CN213290901U - Operating table for glass processing center - Google Patents

Abstract

The application relates to the field of glass processing, in particular to an operating platform for a glass processing center, which comprises a flat plate and a plurality of supporting columns arranged on the lower surface of the flat plate, wherein a plurality of through holes which are the same as the flat plate in the length direction are formed in the flat plate, and the plurality of through holes are distributed at intervals in the width direction of the flat plate; each through hole is internally provided with a conveyor belt mechanism which has the same length direction with the through hole, and the conveyor belt mechanisms are fixedly connected together through a connecting frame; and a lifting mechanism for driving the connecting frame to lift up and down is arranged below the connecting frame. The scheme reduces the workload of operators when carrying glass, greatly facilitates the operation of the operators and effectively improves the processing efficiency of the glass.

Description

Operating table for glass processing center

Technical Field

The application relates to the field of glass processing, in particular to an operating console for a glass processing center.

Background

A glass processing center is a processing device that performs a cutting operation on glass, which is performed on a table of the glass processing center. Because the operation panel on the market is mostly simple plane formula, glass's removal needs the manpower that needs through many operative employee to carry and realizes, and this kind of mode of removing glass wastes time and energy, has seriously reduced glass's machining efficiency.

SUMMERY OF THE UTILITY MODEL

In order to facilitate the glass moving of an operator and improve the processing efficiency of the glass, the application provides an operation table for a glass processing center.

The application provides an operation panel for glass machining center adopts following technical scheme:

an operating platform for a glass processing center comprises a flat plate and a plurality of supporting columns arranged on the lower surface of the flat plate, wherein a plurality of through holes which are the same as the flat plate in the length direction are formed in the flat plate, and the through holes are distributed at intervals in the width direction of the flat plate; each through hole is internally provided with a conveyor belt mechanism which has the same length direction with the through hole, and the conveyor belt mechanisms are fixedly connected together through a connecting frame; a lifting mechanism for driving the connecting frame to lift up and down is arranged below the connecting frame; both ends of the flat plate are provided with a row of universal wheels for supporting glass.

Through adopting above-mentioned technical scheme, when needs place glass on the flat board, the operative employee can order about the link through elevating system and rise, and many conveyor mechanisms will rise together and the part wears out dull and stereotyped upper surface along with the link, and behind glass contacted conveyor mechanism, conveyor mechanism alright realize the transportation to glass. When the glass moves to a proper position, the operator stops the conveyor belt mechanism, and drives the connecting frame and the conveyor belt mechanism to descend through the lifting mechanism, so that the glass can be successfully placed on the flat plate. When the glass needs to be moved out of the flat plate, an operator jacks up the glass through the lifting mechanism and then transports the glass away through the conveyor belt mechanism. In addition, the universal wheels can provide certain supporting force for the glass in the glass conveying process, so that the force of an operator in the glass conveying process is saved, and the operator can slide the glass to the conveyor belt mechanism more smoothly by means of the universal wheels. Compare in traditional operation panel, this scheme has reduced the work load when operative employee transport glass, has made things convenient for operative employee's operation greatly, has effectively improved glass's machining efficiency.

Preferably, the lifting mechanism comprises four bottom plates which are arranged below the connecting frame and distributed in a cross shape, a sliding groove which is formed in the bottom plate and is the same as the bottom plate in length direction, a sliding block which is in sliding fit with the sliding groove, a linkage rod which is hinged between the sliding block and the connecting frame and is used for driving the connecting frame to move up and down, and a driving assembly which is arranged between the four bottom plates and is used for driving the four sliding blocks to be folded or unfolded simultaneously.

Through adopting above-mentioned technical scheme, the operative employee controls four sliders through drive assembly and draws in simultaneously or open, and the one end of gangbar not only can slide along with the slider synchronization emergence that corresponds, still can take place rotatoryly round the pin joint with the slider, and the other end of gangbar will also rotate round the pin joint with the backup pad, and the contained angle of four gangbars and horizontal plane will diminish simultaneously or grow, and four gangbars alright order about link and the simultaneous oscilaltion of conveyer belt mechanism. The lifting mechanism is ingenious in structural design, the stability of the connecting frame and the conveyor belt mechanism in the lifting process is guaranteed, and the operation steps are very convenient and fast.

Preferably, the driving assembly comprises a threaded rod which is rotatably connected in the sliding groove and has the same length direction with the sliding groove, and the threaded rod penetrates through the sliding block in the corresponding sliding groove and is in threaded fit with the sliding block; the driving assembly further comprises driving pieces which are arranged among the four bottom plates and used for synchronously rotating the four threaded rods.

