside the first pin shaft and encapsulates the first bearing in the center hole. The tensioning large belt wheel mechanism further comprises a second pin shaft, a second bearing and a second framework sealing ring, one end of the second pin shaft is connected with the first tensioning adjusting seat, the driven large belt wheel is provided with a central concave cavity, the central concave cavity is sleeved outside the other end of the second pin shaft, the second bearing is located between the inner wall of the central concave cavity and the outer wall of the second pin shaft, and the second framework sealing ring is sleeved outside the second pin shaft and seals the second bearing in the central concave cavity. The tensioning small belt pulley mechanism further comprises a third pin shaft, a third bearing and a third framework sealing ring, one end of the third pin shaft is connected with the second tensioning adjusting seat, the second driven small belt pulley is provided with a second center concave cavity, the second center concave cavity is sleeved outside the other end of the third pin shaft, the third bearing is located between the inner wall of the second center concave cavity and the outer wall of the third pin shaft, the third framework sealing ring is sleeved outside the third year pin shaft, and the third bearing is packaged in the second center concave cavity. The framework sealing rings can prevent glass dust and water from entering the bearing.

The driving synchronous belt and the driven synchronous belt comprise a PC material outer layer and a steel wire inner layer, and the PC material outer layer is tightly wrapped outside the steel wire inner layer. The PC material outer layer can have good meshing degree with the belt pulley, so that the running synchronization can be ensured, and the rust of the steel wire inner layer can be avoided.

The fixed edge assembly comprises a first conveying guide rail and a first driving box, the first driving box is in transmission connection with the first conveying guide rail, and the fixed edge assembly is fixed on the lathe bed assembly; the movable side assembly comprises a second conveying guide rail and a second driving box, the second driving box is in transmission connection with the second conveying guide rail, the movable side assembly is connected with a linear guide rail, the linear guide rail is arranged on the lathe bed assembly in a left-right pointing manner, and the movable side assembly slides left and right along the linear guide rail; the middle riding wheel assembly is arranged on the linear guide rail through a sliding plate; the driving mechanism comprises a motor and a reduction gearbox, and the motor is connected with the movable edge assembly through the reduction gearbox and a screw transmission pair.

The middle riding wheel assembly comprises supporting rollers, a wheel frame, a height adjusting frame and upright posts, wherein the supporting rollers are arranged on the wheel frame, the wheel frame is connected with the upright posts through the height adjusting frame, the upright posts are at least provided with a front part and a rear part, the lower ends of the following upright posts are respectively connected with the sliding plates, and the sliding plates are connected through connecting pipes. The connecting pipe is convenient for supporting the oil pipe when the sliding block of the linear guide rail is filled with oil.

The lathe bed assembly is provided with a front synchronous transmission device and a rear synchronous transmission device, the front synchronous transmission device and the rear synchronous transmission device are respectively connected with the front upright post and the rear upright post, and driving power is balanced.

The edges of the driving synchronous belt, which are connected with the driving carriage, and the edges of the driven synchronous belt, which are connected with the driven carriage, are parallel to the upper plane of the linear guide rail; the moving distance of the synchronous belt is ensured to be consistent with the moving distance of the moving edge assembly.

The height adjusting frame is provided with a long hole which points up and down corresponding to the surface of the upright post, and the height adjusting frame can be adjusted up and down along the long hole, namely, the height adjustment of the supporting roller is realized.

The beneficial effects of the invention are as follows:

(1) The middle riding wheel structure of the horizontal glass bilateral edge grinder realizes electric adjustment by means of the power of the movable side assembly (without adding an additional motor), and the adjustment is linked with the movable side assembly, so that the middle riding wheel assembly can be positioned at a reasonable position between the fixed side assembly and the movable side assembly, and the aims of high working efficiency and greatly reducing labor cost are fulfilled.

(2) The middle riding wheel structure of the horizontal glass bilateral edging machine is linked with the movable edge assembly through the synchronous belt transmission device, so that the operation noise is low, the cost is low, and the positioning is accurate.

(3) The left-right sliding of the middle riding wheel structure of the horizontal glass bilateral edging machine is realized by virtue of the linear guide rail, and a bracket beam in the prior art is not required to be additionally added.

(4) The middle riding wheel structure of the horizontal glass bilateral edging machine utilizes the original linear guide rail of the lathe bed structure to guide, and no matter how the middle riding wheel is stressed, the problem of rising like the prior art can not occur.

(5) The synchronous transmission device of the middle riding wheel structure of the horizontal glass bilateral edging machine is arranged outside the front side and the rear side of the lathe bed assembly, and is very convenient for tensioning and replacing synchronous belts.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present invention.

