CN220055489U - Glass conveying device capable of conveying in criss-cross mode - Google Patents

Abstract

The utility model relates to the field of conveying equipment, in particular to a glass conveying device capable of realizing criss-cross conveying of stable transfer support under the action of dynamic load, which comprises a frame, wherein a transverse conveying device and a longitudinal conveying device for conveying glass are arranged on the frame, a transfer mechanism for receiving the glass conveyed by the longitudinal conveying device is also arranged on a conveying path of the transverse conveying device on the frame, and the transfer mechanism comprises a second frame which is arranged on the frame and can slide up and down, a second conveying device arranged on the second frame and used for receiving the glass conveyed by the longitudinal conveying device, and a first driving device arranged on the frame and used for driving the second frame to slide up and down.

Description

Glass conveying device capable of conveying in criss-cross mode

Technical Field

The utility model relates to the field of conveying equipment, in particular to a glass conveying device capable of conveying vertically and horizontally in a staggered mode.

Background

With the progress of technology, the automation level of equipment is higher and higher, and in the automatic production process, the use of conveying equipment plays a very important role. In the glass manufacturing industry, in order to improve the efficiency of glass production, it is generally required to automatically convey the glass in a panel shape and cut and convey the glass to a position where the glass is packed and stored in the conveying process, however, due to the limitation of the production field, the glass conveying device is often required to be designed into an interlaced shape, but the interlaced glass conveying device is required to design a switching mechanism so that the conveying glass from different conveying directions can be effectively connected, and especially for the interlaced glass conveying device not at the same conveying height, the design requirement of the switching mechanism is higher. In order to realize the switching of conveying surfaces with different heights and save the cost, a driving device of the switching mechanism usually adopts an air cylinder, but as conveying glass gradually enters the conveying surface of the switching mechanism, the bearing weight of the switching mechanism is continuously increased, and the vibration of the conveying surface of the glass is easily caused, so that the conveying of the glass is not facilitated. When the size of the conveyed glass is large, the number of required air cylinders is increased, so that the whole conveying surface of the glass can be stably supported, and the difficulty of synchronous control is increased due to the increase of the number of the air cylinders.

Disclosure of Invention

The utility model aims to solve the problems and provides a glass conveying device capable of realizing crisscross conveying of stable switching support under the action of dynamic load.

In order to achieve the above purpose, the utility model discloses a glass conveying device capable of conveying glass in a crisscross manner, which comprises a rack, wherein a transverse conveying device and a longitudinal conveying device for conveying glass are arranged on the rack, a switching mechanism for receiving the glass conveyed by the longitudinal conveying device is also arranged on a conveying path of the transverse conveying device on the rack, and the switching mechanism comprises a second rack which is arranged on the rack in a vertically sliding manner, a second conveying device which is arranged on the second rack and is used for receiving the glass conveyed by the longitudinal conveying device, and a first driving device which is arranged on the rack and is used for driving the second rack to slide vertically.

The further improvement is that: the first driving device comprises a first driving motor arranged on the frame, a speed reducer in transmission connection with an output shaft of the first driving motor, and a rotating piece in transmission connection with an output shaft of the speed reducer, wherein the other end of the rotating piece is movably connected with the second frame.

The further improvement is that: the first driving device further comprises a limiting device which is arranged on one end of the rotating piece and on the frame, wherein the limiting device comprises a first connecting rod movably connected with one end of the rotating piece, a second connecting rod movably connected with the first connecting rod and the other end of the first connecting rod and the frame, a third connecting rod movably connected with one end of the rotating piece and positioned on one side of the first connecting rod, a fourth connecting rod movably connected with the third connecting rod and the other end of the third connecting rod and movably connected with the frame, and two limiting rods which are arranged on the frame and positioned on two sides of the second connecting rod.

The further improvement is that: the second frame includes the slidable from top to bottom set up in backup pad in the frame, set firmly in backup pad lower extreme along a plurality of crossbeams that left and right sides set up and set firmly in backup pad upper end along a plurality of pillars that left and right sides and front and back direction set up respectively at intervals, at least one of crossbeam with first drive arrangement swing joint, each pillar with second conveyor is connected.