By adopting the technical scheme, an operator synchronously rotates the four threaded rods through the driving piece, the four sliding blocks slide in the corresponding sliding grooves under the traction of the threads and the position constraint of the sliding grooves, and the four sliding blocks can be folded or unfolded simultaneously. The driving mechanism greatly facilitates the operation of operators and is beneficial to improving the processing efficiency of glass.

Preferably, the driving part comprises a first bevel gear rotationally connected to the center of the four bottom plates, a second bevel gear fixedly sleeved on the threaded rod and meshed with the first bevel gear, and a second motor arranged on the center of the four bottom plates and used for rotating the first bevel gear.

Through adopting above-mentioned technical scheme, the operative employee starts the second motor and rotates first bevel gear, and under the meshing effect of first bevel gear and four second bevel gears, four threaded rods alright take place the rotation in step. The arrangement of the driving part not only saves the manufacturing cost of the equipment, but also is very convenient in operation.

Preferably, the sliding block is embedded with a ball which is abutted against the inner wall of the sliding groove in a rolling manner.

Through adopting above-mentioned technical scheme, the ball can reduce the frictional resistance that the slider received when sliding, and the sliding of slider in the spout will be more smooth, and the lift process of link and conveyer belt mechanism will be more smooth.

Preferably, four corners of the connecting frame are provided with vertical limiting pipes, a vertical limiting rod is inserted into each limiting pipe, and the lower end of each limiting rod is fixedly connected to the ground.

Through adopting above-mentioned technical scheme, the setting of gag lever post and spacing pipe can be spacing reciprocating of link to make conveyer belt mechanism can more accurately shuttle through-hole, guaranteed glass's normal transportation.

Preferably, the conveyer belt mechanism is including being located the through-hole and with the same support of through-hole length direction, rotate the action wheel of connecting on one end of support, rotate a plurality of follow driving wheels of connecting on the support, rotate the cover and establish the belt between action wheel and follow driving wheel to and set up the first motor that is used for rotatory action wheel on the support.

Through adopting above-mentioned technical scheme, the operative employee starts behind the first motor, and the belt just can take place to rotate between action wheel and the follow driving wheel to the realization is to the automatic transportation of glass. The structure principle of the driving belt mechanism is simple, and the operation process is convenient and fast.

Preferably, a plurality of rubber sheets for abutting against the glass are distributed on the belt at intervals.

Through adopting above-mentioned technical scheme, the rubber piece can increase the frictional force that produces when belt and glass contact, greatly reduced the condition that glass skidded on the belt.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the arrangement of the through holes, the conveyor belt mechanism, the connecting frame, the lifting mechanism and the universal wheels facilitates the glass moving of an operator, and improves the processing efficiency of the glass;

2. the arrangement of the balls can make the lifting process of the connecting frame and the conveying belt mechanism smoother;

3. the arrangement of the limiting rod and the limiting pipe can enable the conveyor belt mechanism to shuttle in the through hole more accurately, and ensure the normal transportation of glass;

4. the rubber sheet greatly reduces the slipping of the glass on the belt.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is a schematic view of the present invention in partial section;

fig. 3 is a partially enlarged schematic view of a portion a in fig. 2.

Description of reference numerals: 1. a flat plate; 2. a support pillar; 3. a through hole; 4. a support; 5. a driving wheel; 6. a first motor; 7. a driven wheel; 8. a belt; 9. a rubber sheet; 10. a universal wheel; 11. a connecting frame; 12. a base plate; 13. a chute; 14. a slider; 15. a ball bearing; 16. a linkage rod; 17. a threaded rod; 18. a second bevel gear; 19. a first bevel gear; 20. a second motor; 21. a limiting pipe; 22. a limiting rod.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

Referring to fig. 1 and 2, an operating table for a glass processing center includes a flat plate 1 on which glass is horizontally placed, and vertical support columns 2 attached to four corners of the flat plate 1. Three through holes 3 with the same length as the flat plate 1 are formed in the flat plate 1, and the three through holes 3 are distributed at equal intervals along the width direction of the flat plate 1. All be equipped with one in every through-hole 3 with the same support 4 of 3 length direction of through-hole, rotate on the one end of support 4 and be connected with action wheel 5 and the rotatory first motor 6 of drive action wheel 5, first motor 6 passes through the electric wire and is connected with the power, rotate on the support 4 and be connected with a plurality of from driving wheel 7, rotate between driving wheel 7 and the action wheel 5 to overlap and be equipped with the belt 8 that is used for transporting glass. In order to reduce the probability of the glass slipping in the transportation process, a plurality of rubber sheets 9 for increasing friction force are distributed on the belt 8 at equal intervals. The support 4, the driving wheel 5, the driven wheel 7, the belt 8 and the first motor 6 form a conveyor belt mechanism. The three first motors 6 are simultaneously started by an operator to rotate the three belts 8, and when the glass contacts the three belts 8, the glass can be transported by the three belts 8, so that the workload of the operator for carrying the glass is greatly reduced, and convenience is brought to the operation of the operator. If the glass is to be removed, the operator rotates the belt 8 in the reverse direction by the first motor 6.