FIG. 2 isbase:Sub>A schematic view of the sectional A-A structure of FIG. 1.

Fig. 3 is an enlarged schematic view of the structure at B in fig. 2.

Fig. 4 is an enlarged schematic view of fig. 2 at C.

FIG. 5 is a schematic view of the cross-sectional structure a-a in FIG. 1.

FIG. 6 is a schematic view of the cross-sectional structure b-b of FIG. 1.

FIG. 7 is a schematic view of the cross-sectional structure of c-c in FIG. 1.

Fig. 8 is a schematic diagram of a prior art structure.

Fig. 9 is a schematic view of the D-D cross-sectional structure of fig. 8.

Detailed Description

The invention is further described below with reference to the drawings and examples.

Referring to fig. 1 to 4, an intermediate riding wheel structure of a horizontal glass double-sided edging machine comprises a lathe bed assembly 1, a fixed side assembly 2, a movable side assembly 4, an intermediate riding wheel assembly 9 and a driving mechanism 8 for controlling the movable side assembly 4 to move left and right, wherein the fixed side assembly 2 and the movable side assembly 4 are respectively arranged at the left side and the right side of the lathe bed assembly 1, the fixed side assembly 2 and the movable side assembly 4 are used for supporting glass 3 and conveying the glass 3 forwards, the intermediate riding wheel assembly 9 is arranged on the lathe bed assembly 1 and is positioned between the fixed side assembly 2 and the movable side assembly 4, the intermediate riding wheel assembly 9 is in linkage with the movable side assembly 4 through a synchronous transmission device, and the left and right movement speed of the intermediate riding wheel assembly 9 is smaller than the left and right movement speed of the movable side assembly 4.

As a further scheme, the middle riding wheel assembly 9 is positioned in the middle of the straight line distance between the fixed side assembly 2 and the movable side assembly 4, and the left-right movement speed of the middle riding wheel assembly 9 is half of the left-right movement speed of the movable side assembly 4.

The synchronous transmission device is a synchronous belt transmission device.

Referring to fig. 5-7, the synchronous belt transmission device comprises a driving pulley mechanism 5, a tensioning large pulley mechanism 7 and a tensioning small pulley mechanism 6; the driving pulley mechanism 5 comprises a driving large pulley 53, a first driven small pulley 54, a driving synchronous belt 52 and a driven synchronous belt 51, wherein the driving large pulley 53 and the first driven small pulley 54 are coaxially arranged and simultaneously rotatably arranged on the lathe bed assembly 1; the tensioning large belt wheel mechanism 7 comprises a driven large belt wheel 71 and a first tensioning adjustment seat, the driven large belt wheel 71 is rotatably arranged on the first tensioning adjustment seat, the first tensioning adjustment seat is connected with the lathe bed assembly 1, the driving synchronous belt 52 is arranged outside the driving large belt wheel 53 and the driven large belt wheel 71 in a tensioning manner, the movable edge assembly 4 is provided with a driving carriage 42, and the driving carriage 42 is fixedly connected with the driving synchronous belt 52; the tensioning small belt pulley mechanism 6 is located between the driving belt pulley mechanism 5 and the tensioning large belt pulley mechanism 7, and comprises a second driven small belt pulley 61 and a second tensioning adjustment seat, the second driven small belt pulley 61 is rotatably arranged on the second tensioning adjustment seat, the second tensioning adjustment seat is connected with the lathe bed assembly 1, the driven synchronous belt 51 is arranged outside the first driven small belt pulley 54 and the second driven small belt pulley 61 in a tensioning mode, the middle riding wheel assembly 9 is provided with a driven dragging plate 95, and the driven dragging plate 95 is fixedly connected with the driven synchronous belt 51.

The number of teeth of the driving large belt pulley 53 is twice that of the first driven small belt pulley 54.

The driving pulley mechanism 5 further comprises a fixing seat 57, a first pin shaft 55, a first bearing 58 and a first framework sealing ring 56, the fixing seat 57 is connected with the lathe bed assembly 1 in an adjustable mode, one end of the first pin shaft 55 is connected with the fixing seat 57, the driving large pulley 53 is provided with a center hole, the first driven small pulley 54 is arranged at the outer end of the driving large pulley 53 and covers the center hole, the center hole is sleeved outside the other end of the first pin shaft 55, the first bearing 58 is located between the inner wall of the center hole and the outer wall of the first pin shaft 55, and the first framework sealing ring 56 is sleeved outside the first pin shaft 55 and encapsulates the first bearing 58 in the center hole. The specific structure of the fixing base 57 is: the surface of the fixing seat 57 is provided with a vertically-directed long hole, a bolt passes through the long hole to be connected with the lathe bed assembly 1, and before the bolt is locked, the fixing seat 57 can be adjusted up and down along the long hole.

