CN112537596A - Quick shunting machine - Google Patents

Abstract

The invention discloses a quick shunting machine which comprises a conveying mechanism, a shunting mechanism and a jacking mechanism, wherein the shunting mechanism is arranged in the middle of the conveying mechanism and comprises a shunting machine body frame and a riding wheel mechanism, the shunting machine body frame is provided with a starting end and an output end, one end of the riding wheel mechanism is hinged to the output end of the shunting machine body frame, the other end of the riding wheel mechanism is erected at the starting end of the shunting machine body frame, and the jacking mechanism is arranged at the lower part of the shunting mechanism and close to the starting end of the shunting machine body frame. According to the rapid shunting machine, the original mode of integrally lifting the shunting mechanism is changed into the mode of only lifting the shunting starting end, the lifting capacity is improved by about one time by utilizing the lever principle, and meanwhile, the shunting output end is not lifted, so that materials can be smoothly output, the stability of a transmission system is improved, the collision damage of the materials is reduced, the material qualification rate is improved, and the equipment cost is saved.

Description

Quick shunting machine

Technical Field

The invention belongs to the technical field of material conveying equipment, and particularly relates to a quick flow divider.

Background

At present, the material conveying is widely applied to the fields of production, processing, storage and the like, and the material is often required to be shunted in the conveying process, so that the corresponding purpose is realized.

The shunt mechanism that prior art generally increased can whole lifting is reformed transform on original conveyer and is realized shunting, because to relevant operational environment's requirement, like in the tire workshop, should not adopt hydraulic pressure, because oil can influence the tire quality, can only adopt the cylinder as jacking part, and the service pressure of cylinder generally is in 0.2-1.0Mpa scope, when lifting heavy materials such as large-scale tire, the specification that the cylinder can whole lifting is limited, and because of there being the difference in height behind the whole lifting, the material is difficult for following the smooth output of shunt mechanism.

Disclosure of Invention

Aiming at the technical problems, the invention provides a quick diverter which is used for solving the problems that the integral lifting capacity of a cylinder is limited and materials are not easy to smoothly output during diversion conveying.

A quick shunting machine comprises a conveying mechanism used for conveying materials along a first direction, a shunting mechanism used for conveying the materials along a second direction and a jacking mechanism. The conveying mechanism comprises a transverse machine body frame, a plurality of conveying rollers and a conveying driving assembly, the extension direction of a rotating shaft of each conveying roller is parallel to the second direction, and the conveying driving assembly for providing power for the plurality of conveying rollers is arranged on the transverse machine body frame. The shunting mechanism comprises a shunting body frame, a riding wheel mechanism and a shunting driving assembly, the shunting body frame is arranged below the transverse body frame, the shunting body frame is provided with a shunting starting end and a shunting output end in the second direction, the shunting starting end is positioned in the transverse body frame, the shunting output end is positioned outside the transverse body frame, the shunting driving assembly for providing shunting power for the riding wheel mechanism is arranged on the shunting body frame, the shunting driving assembly comprises a shunting transmission shaft, the axial direction of the shunting transmission shaft is parallel to the first direction, the shunting transmission shaft is rotatably erected at the shunting output end, the riding wheel mechanism is arranged on the shunting body frame, one end of the riding wheel mechanism in the second direction is hinged on the shunting transmission shaft, the other end of the riding wheel mechanism is erected at the shunting starting end, and the highest point of the riding wheel mechanism is lower than the highest point of the conveying roller when shunting conveying is. The jacking mechanism is arranged below the riding wheel mechanism and close to the shunting starting end, the jacking mechanism comprises a cylinder and a jacking plate, the cylinder is fixed on the shunting machine body frame, the lower surface of the jacking plate is vertically connected with a jacking rod of the cylinder, and the upper surface of the jacking plate is connected with the lower surface of the riding wheel mechanism.

Preferably, the shunt drive assembly further comprises a shunt motor, a shunt motor sprocket, a shunt drive chain and a shunt transmission belt, the shunt motor is mounted at the lower part of the shunt output end, the shunt motor is connected with the shunt transmission shaft through the shunt motor sprocket and the shunt drive chain to transmit power, and the shunt transmission shaft is connected with the riding wheel structure through the shunt transmission belt to transmit power.