Referring to fig. 1, a plurality of universal wheels 10 for supporting glass are provided on both ends of a flat plate 1, and the plurality of universal wheels 10 are equally spaced apart in a width direction of the flat plate 1. The universal wheels 10 can provide certain supporting force for the glass in the glass conveying process, so that the force of an operator in the glass conveying process is saved, and meanwhile, the operator can enable the glass to smoothly slide to the belt 8 by means of the universal wheels 10.

Referring to fig. 2 and 3, each of the three brackets 4 can move up and down in the corresponding through hole 3, and the three brackets 4 are fixedly connected together through the connecting frame 11. Four bottom plates 12 distributed in a cross shape are arranged below the connecting frame 11, and the cross points of the four bottom plates 12, the central point of the connecting frame 11 and the central point of the flat plate 1 are all on the same vertical line. Each bottom plate 12 is provided with a sliding groove 13 with the same length direction, a sliding block 14 is attached to the sliding groove 13 in a sliding mode, the sliding block 14 can slide along the length direction of the corresponding sliding groove 13, and the distances from the four sliding blocks 14 to the cross point of the bottom plate 12 are equal. Each sliding block 14 is embedded with a ball 15 which is abutted against the bottom of the sliding groove 13 in a rolling manner, and the ball 15 is used for reducing the friction resistance borne by the sliding block 14 during sliding. A linkage rod 16 is hinged between each sliding block 14 and the connecting frame 11, and hinged points of the four linkage rods 16 and the lower surface of the connecting frame 11 are distributed at equal-angle intervals around the central point of the connecting frame 11. A threaded rod 17 in threaded fit with the corresponding sliding block 14 is rotatably connected in each sliding groove 13, and the length direction of the threaded rod 17 is consistent with that of the corresponding sliding groove 13. One ends of the four threaded rods 17, which are close to the intersection of the bottom plate 12, are fixedly sleeved with second bevel gears 18, the intersection of the bottom plate 12 is rotatably connected with a first bevel gear 19, the first bevel gear 19 and the four second bevel gears 18 are all kept meshed, the intersection of the bottom plate 12 is also provided with a second motor 20 for rotating the first bevel gear 19, and the first motor 6 is connected with a power supply through an electric wire. Wherein, the first bevel gear 19, the second bevel gear 18 and the first motor 6 form a driving part for synchronously rotating the four threaded rods 17; the threaded rod 17 and the driving part form a driving component for driving the four sliding blocks 14 to simultaneously fold or unfold; the bottom plate 12, the sliding groove 13, the sliding block 14, the linkage rod 16 and the driving component form a lifting mechanism for lifting the connecting frame 11 up and down. When glass needs to be conveyed to the flat plate 1, an operator starts the first motor 6 to rotate the first bevel gear 19, under the linkage action of the first bevel gear 19 and the four second bevel gears 18, the four threaded rods 17 synchronously rotate, under the traction of the threads and the position constraint of the sliding chute 13, the four sliding blocks 14 simultaneously slide towards the direction away from the cross point of the bottom plate 12, the lower ends of the linkage rods 16 synchronously move along with the corresponding sliding blocks 14 and rotate around the hinge points with the corresponding sliding blocks 14, the upper ends of the linkage rods 16 rotate around the hinge points with the connecting frame 11, the included angles between the linkage rods 16 and the horizontal plane are gradually increased, so that the connecting frame 11 is driven to move upwards, and the conveyor belt mechanism passes through the corresponding through holes 3 to reach the upper side of the flat plate 1. When the glass contacts the belts 8, the three belts 8 can transport the glass. After the glass is transported to a proper position, the operator stops the first motor 6, and simultaneously rotates the second motor 20 in the reverse direction to gradually reduce the included angle between the linkage rod 16 and the horizontal plane, so that the height of the connecting frame 11 is reduced, the belt 8 is retracted into the corresponding through hole 3, and the glass can be successfully placed on the flat plate 1. After the glass is cut, the operator reverses the operation and removes the glass.

Referring to fig. 2, four corners of the connecting frame 11 are fixedly connected with vertical limiting pipes 21, a limiting rod 22 fixedly connected with the ground is inserted into each limiting pipe 21, and the side wall of each limiting rod 22 is attached to the inner side wall of each limiting pipe 21. The limiting pipe 21 and the limiting rod 22 can restrain the lifting of the connecting frame 11 in position, so that the belt 8 can accurately shuttle up and down in the through hole 3, and the guarantee is provided for the normal transportation of glass.