The tensioning large belt pulley mechanism 7 further comprises a second pin shaft 72, a second bearing 77 and a second framework sealing ring 76, one end of the second pin shaft 72 is connected with the first tensioning adjusting seat, the driven large belt pulley 71 is provided with a first center concave cavity, the first center concave cavity is sleeved outside the other end of the second pin shaft 72, the second bearing 77 is located between the inner wall of the first center concave cavity and the outer wall of the second pin shaft 72, the second framework sealing ring 76 is sleeved outside the second pin shaft 72, and the second bearing 77 is packaged in the first center concave cavity. The first tensioning adjustment seat comprises a first adjustment plate 78, a first fixing plate 75 and a first adjustment screw 74, the second pin shaft 72 is fixedly connected with the surface of the first adjustment plate 78, a transverse directional long hole is formed in the surface of the first adjustment plate 78, a bolt penetrates through the long hole to be connected with the lathe bed assembly 1, the first fixing plate 75 is fixedly connected with the lathe bed assembly 1 and is located beside the first adjustment plate 78, the first adjustment screw 74 is simultaneously connected with the first adjustment plate 78 and the first fixing plate 75, when the bolt is not screwed down, the first adjustment screw 74 is screwed down, the first adjustment plate 78 can be adjusted left and right to loosen or tension the active synchronous belt 52, and when the position of the first adjustment plate 78 is adjusted, the bolt is locked, namely the second pin shaft 72 and the lathe bed assembly 1 are fixed.

The tensioning small belt pulley mechanism 6 further comprises a third pin shaft 66, a third bearing 68 and a third framework sealing ring 67, one end of the third pin shaft 66 is connected with the second tensioning adjusting seat, the second driven small belt pulley 61 is provided with a second center concave cavity, the second center concave cavity is sleeved outside the other end of the third pin shaft 66, the third bearing 68 is located between the inner wall of the second center concave cavity and the outer wall of the third pin shaft 66, the third framework sealing ring 67 is sleeved outside the third-year pin shaft, and the third bearing 68 is packaged in the second center concave cavity. The second tensioning adjustment seat comprises a second adjustment plate 68, a second fixing plate 65 and a second adjustment screw 64, the third pin shaft 66 is fixedly connected with the surface of the second adjustment plate 68, a transverse directional long hole is formed in the surface of the second adjustment plate 68, a bolt penetrates through the long hole to be connected with the lathe bed assembly 1, the second fixing plate 65 is fixedly connected with the lathe bed assembly 1 and is located beside the second adjustment plate 68, the second adjustment screw 64 is simultaneously connected with the first adjustment plate 68 and the second fixing plate 65, when the bolt is not screwed down, the second adjustment screw 64 is screwed down, the second adjustment plate 68 can be adjusted left and right to loosen or tension the driven synchronous belt 51, and when the position of the second adjustment plate 68 is adjusted, the bolt is locked, namely the fixing of the third pin shaft 66 and the lathe bed assembly 1 is achieved.

The driving synchronous belt 52 and the driven synchronous belt 51 comprise a PC material outer layer and a steel wire inner layer, and the PC material outer layer is tightly wrapped outside the steel wire inner layer.

The fixed edge assembly 2 comprises a first conveying guide rail 21 and a first driving box 22, the first driving box 22 is in transmission connection with the first conveying guide rail 21, and the fixed edge assembly 2 is arranged on the lathe bed assembly 1; the movable side assembly 4 comprises a second conveying guide rail 41 and a second driving box 44, the second conveying guide rail 41 of the second driving box 44 is in transmission connection, the linear guide rail 43 is arranged on the lathe bed assembly 1 in a left-right direction, and the movable side assembly 4 is arranged on the linear guide rail 43 and slides left and right along the linear guide rail 43; the middle riding wheel assembly 9 is arranged on the linear guide rail 43 through a sliding plate 97; the driving mechanism 8 comprises a motor and a reduction gearbox, and the motor is in transmission connection with the movable edge assembly 4 through the reduction gearbox and a screw transmission pair 81 (ball screw).

The intermediate riding wheel assembly 9 comprises supporting rollers 92, a wheel frame 91, a height adjusting frame 93 and upright posts 94, wherein the supporting rollers 92 are arranged on the wheel frame 91, the wheel frame 91 is connected with the upright posts 94 through the height adjusting frame 93, the upright posts 94 are at least provided with a front upright post and a rear upright post, the lower ends of the upright posts 94 are respectively connected with the sliding plates 97, and the sliding plates 97 are connected through connecting pipes 96. The wheel frame 91 is an aluminum profile, and the aluminum profile is connected with the upright post 94 through a height adjusting frame 93 by bolts.