The further improvement is that: and a plurality of parallel connecting rods are further arranged on each cross beam, one end of each parallel connecting rod is movably connected with the cross beam through a second roller wheel rotatably arranged at one end of each parallel connecting rod, and the other end of each parallel connecting rod is movably connected with the frame.

The further improvement is that: and a plurality of grooves are also formed in each cross beam, the upper end and the lower end of at least one groove in each groove are connected with the first roller in a matched manner, the upper end and the lower end of the other grooves are connected with the second roller in a matched manner, and the length of each groove is larger than the diameter of the first roller and the diameter of the second roller.

The further improvement is that: the front end and the rear end of the two cross beams at the left end and the right end are respectively provided with a guide device for guiding the support plate to slide up and down, and the guide device comprises a third roller which is rotatably arranged at the end part of the corresponding cross beam and a guide rail which is fixedly arranged on the frame and is in matched connection with the third roller.

The further improvement is that: the second conveying device comprises a plurality of conveying lines arranged at the upper ends of the corresponding support columns in the front-rear direction and a second driving device arranged at the upper ends of the support plates and used for driving the conveying lines to synchronously work.

The further improvement is that: each conveying line comprises a first driving belt pulley rotatably arranged at the upper end of each support column at the front side of the supporting plate, a first driven belt pulley rotatably arranged at the upper end of each support column at the rear side of the supporting plate, and a first conveying belt wound on each first driving belt pulley and each first driven belt pulley.

The further improvement is that: the second driving device comprises a second driving motor arranged on the supporting plate, a first supporting shaft rotatably penetrating through the lower parts of the supporting columns on the front side of the supporting plate and in transmission connection with the output shaft of the second driving motor, a second driving transmission wheel in transmission connection with the first supporting shaft and positioned on the lower parts of the supporting columns on the front side of the supporting plate, a second driven transmission wheel arranged on the upper parts of the supporting columns on the front side of the supporting plate and positioned on one side of each first driving belt pulley, and a transmission belt wound on the second driving transmission wheel and the second driven transmission wheel, wherein the second driven transmission wheel and the first driving belt pulley are respectively in transmission connection with the second supporting shaft rotatably arranged on the upper parts of the supporting columns on the front side of the supporting plate.

After the technical scheme is adopted, the utility model has the following beneficial effects:

1. the rotating piece of the first driving device is matched with the groove of the second frame to drive through the first roller, the second frame is driven to slide up and down, the bearing capacity of the switching mechanism is enhanced due to the fact that the contact surface between the components is large, and the structure can realize stable support under the action of dynamic load along with conveying of glass from the longitudinal conveying device to the second conveying device.

2. Because the size of the glass conveying device is larger, the size of the supporting plate of the second frame is larger, and each parallel connecting rod can cooperate with the rotating piece to realize the horizontal support of the second frame, so that the conveying surface of the second conveying device on the second frame is always in a horizontal state, accidents caused by inclination of the conveying surface in the transferring process of the glass are prevented, and the parallel connecting rods can assist the rotating piece to provide support for the second frame when in a vertical state.

3. The arrangement of the support column ensures that the transfer mechanism does not influence the transverse conveying device to continuously convey glass when the glass is conveyed from the longitudinal conveying device, thereby being beneficial to improving the overall conveying efficiency of the glass conveying device.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are needed in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings can be obtained from these drawings without inventive faculty for a person skilled in the art.

Fig. 1 is a top view of the present utility model.

Fig. 2 is a left side view of the transfer mechanism of the present utility model in an initial position (without the rotating member and the stop).

Fig. 3 is a left side view of the transfer mechanism of the present utility model in an actuated state.

Fig. 4 is a top view of the structure of the second frame of the present utility model.

Fig. 5 is a schematic structural view of the first driving device of the present utility model.

Fig. 6 is a partial cross-sectional view of a second housing of the present utility model.

Description of the embodiments

The utility model will now be further described with reference to the drawings and specific examples. The following examples are only for more clearly illustrating the technical aspects of the present utility model, and are not intended to limit the scope of the present utility model.