Preferably, the riding wheel mechanism comprises a first riding wheel mounting plate, a plurality of second riding wheel mounting plates, a third riding wheel mounting plate, a linkage rod, a plurality of head wheels, a plurality of tail wheels and a plurality of small riding wheels, the head wheels and the tail wheels are same in number and size and are in one-to-one correspondence, the first riding wheel mounting plate, the plurality of second riding wheel mounting plates and the third riding wheel mounting plate are sequentially arranged along a first direction and are respectively arranged between two adjacent conveying rollers in one-to-one correspondence, the plurality of second riding wheel mounting plates are positioned between the first riding wheel mounting plate and the third riding wheel mounting plate, the first riding wheel mounting plate, the second riding wheel mounting plates and the third riding wheel mounting plate extend along a second direction and pass through gap holes formed in the transverse machine body frame without interference, one end of the linkage rod is fixed on the first riding wheel mounting plate, the other end of the linkage rod is fixed on the third riding wheel mounting plate, the middle part of the linkage rod is sequentially and fixedly connected with the plurality of second riding wheel mounting plates, the first riding wheel mounting plate and the third riding wheel mounting plate are respectively and rotatably connected to the shunt transmission shaft, a tail wheel and a plurality of small riding wheels are respectively fixed on the first riding wheel mounting plate, the plurality of second riding wheel mounting plates and the third riding wheel mounting plate, a head wheel corresponding to each tail wheel is sleeved on the shunt transmission shaft, and the highest point of each head wheel, each tail wheel and each small riding wheel is consistent in height.

Preferably, the shunting transmission belt is a triangular belt, the head wheel is a triangular head wheel, the tail wheel is a triangular tail wheel, and the small riding wheel is a triangular small riding wheel.

Preferably, the transverse frame comprises a first frame and a second frame arranged in parallel, and the plurality of conveying roller frames are arranged between the first frame and the second frame.

Preferably, the conveying driving assembly comprises a transverse conveying motor, a transverse motor chain wheel, a transverse transmission chain, a head shaft, a tail shaft, a transverse conveying belt and a plurality of transverse supporting wheels, the head shaft and the tail shaft which are parallel to the conveying roller are erected between the first frame and the second frame, the head shaft and the tail shaft are respectively located at two ends of the transverse machine body frame in the first direction, the transverse conveying motor is fixed at one end of the first frame, the transverse conveying motor is connected with the head shaft through the transverse motor chain wheel and the transverse transmission chain to transmit power, the first frame is provided with the plurality of transverse supporting wheels, the transverse conveying belt is erected on the plurality of transverse supporting wheels, and the head shaft and the tail shaft are connected with the plurality of conveying roller through the transverse conveying belt to transmit power.

Preferably, the transverse conveying belt adopts a sheet base belt, and the transverse supporting wheel adopts a sheet base belt supporting wheel.

Preferably, the jacking plate is detachably connected to the jacking rod of the cylinder and the lower surface of the riding wheel mechanism.

Preferably, the shunting mechanism is detachably fixed below the conveying mechanism, and the jacking mechanism is detachably fixed below the shunting mechanism.

Preferably, the bottom of the rapid flow divider is provided with a height-adjustable foot cup.

Compared with the prior art, the rapid shunting machine provided by the invention has the advantages that the original mode of integrally lifting the shunting mechanism is changed into the mode of only lifting the shunting starting end, the nearly doubled lifting capacity is improved by utilizing the lever principle, and meanwhile, the shunting output end is not lifted, so that materials can be smoothly output, the stability of a transmission system is improved, the collision damage of the materials is reduced, the material qualification rate is improved, and the equipment cost is saved.

Drawings

Fig. 1 is a schematic structural diagram of a rapid flow divider according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of a fast splitter according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a fast splitter according to another view of the present invention;

fig. 4 is a schematic structural diagram of a fast splitter according to another view of the embodiment of the present invention.

Detailed Description

In order to further understand the objects, structures, features and functions of the present invention, the following embodiments are described in detail.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1, 2, 3 and 4, a fast diverter 100 according to an embodiment of the present invention includes a conveying mechanism 1 for conveying materials along a first direction X10, a diverting mechanism 2 for conveying materials along a second direction Y20, and a jacking mechanism 3.

The conveying mechanism 1 includes a transverse body frame 11, a plurality of conveying rollers 12, and a conveying drive assembly 13, a rotating shaft extending direction of each conveying roller 12 is parallel to the second direction, and the conveying drive assembly 13 for powering the plurality of conveying rollers 12 is provided on the transverse body frame 11.