The implementation principle of the embodiment is as follows: when glass needs to be conveyed to the flat plate 1, an operator starts the first motor 6 to rotate the first bevel gear 19, under the linkage action of the first bevel gear 19 and the four second bevel gears 18, the four threaded rods 17 synchronously rotate, under the traction of the threads and the position constraint of the sliding chute 13, the four sliding blocks 14 simultaneously slide towards the direction away from the cross point of the bottom plate 12, the lower ends of the linkage rods 16 synchronously move along with the corresponding sliding blocks 14 and rotate around the hinge points with the corresponding sliding blocks 14, the upper ends of the linkage rods 16 rotate around the hinge points with the connecting frame 11, the included angles between the linkage rods 16 and the horizontal plane are gradually increased, so that the connecting frame 11 is driven to move upwards, and the conveyor belt mechanism passes through the corresponding through holes 3 to reach the upper side of the flat plate 1. When the glass contacts the belts 8, the three belts 8 can transport the glass. After the glass is transported to a proper position, the operator stops the first motor 6, and simultaneously rotates the second motor 20 in the reverse direction to gradually reduce the included angle between the linkage rod 16 and the horizontal plane, so that the height of the connecting frame 11 is reduced, the belt 8 is retracted into the corresponding through hole 3, and the glass can be successfully placed on the flat plate 1. After the glass is cut, the operator reverses the operation and removes the glass.

The embodiment of this specific implementation mode is the preferred embodiment of the present invention, not limit according to this the utility model discloses a protection scope, so: all equivalent changes made according to the structure, shape and principle of the utility model are covered within the protection scope of the utility model.

Claims (8)

1. The utility model provides an operation panel for glass machining center, includes dull and stereotyped (1) to and set up many spinal branchs post (2) at dull and stereotyped (1) lower surface, its characterized in that: a plurality of through holes (3) which are the same as the flat plate (1) in the length direction are formed in the flat plate (1), and the through holes (3) are distributed at intervals in the width direction of the flat plate (1); each through hole (3) is internally provided with a conveyor belt mechanism which has the same length direction with the through holes (3), and a plurality of conveyor belt mechanisms are fixedly connected together through a connecting frame (11); a lifting mechanism for driving the connecting frame (11) to lift up and down is arranged below the connecting frame (11); both ends of the flat plate (1) are provided with a row of universal wheels (10) for supporting glass.

2. The station of claim 1, wherein: the lifting mechanism comprises four bottom plates (12) which are arranged below the connecting frame (11) and distributed in a cross shape, sliding grooves (13) which are formed in the bottom plates (12) and are identical to the bottom plates (12) in length direction, sliding blocks (14) which are attached to the sliding grooves (13) in a sliding mode, linkage rods (16) which are hinged between the sliding blocks (14) and the connecting frame (11) and are used for driving the connecting frame (11) to move up and down, and driving assemblies which are arranged between the four bottom plates (12) and are used for driving the four sliding blocks (14) to be folded or unfolded simultaneously.

3. The console for a glass processing center of claim 2, wherein: the driving assembly comprises a threaded rod (17) which is rotatably connected in the sliding groove (13) and has the same length direction with the sliding groove (13), and the threaded rod (17) penetrates through the sliding block (14) in the corresponding sliding groove (13) and is in threaded fit with the sliding block (14); the driving component also comprises a driving part which is arranged among the four bottom plates (12) and is used for synchronously rotating the four threaded rods (17).

4. The station of claim 3, wherein: the driving part comprises a first bevel gear (19) rotationally connected to the center of the four bottom plates (12), a second bevel gear (18) fixedly sleeved on the threaded rod (17) and meshed with the first bevel gear (19), and a second motor (20) arranged on the center of the four bottom plates (12) and used for rotating the first bevel gear (19).

5. The console for a glass processing center of claim 2, wherein: and the sliding block (14) is provided with a rolling ball (15) which is abutted against the inner wall of the sliding groove (13) in a rolling and embedding way.

6. The station of claim 1, wherein: vertical limiting pipes (21) are arranged on four corners of the connecting frame (11), a vertical limiting rod (22) is inserted into each limiting pipe (21), and the lower end of each limiting rod (22) is fixedly connected to the ground.

7. The station of claim 1, wherein: the conveyor belt mechanism comprises a support (4) which is located in the through hole (3) and is the same as the through hole (3) in length direction, a driving wheel (5) which is connected to one end of the support (4) in a rotating mode, a plurality of driven wheels (7) which are connected to the support (4) in a rotating mode, a belt (8) which is sleeved between the driving wheel (5) and the driven wheels (7) in a rotating mode, and a first motor (6) which is arranged on the support (4) and used for rotating the driving wheel (5).

8. The console for a glass processing center of claim 7, wherein: a plurality of rubber sheets (9) used for abutting against the glass are distributed on the belt (8) at intervals.

Images