Referring to fig. 1 to 6, the technical scheme adopted in this embodiment is as follows:

the utility model provides a vertically and horizontally staggered glass conveyor who carries, includes frame 1, be provided with on frame 1 and be used for carrying glass's horizontal conveyor 2 and vertical conveyor 3, be located on frame 1 horizontal conveyor 2's the delivery path is still provided with and is used for accepting and come from vertical conveyor 3 carries glass's switching mechanism 4, switching mechanism 4 include can the gliding setting in second frame 41 on frame 1, set up in second frame 41 be used for accepting from vertical conveyor 3 carries glass's second conveyor 42 and set up in frame 1 be used for driving second frame 41 slides from top to bottom first drive arrangement 43, vertical conveyor 3's glass conveying face position is higher than horizontal conveyor 2's glass conveying face position, as shown in fig. 2.

As shown in fig. 3, the first driving device 43 includes a first driving motor 431 disposed on the frame 1, a reducer 432 in transmission connection with an output shaft of the first driving motor 431, and a rotating member 433 in transmission connection with an output shaft of the reducer 432, where the other end of the rotating member 433 is movably connected with the second frame 41 through a first roller 5 rotatably disposed at an end of the rotating member 433.

The first driving device 43 further comprises a limiting device 434 commonly arranged at one end of the rotating member 433 and on the frame 1, the limiting device 434 comprises a first connecting rod 4341 hinged with one end of the rotating member 433, a second connecting rod 4342 hinged with the first connecting rod 4341 and the other end hinged with the frame 1, a third connecting rod 4343 hinged with one end of the rotating member 433 and positioned at one side of the first connecting rod 4341, a fourth connecting rod 4344 hinged with the third connecting rod 4343 and the other end hinged with the frame 1, and two limiting rods 4345 arranged on the frame 1 and positioned at two sides of the second connecting rod 4342, the first driving motor 431 adopts a control motor with a brake device, the rotating member 433 is an L-shaped connecting rod, the rotating member 433 and the output shaft of the speed reducer 432 are in transmission connection through a connecting key, the turning part of the rotating member 433 is provided with a through groove which is cooperatively connected with the output shaft of the speed reducer 432 and the connecting key, the first driving motor 431 can drive the rotating member 433 to rotate forward or reversely through the speed reducer 432, the control angle can enable the second conveying device 42 on the second rack 41 to be capable of receiving the position of conveying glass from the longitudinal conveying device 3 when ascending to a proper position, the conveying glass can be placed on the transverse conveying device 2 when descending to a proper position, the two limiting rods 4345 indirectly limit the rotation of the rotating member 433 by limiting the rotation of the second connecting rod 4342, and the first driving motor 431 and the limiting device 434 cooperatively cooperate to jointly ensure the rotating member 433 to rotate forward or reversely in a designed movable range, so that the switching work of the switching mechanism 4 is ensured to be smoothly carried out.

As shown in fig. 4, the second frame 41 includes a supporting plate 411 slidably disposed on the frame 1, three beams 412 fixed at the lower end of the supporting plate 411 and disposed at intervals in the left-right direction, and six struts 413 fixed at the upper end of the supporting plate 411 and disposed at intervals in the left-right and front-rear directions, the beams 412 are movably connected with the first driving device 43 in the middle position, each strut 413 is connected with the second conveying device 42, the supporting plate 411 of the second frame 41 is also larger in size due to the larger size of the conveying glass, in order to stably support the supporting plate 411, a parallel connecting rod 7 is disposed at the front and rear of each beam 412, one end of each parallel connecting rod 7 is movably connected with the cross beam 412 at a corresponding position through a second roller 8 rotatably arranged at one end of each parallel connecting rod 7, the other end of each parallel connecting rod 7 is hinged with the frame 1, each parallel connecting rod 7 is parallel to one side supporting rod 4331 of the rotating member 433, when each parallel connecting rod 7 is in a vertical state, the rotating member 432 can assist in providing a horizontal stable support for the supporting plate 411 during glass transition, and when the rotating member 433 is in a rotating state, each parallel connecting rod 7 can also cooperate with the rotating member 433 to keep the supporting plate 411 in a horizontal state, so that the conveying surface of the second conveying device 42 on the second frame 41 is always in a horizontal state, and accidents caused by inclination of the conveying surface during glass transition are prevented.