The shunt mechanism 2 is arranged in the middle of the transverse conveying mechanism 1, the shunt mechanism 2 comprises a shunt body frame 21, a riding wheel mechanism 22 and a shunt driving assembly 23, the shunt body frame 21 is arranged below the transverse body frame 11, the shunt body frame 21 is provided with a shunt starting end 211 and a shunt output end 212 in a second direction Y20, the shunt starting end 211 is positioned in the transverse body frame 11, the shunt output end 212 is positioned outside the transverse body frame 11, so as to facilitate lifting of the shunt starting end 211, the shunt driving assembly 23 for providing shunt power for the riding wheel mechanism 22 is arranged on the shunt body frame 21, the shunt driving assembly 23 comprises a shunt transmission shaft 231, the axial direction of the shunt transmission shaft 231 is parallel to a first direction X10, the shunt transmission shaft 231 is rotatably erected at the shunt output end 212, the riding wheel mechanism 22 is arranged on the shunt body frame 21, one end of the riding wheel mechanism 22 in a second direction Y20 is hinged on the shunt transmission shaft 231, the other end is erected at a diversion starting end 211, and the highest point of the riding wheel mechanism 22 is lower than the highest point of the conveying roller 12 when diversion conveying is not carried out.

The jacking mechanism 3 is arranged below the riding wheel mechanism 22, the jacking mechanism 3 is close to the shunting starting end 211, the jacking mechanism 3 comprises a cylinder 31 and a jacking plate 32, the cylinder 31 is fixed on the shunting body frame 21, the lower surface of the jacking plate 32 is vertically connected with a jacking rod of the cylinder 31, and the upper surface of the jacking plate 32 is connected with the lower surface of the riding wheel mechanism 22.

Preferably, the shunt driving assembly 23 further includes a shunt motor 232, a shunt motor sprocket 233, a shunt transmission chain (not shown), and a shunt transmission belt (not shown), the shunt motor 232 is installed at a lower portion of the shunt output end 212, the shunt motor 232 is connected to the shunt transmission shaft 231 through the shunt motor sprocket 233 and the shunt transmission chain to transmit power, the shunt transmission shaft 231 is connected to the riding wheel structure 22 through the shunt transmission belt (not shown) to transmit power, the structural mode is reasonable in layout, and power transmission is stable.

Preferably, the riding wheel mechanism 22 includes a first riding wheel mounting plate 221, a plurality of second riding wheel mounting plates 222, a third riding wheel mounting plate 223, a linkage rod 224, a plurality of head wheels 225, a plurality of tail wheels 226 and a plurality of small riding wheels 227, the plurality of head wheels 225 and the plurality of tail wheels 226 are the same in number and size and are in one-to-one correspondence, the first riding wheel mounting plate 221, the plurality of second riding wheel mounting plates 222 and the third riding wheel mounting plate 223 are sequentially arranged along a first direction X10 and are respectively arranged between two adjacent conveying rollers 12 in one-to-one correspondence, the plurality of second riding wheel mounting plates 222 are located between the first riding wheel mounting plate 221 and the third riding wheel mounting plate 223, the first riding wheel mounting plate 221, the second riding wheel mounting plate 222 and the third riding wheel mounting plate 223 all extend along a second direction Y20 and all pass through the holes formed in the transverse body frame 11 without interference, one end of the linkage rod 224 is fixed to the first riding wheel mounting plate 221, the other end of the linkage rod 224 is fixed on a third supporting roller mounting plate 223, the middle part of the linkage rod 224 is fixedly connected with a plurality of second supporting roller mounting plates 222 in sequence, the first supporting roller mounting plate 221 and the third supporting roller mounting plate 223 are respectively and rotatably connected on the flow dividing transmission shaft 231, the first supporting roller mounting plate 221, the second supporting roller mounting plates 222 and the third supporting roller mounting plate 223 are respectively and fixedly provided with a tail wheel 226 and a plurality of small supporting rollers 227, a head wheel 225 corresponding to each tail wheel 226 is sleeved on the flow dividing transmission shaft 231, the highest point of each head wheel 225, each tail wheel 226 and each small supporting roller 227 are consistent in height, the supporting roller structure 22 is compact in layout and ingenious in arrangement, and flow dividing transportation can be well achieved.

Preferably, the shunting transmission belt (not shown) is a triangular belt, the head wheel 225 is a triangular head wheel, the tail wheel 226 is a triangular tail wheel, the small riding wheel 227 is a triangular small riding wheel, the triangular belt is adopted for shunting transmission, the cost is low, the noise is low, the transmission is stable, and the buffering and vibration absorption can be realized.