The lathe bed assembly 1 is provided with a front synchronous transmission device and a rear synchronous transmission device which are respectively connected with a front upright post 94 and a rear upright post 94.

The side of the driving synchronous belt 52 connected with the driving carriage 42 and the side of the driven synchronous belt 51 connected with the driven carriage 95 are parallel to the upper plane of the linear guide rail 43.

The height adjusting frame 93 is provided with an elongated hole 931 which is vertically directed in correspondence to the surface of the column 94.

Working principle: when the device works, the driving mechanism 8 drives the screw transmission pair 81 to operate, drives the movable edge assembly 4 to open and close towards/back to the fixed edge assembly 2, then drives the driving synchronous belt 52 to move through the driving carriage 42, drives the large driving belt wheel 53 and rotate, and further drives the driven carriage 95 and the middle riding wheel assembly 9 to move through the driven synchronous belt 51. Referring to fig. 1, when the movable side assembly 4 moves back to the fixed side assembly 2 for opening, the synchronous transmission device moves along the arrow direction R1, and the intermediate riding wheel assembly 9 moves along the arrow direction F1; when the movable side assembly 4 performs closing movement towards the fixed side assembly 2, the synchronous transmission device operates along the arrow direction R2, and the movable side assembly 4 and the intermediate riding wheel assembly 9 move along the arrow direction F2.

Claims

1. The utility model provides a bilateral edging machine intermediate riding wheel structure of horizontal glass, including lathe bed assembly (1), fixed limit assembly (2), remove limit assembly (4), intermediate riding wheel assembly (9) and be used for controlling the actuating mechanism (8) that removes about removing limit assembly (4), fixed limit assembly (2) and remove limit assembly (4) and set up respectively in the left and right sides of lathe bed assembly (1), fixed limit assembly (2) and remove limit assembly (4) and be used for holding glass, and carry glass forward, intermediate riding wheel assembly (9) set up on lathe bed assembly (1) and lie in between fixed limit assembly (2) and the remove limit assembly (4), characterized by, intermediate riding wheel assembly (9) are through synchronous transmission device and remove limit assembly (4) linkage, and the left and right movement speed of intermediate riding wheel assembly (9) is less than the left and right movement speed of removing limit assembly (4).

2. The middle riding wheel structure of the horizontal glass double-sided edging machine according to claim 1, wherein the middle riding wheel assembly (9) is positioned in the middle of the straight line distance between the fixed side assembly (2) and the movable side assembly (4), and the left-right movement speed of the middle riding wheel assembly (9) is half of the left-right movement speed of the movable side assembly (4).

3. The intermediate riding wheel structure of a horizontal glass double-sided edging machine according to claim 1 or 2, wherein the synchronous transmission device is a synchronous belt transmission device.

4. The intermediate riding wheel structure of the horizontal glass double-sided edging machine according to claim 3, wherein the synchronous belt transmission device comprises a driving belt wheel mechanism (5), a tensioning large belt wheel mechanism (7) and a tensioning small belt wheel mechanism (6);

the driving belt wheel mechanism (5) comprises a driving large belt wheel (53), a first driven small belt wheel (54), a driving synchronous belt (52) and a driven synchronous belt (51), wherein the driving large belt wheel (53) and the first driven small belt wheel (54) are coaxially arranged and simultaneously rotatably arranged on the lathe bed assembly (1);

the tensioning large belt wheel mechanism (7) comprises a driven large belt wheel (71) and a first tensioning adjustment seat, the driven large belt wheel (71) is rotatably arranged on the first tensioning adjustment seat, the first tensioning adjustment seat is connected with the lathe bed assembly (1), the driving synchronous belt (52) is arranged outside the driving large belt wheel (53) and the driven large belt wheel (71) in a tensioning mode, the movable edge assembly (4) is provided with a driving carriage (42), and the driving carriage (42) is fixedly connected with the driving synchronous belt (52);

the tensioning small belt wheel mechanism (6) is located between the driving belt wheel mechanism (5) and the tensioning large belt wheel mechanism (7), the tensioning small belt wheel mechanism comprises a second driven small belt wheel (61) and a second tensioning adjusting seat, the second driven small belt wheel (61) is rotatably arranged on the second tensioning adjusting seat, the second tensioning adjusting seat is connected with the lathe bed assembly (1), the driven synchronous belt (51) is arranged outside the first driven small belt wheel (54) and the second driven small belt wheel (61) in a tensioning mode, the middle riding wheel assembly (9) is provided with a driven dragging plate (95), and the driven dragging plate (95) is fixedly connected with the driven synchronous belt (51).