Each of the cross beams 412 is further provided with a plurality of grooves 10, wherein the front and rear parts of the two cross beams 412 positioned at the left and right ends are respectively provided with one groove 10, the middle position of the cross beam 412 is provided with three grooves 10 at intervals along the front and rear direction, the upper and lower ends of the middle position groove 10 on the cross beam 412 are matched and connected with the first roller 5, the upper and lower ends of the rest grooves 10 are respectively matched and connected with the second roller 8 except the upper and lower ends of the middle position groove 10 on the middle position of the cross beam 412, the length of each groove 10 is larger than the diameter of the first roller 5 and the diameter of the second roller 8, when the rotating piece 432 and each parallel connecting rod 7 rotate anticlockwise, each cross beam 412 and each supporting plate 411 can be lifted, and as the cross beam 412 and the supporting plate 411 cannot slide along the front and rear direction in the ascending process, at this time, each groove 10 provides a movable space for the first roller 5 and the second roller 8 to deflect laterally along the front and rear direction due to rotation, so that the rotating piece 432 and each connecting rod 7 can continue to rotate in parallel as shown in fig. 4.

The front end and the rear end of the two cross beams 412 at the left end and the right end are respectively provided with a guiding device 9 for guiding the supporting plate 411 to slide up and down, the guiding device 9 comprises a third roller 91 rotatably arranged at the end of the corresponding cross beam 412 and a guide rail 92 fixedly arranged on the frame 1 and connected with the third roller 91 in a matched manner, the third roller 91 adopts a V-shaped roller, the guide rail 92 adopts a V-shaped guide rail, and the guiding device 9 can prevent the cross beam 412 and the supporting plate 411 from sliding in the front-rear direction laterally and can reduce the friction force between the corresponding cross beam 412 and the supporting plate 411 and the frame 1 in the up-down sliding process.

The second conveying device 42 includes three conveying lines 421 disposed at the upper ends of the corresponding pillars 413 in the front-rear direction, and a second driving device 422 disposed at the upper ends of the supporting plates 411 for driving each of the conveying lines 421 to operate synchronously, where two pillars 413 corresponding in the front-rear direction among the six pillars 413 form a group, three groups of pillars are provided in total, and one conveying line 421 for conveying the pillars 413 in the front-rear direction is disposed at the upper ends of each group of pillars 413, as shown in fig. 4.

As shown in fig. 4 and 5, each of the conveying lines 421 includes a first driving pulley 4211 rotatably provided at an upper end of each of the support posts 413 on a front side of the support plate 411, a first driven pulley 4212 rotatably provided at an upper end of each of the corresponding support posts 413 on a rear side of the support plate 411, and a first conveying belt 4213 wound around each of the first driving pulley 4211 and the first driven pulley 4212.

As shown in fig. 6, the second driving device 422 includes a second driving motor 4221 disposed on the supporting plate 411, a first supporting shaft 4222 rotatably penetrating through the lower portion of each supporting post 413 on the front side of the supporting plate 411 and in driving connection with the output shaft of the second driving motor 4221, a second driving wheel 4223 in driving connection with the first supporting shaft 4222 and respectively located at the lower portion of each supporting post 413 on the front side of the supporting plate 411, a second driven wheel 4224 disposed on the upper portion of each supporting post 413 on the front side of the supporting plate 411 and located at the corresponding position on one side of each first driving wheel 4211, and a driving belt 4225 wound around each second driving wheel 4223 and each second driven wheel 4224 at the corresponding position, wherein each second driven wheel 4224 is in driving connection with each first driving wheel 4211 at the corresponding position and each second supporting shaft 4226 rotatably disposed on the upper portion of each supporting post 413 on the front side of the supporting plate 411.

The transverse conveying device 2 includes a plurality of third support shafts 21 rotatably disposed on the frame 1 and disposed at intervals along a left-right direction, and a third driving device (not labeled) disposed on the frame 1 and configured to drive each third support shaft 21 to rotate synchronously, each third support shaft 21 is sleeved with a plurality of elastic rings 22 at intervals along a front-rear direction, a clearance space between two adjacent elastic rings 22 corresponding to the left-right direction allows each strut 413 at a corresponding position to extend when rising, and the number of the third support shafts 21 can be set according to actual conveying conditions. When the switching mechanism 4 is in the initial position non-working state, the top position of the elastic ring 22 of the transverse conveying device 2 is higher than the upper end surface of the first conveying belt 4213 so as not to influence the transverse conveying device 2 to convey glass in a normal state.