Preferably, the transverse frame 11 comprises a first frame 111 and a second frame 112 which are arranged in parallel, and the plurality of conveying rollers 12 are erected between the first frame 111 and the second frame 112, so that the structure is reasonable, and stable conveying is facilitated.

Preferably, the conveying driving assembly 13 includes a transverse conveying motor 131, a transverse motor sprocket 132, a transverse transmission chain (not shown), a head shaft 133, a tail shaft 134, a transverse transmission belt 135 and a plurality of transverse supporting rollers 136, the head shaft 133 and the tail shaft 134 are disposed between the first frame 111 and the second frame 112 and parallel to the conveying roller 12, the head shaft 133 and the tail shaft 134 are respectively disposed at two ends of the transverse body frame 11 in the first direction X10, the transverse conveying motor 131 is fixed at one end of the first frame 111, the transverse conveying motor 131 is connected with the head shaft 133 through the transverse motor sprocket 132 and the transverse transmission chain to transmit power, the first frame 111 is provided with a plurality of transverse supporting rollers 136, the transverse transmission belt 135 is disposed on the plurality of transverse supporting rollers 136, and the head shaft 133 and the tail shaft 134 are connected with the plurality of conveying rollers 12 through the transverse transmission belt 135 to transmit power, which is compact in structure, reasonable in layout, The transmission is reliable and stable.

Preferably, the transverse conveying belt 135 adopts a sheet base belt, and the transverse riding wheel 136 adopts a sheet base belt riding wheel, so that the transverse conveying is more stable and reliable because the sheet base belt has the characteristics of light weight, high strength, small use elongation, good oil resistance and wear resistance, soft belt body, energy conservation and the like.

Preferably, the lifting plate 32 is detachably connected to the lower surface of the ejector rod of the cylinder 31 and the riding wheel mechanism 22, and the detachable combination is convenient for maintenance and replacement.

Preferably, reposition of redundant personnel mechanism 2 detachably fixes in conveying mechanism 1 below, and climbing mechanism 3 detachably fixes in reposition of redundant personnel mechanism 2 below, and the detachable combination is convenient for maintain and change.

Preferably, the bottom of the rapid diverter 100 is provided with a height-adjustable foot cup 4, which is convenient for docking with other transportation mechanisms.

The fast diverter 100 of an embodiment has the following work flows:

the material that the thread was carried, if need not to shunt and carry, then directly down carry through carrying cylinder 12, when the material will shunt and carry, cylinder 31 makes the material be located riding wheel mechanism 22's surface through the one end of jacking board 32 jack-up riding wheel mechanism 22 to being higher than carrying cylinder 12, and riding wheel mechanism 22 rotates under shunting drive assembly 23 drives simultaneously, and the material can shunt and carry.

According to the rapid shunting machine, the original mode of integrally lifting the shunting mechanism is changed into the mode of only lifting the shunting starting end, the lifting capacity is improved by about one time by utilizing the lever principle, and meanwhile, the shunting output end is not lifted, so that materials can be smoothly output, the stability of a transmission system is improved, the collision damage of the materials is reduced, the material qualification rate is improved, and the equipment cost is saved.

The present invention has been described in relation to the above embodiments, which are only exemplary of the implementation of the present invention. It should be noted that the disclosed embodiments do not limit the scope of the invention. Rather, it is intended that all such modifications and variations be included within the spirit and scope of this invention.

Claims (10)

1. A quick diverter is characterized by comprising a conveying mechanism for conveying materials along a first direction, a diverting mechanism for conveying materials along a second direction and a jacking mechanism;

the conveying mechanism comprises a transverse machine body frame, a plurality of conveying rollers and a conveying driving assembly, wherein the extension direction of a rotating shaft of each conveying roller is parallel to the second direction, and the conveying driving assembly for providing power for the plurality of conveying rollers is arranged on the transverse machine body frame;

the shunting mechanism comprises a shunting machine body frame, a riding wheel mechanism and a shunting driving component, the shunting machine body frame is arranged below the transverse machine body frame, the shunting body frame is provided with a shunting starting end and a shunting output end in the second direction, the shunting starting end is positioned in the transverse body frame, the shunt output end is positioned outside the transverse machine body frame, the shunt driving component for providing shunt power for the riding wheel mechanism is arranged on the shunt machine body frame, the shunt driving assembly comprises a shunt transmission shaft, the axial direction of the shunt transmission shaft is parallel to the first direction, and the shunt transmission shaft is rotatably erected at the shunt output end, the riding wheel mechanism is arranged on the frame of the shunting machine body, one end of the riding wheel mechanism in the second direction is hinged on the shunting transmission shaft, the other end is erected at the shunting starting end, the highest point of the riding wheel mechanism is lower than that of the conveying roller when shunt conveying is not carried out;