5. The middle riding wheel structure of the horizontal glass bilateral edge grinder according to claim 4, wherein the driving belt wheel mechanism (5) further comprises a fixed seat (57), a first pin shaft (55), a first bearing (58) and a first framework sealing ring (56), the fixed seat (57) is adjustably connected with the lathe bed assembly (1), one end of the first pin shaft (55) is connected with the fixed seat (57), the driving large belt wheel (53) is provided with a central hole, the first driven small belt wheel (54) is arranged at the outer end of the driving large belt wheel (53) and covers the central hole, the central hole is sleeved outside the other end of the first pin shaft (55), the first bearing (58) is positioned between the inner wall of the central hole and the outer wall of the first pin shaft (55), and the first framework sealing ring (56) is sleeved outside the first pin shaft (55) and encapsulates the first bearing (58) in the central hole;

the tensioning large belt wheel mechanism (7) further comprises a second pin shaft (72), a second bearing (77) and a second framework sealing ring (76), one end of the second pin shaft (72) is connected with the first tensioning adjusting seat, the driven large belt wheel (71) is provided with a first center concave cavity, the first center concave cavity is sleeved outside the other end of the second pin shaft (72), the second bearing (77) is positioned between the inner wall of the first center concave cavity and the outer wall of the second pin shaft (72), and the second framework sealing ring (76) is sleeved outside the second pin shaft (72) and encapsulates the second bearing (77) in the first center concave cavity;

the tensioning small belt pulley mechanism (6) further comprises a third pin shaft (66), a third bearing (68) and a third framework sealing ring (67), one end of the third pin shaft (66) is connected with the second tensioning adjusting seat, the second driven small belt pulley (61) is provided with a second center concave cavity, the second center concave cavity is sleeved outside the other end of the third pin shaft (66), the third bearing (68) is located between the inner wall of the second center concave cavity and the outer wall of the third pin shaft (66), and the third framework sealing ring (67) is sleeved outside the third year pin shaft and encapsulates the third bearing (68) in the second center concave cavity.

6. The intermediate riding wheel structure of the horizontal glass double-sided edging machine according to claim 4, wherein the driving synchronous belt (52) and the driven synchronous belt (51) comprise a PC material outer layer and a steel wire inner layer, and the PC material outer layer is tightly wrapped outside the steel wire inner layer.

7. The middle riding wheel structure of the horizontal glass double-sided edging machine according to claim 4, wherein the fixed-side assembly (2) comprises a first conveying guide rail (21) and a first driving box (22), and the first driving box is in transmission connection with the first conveying guide rail (21); the movable edge assembly (4) comprises a second conveying guide rail (41) and a second driving box (44), the second driving box (44) is in transmission connection with the second conveying guide rail (41), the linear guide rail (43) is arranged on the lathe bed assembly (1) in a left-right direction, and the movable edge assembly (4) is arranged on the linear guide rail (43) and slides left and right along the linear guide rail (43); the middle riding wheel assembly (9) is arranged on the linear guide rail (43) through a sliding plate (97); the driving mechanism (8) comprises a motor and a reduction gearbox, and the motor is in transmission connection with the movable edge assembly (4) through the reduction gearbox and a screw transmission pair (81).

8. The middle riding wheel structure of the horizontal glass bilateral edge grinder according to claim 7, wherein the middle riding wheel assembly (9) comprises a supporting roller (92), a wheel frame (91), a height adjusting frame (93) and upright posts (94), the supporting roller (92) is arranged on the wheel frame (91), the wheel frame (91) is connected with the upright posts (94) through the height adjusting frame (93), the upright posts (94) are provided with a front upright post and a rear upright post, the lower ends of the upright posts (94) are respectively connected with the sliding plates (97), and the sliding plates (97) are connected through connecting pipes (96).

9. The middle riding wheel structure of the horizontal glass bilateral edge grinder according to claim 8, wherein the lathe bed assembly (1) is provided with a front synchronous transmission device and a rear synchronous transmission device which are respectively connected with a front upright post and a rear upright post (94).

10. The middle riding wheel structure of the horizontal glass double-sided edging machine according to claim 7, wherein the edge of the driving synchronous belt (52) connected with the driving carriage (42) and the edge of the driven synchronous belt (51) connected with the driven carriage (95) are parallel to the upper plane of the linear guide rail (43).