The longitudinal conveying device 3 includes a plurality of fourth supporting shafts 31 rotatable and arranged on the frame 1 at intervals along the front-rear direction, and a fourth driving device (not labeled) arranged on the frame 1 and used for driving each fourth supporting shaft 31 to rotate, each fourth supporting shaft 31 is also sleeved with a plurality of elastic rings 22 at intervals along the left-right direction, and the number of the fourth supporting shafts 31 can be set according to actual conveying conditions.

The third driving device (not shown) and the fourth driving device (not shown) respectively drive each third supporting shaft 21 to synchronously rotate and each fourth supporting shaft 31 to synchronously rotate by adopting a common driving motor and a double-row sprocket chain staggered engagement transmission mode, and the description is omitted here.

Basic principle:

1. working principle of the switching mechanism: as shown in fig. 3 and fig. 4, when the first driving motor 431 drives the rotating member 433 to rotate counterclockwise through the output shaft of the speed reducer 432, the one-side supporting rod 4331 of the rotating member 433 will drive the first roller 5 to rotate counterclockwise, because the first roller 5 is cooperatively connected with the upper and lower ends of the middle groove 10 of the middle position cross beam 412, the counterclockwise rotation of the first roller 5 will drive the middle position cross beam 412 to slide upward, and because the guiding device 9 makes the middle position cross beam 412 unable to slide laterally in the front-rear direction relative to the frame 1, so that the first roller 5 will move along the length direction of the middle groove 10 of the middle position cross beam 412, the rising of the middle position cross beam 412 will simultaneously drive the supporting plate 411 and the second conveying device 42 thereon, and at this time, the two cross beams 412 at the left and right ends will also rise, and finally will simultaneously drive each parallel link 7 to rotate counterclockwise around the hinge point with the frame 1, and when the rotating member 433 rotates counterclockwise to the position, the parallel links 7 are in a vertical state and the second conveying device 433 can provide stable conveyance for the glass 41. When the rotating member 433 rotates clockwise to a proper position, the conveying glass on the second conveying device 42 can be accurately placed on the transverse conveying device 2, and the first driving motor 431 and the limiting device 434 are coordinated to cooperate to ensure that the rotating member 433 rotates within a designed control angle range.

2. Glass conveying principle: as shown in fig. 1 and 2, when the switching mechanism 4 is in the non-actuated initial position, the upper end face of the first conveyor belt 4213 is lower than the top position of the elastic ring 22 of the lateral conveyor 2 so as not to affect the conveyance of glass by the lateral conveyor 2 in a normal state, when the conveyance glass from the longitudinal conveyor 3 reaches the designated position and when the area covered by the switching mechanism 4 is not detected with the conveyance glass from the lateral conveyor 2, the rotation of each third support shaft 21 is stopped briefly, after the first drive motor 431 of the switching mechanism 4 is actuated so that each pillar 413 is extended in place, each third support shaft 21 continues to rotate for conveying glass from the lateral conveyor 2, while the second conveyor 42 on the longitudinal conveyor 3 and the switching mechanism 4 begin to cooperate to switch the conveyance glass from the longitudinal conveyor 3 onto the second conveyor 42, when the switching is in place and the area covered by the switching mechanism 4 is not detected with the conveyance glass from the lateral conveyor 2, the entire conveyance process is stopped again by the third support shaft 21 being stopped sequentially, and the overall rotation of the lateral conveyor is continued until the overall conveyance efficiency is again increased.

While the basic principles and main features of the present utility model and advantages thereof have been shown and described, it will be understood by those skilled in the art that the present utility model is not limited by the foregoing embodiments, which are described merely by way of illustration of the principles of the present utility model, and various changes and modifications may be made therein without departing from the spirit and scope of the utility model as defined in the appended claims and their equivalents.