this climbing mechanism sets up in this riding wheel mechanism below, and this climbing mechanism is close to this reposition of redundant personnel initiating terminal, and this climbing mechanism includes cylinder and jacking board, and this cylinder is fixed on this reposition of redundant personnel fuselage frame, and the lower surface of this jacking board is connected with the ejector pin of this cylinder is perpendicular, and the upper surface of this jacking board is connected with the lower surface of this riding wheel mechanism.

2. The rapid diverter according to claim 1, wherein the diverter drive assembly further comprises a diverter motor mounted to a lower portion of the diverter output, a diverter motor sprocket, a diverter drive chain, and a diverter belt, the diverter motor being coupled to the diverter drive shaft via the diverter motor sprocket and the diverter drive chain for power transfer, the diverter drive shaft being coupled to the riding wheel structure via the diverter belt for power transfer.

3. The fast splitter as claimed in claim 2, wherein the riding wheel mechanism comprises a first riding wheel mounting plate, a plurality of second riding wheel mounting plates, a third riding wheel mounting plate, a linkage rod, a plurality of head wheels, a plurality of tail wheels and a plurality of small riding wheels, the plurality of head wheels and the plurality of tail wheels are same in number and size and are in one-to-one correspondence, the first riding wheel mounting plate, the plurality of second riding wheel mounting plates and the third riding wheel mounting plate are sequentially arranged along a first direction and are respectively arranged between two adjacent conveying rollers in one-to-one correspondence, the plurality of second riding wheel mounting plates are located between the first riding wheel mounting plate and the third riding wheel mounting plate, the first riding wheel mounting plate, each second riding wheel mounting plate and the third riding wheel mounting plate extend along the second direction and pass through a gap hole formed in the transverse frame without interference, one end of the linkage rod is fixed on the first riding wheel mounting plate, the other end of the linkage rod is fixed on the third supporting wheel mounting plate, the middle part of the linkage rod is fixedly connected with each second supporting wheel mounting plate in sequence, the first supporting wheel mounting plate and the third supporting wheel mounting plate are respectively and rotatably connected on the shunt transmission shaft, the first supporting wheel mounting plate, each second supporting wheel mounting plate and the third supporting wheel mounting plate are respectively and fixedly provided with one tail wheel and a plurality of small supporting wheels, the head wheel corresponding to each tail wheel is sleeved on the shunt transmission shaft, and the highest point of each head wheel, each tail wheel and each small supporting wheel is consistent in height.

4. A rapid diverter according to claim 3, wherein the diverter belt is a v-belt, each head roller is a v-head roller, each tail roller is a v-tail roller, and each small idler is a v-small idler.

5. The rapid diverter according to claim 1, wherein the transverse body frame comprises a first frame and a second frame arranged in parallel, the plurality of transport rollers being disposed between the first frame and the second frame.

6. The rapid flow divider of claim 5, wherein the conveying driving assembly comprises a traverse motor, a traverse motor sprocket, a traverse transmission chain, a head shaft, a tail shaft, a traverse transmission belt, and a plurality of traverse supporting rollers, the head shaft and the tail shaft are disposed between the first frame and the second frame and parallel to the conveying roller, the head shaft and the tail shaft are disposed at two ends of the traverse body frame in the first direction, respectively, the traverse motor is fixed at one end of the first frame, the traverse motor is connected to the head shaft through the traverse motor sprocket and the traverse transmission chain to transmit power, the plurality of traverse supporting rollers are disposed on the first frame, the traverse transmission belt is disposed on the plurality of traverse supporting rollers, and the head shaft and the tail shaft are connected to the plurality of conveying rollers through the traverse transmission belt to transmit power.

7. A rapid diverter according to claim 6, wherein the cross conveyor employs a web of material and the cross idler employs a web of material idler.

8. A rapid diverter according to claim 1, wherein the jacking plate is removably attached to the ejector rod of the cylinder and to the lower surface of the riding wheel mechanism.

9. The rapid diverter according to claim 1, wherein the diverter mechanism is removably secured below the conveyor mechanism and the lift mechanism is removably secured below the diverter mechanism.

10. A rapid diverter according to claim 1, wherein the bottom of the rapid diverter is provided with a height adjustable foot cup.

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