Claims (10)

1. The utility model provides a vertically and horizontally staggered glass conveyor who carries, includes the frame, be provided with in the frame and be used for carrying glass's horizontal conveyor and vertical conveyor, be located in the frame horizontal conveyor's the delivery path is last still to be provided with and be used for accepting and come from vertical conveyor carries glass's switching mechanism, its characterized in that: the switching mechanism comprises a second rack which is arranged on the rack in a vertical sliding way, a second conveying device which is arranged on the second rack and used for carrying glass conveyed by the longitudinal conveying device, and a first driving device which is arranged on the rack and used for driving the second rack to slide up and down.

2. The crisscross conveyor glass conveying device of claim 1, wherein: the first driving device comprises a first driving motor arranged on the frame, a speed reducer in transmission connection with an output shaft of the first driving motor, and a rotating piece in transmission connection with an output shaft of the speed reducer, wherein the other end of the rotating piece is movably connected with the second frame.

3. The crisscross conveyor glass conveying device of claim 2, wherein: the first driving device further comprises a limiting device which is arranged on one end of the rotating piece and on the frame, wherein the limiting device comprises a first connecting rod movably connected with one end of the rotating piece, a second connecting rod movably connected with the first connecting rod and the other end of the first connecting rod and the frame, a third connecting rod movably connected with one end of the rotating piece and positioned on one side of the first connecting rod, a fourth connecting rod movably connected with the third connecting rod and the other end of the third connecting rod and movably connected with the frame, and two limiting rods which are arranged on the frame and positioned on two sides of the second connecting rod.

4. A crisscross conveyor glass delivery apparatus according to claim 3, wherein: the second frame includes the slidable from top to bottom set up in backup pad in the frame, set firmly in backup pad lower extreme along a plurality of crossbeams that left and right sides set up and set firmly in backup pad upper end along a plurality of pillars that left and right sides and front and back direction set up respectively at intervals, at least one of crossbeam with first drive arrangement swing joint, each pillar with second conveyor is connected.

5. The crisscross conveyor glass conveying device of claim 4, wherein: and a plurality of parallel connecting rods are further arranged on each cross beam, one end of each parallel connecting rod is movably connected with the cross beam through a second roller wheel rotatably arranged at one end of each parallel connecting rod, and the other end of each parallel connecting rod is movably connected with the frame.

6. The crisscross conveyor glass conveying device of claim 5, wherein: and a plurality of grooves are also formed in each cross beam, the upper end and the lower end of at least one groove in each groove are connected with the first roller in a matched manner, the upper end and the lower end of the other grooves are connected with the second roller in a matched manner, and the length of each groove is larger than the diameter of the first roller and the diameter of the second roller.

7. The crisscross conveyor glass conveying device of claim 6, wherein: the front end and the rear end of the two cross beams at the left end and the right end are respectively provided with a guide device for guiding the support plate to slide up and down, and the guide device comprises a third roller which is rotatably arranged at the end part of the corresponding cross beam and a guide rail which is fixedly arranged on the frame and is in matched connection with the third roller.

8. The crisscross conveyor glass conveying device of claim 4, wherein: the second conveying device comprises a plurality of conveying lines arranged at the upper ends of the corresponding support columns in the front-rear direction and a second driving device arranged at the upper ends of the support plates and used for driving the conveying lines to synchronously work.

9. The crisscross conveyor glass conveying device of claim 8, wherein: each conveying line comprises a first driving belt pulley rotatably arranged at the upper end of each support column at the front side of the supporting plate, a first driven belt pulley rotatably arranged at the upper end of each support column at the rear side of the supporting plate, and a first conveying belt wound on each first driving belt pulley and each first driven belt pulley.

10. The crisscross conveyor glass conveying device of claim 9, wherein: the second driving device comprises a second driving motor arranged on the supporting plate, a first supporting shaft rotatably penetrating through the lower parts of the supporting columns on the front side of the supporting plate and in transmission connection with the output shaft of the second driving motor, a second driving transmission wheel in transmission connection with the first supporting shaft and positioned on the lower parts of the supporting columns on the front side of the supporting plate, a second driven transmission wheel arranged on the upper parts of the supporting columns on the front side of the supporting plate and positioned on one side of each first driving belt pulley, and a transmission belt wound on the second driving transmission wheel and the second driven transmission wheel, wherein the second driven transmission wheel and the first driving belt pulley are respectively in transmission connection with the second supporting shaft rotatably arranged on the upper parts of the supporting columns on the front side of the supporting plate.