CN115072313B

CN115072313B - Automatic control reciprocating type material conveyer belt

Info

Publication number: CN115072313B
Application number: CN202210685151.XA
Authority: CN
Inventors: 孙佳钧
Original assignee: Baoyang Equipment Technology Huai'an Co ltd
Current assignee: Baoyang Equipment Technology Huai'an Co ltd
Priority date: 2022-06-17
Filing date: 2022-06-17
Publication date: 2024-03-01
Anticipated expiration: 2042-06-17
Also published as: CN115072313A

Abstract

The invention discloses an automatically-controlled reciprocating material conveyer belt, relates to the technical field of material conveyer belts, and aims to solve the problem that the practicability is poor because the conventional conveyer belt component device is limited in that the conveyer belt component device cannot reciprocate. The conveying belt device comprises a lifting supporting structure, a mounting and carrying structure and a conveying belt assembly; the support base member is included in the lifting support structure, and the upper end of the support base member is fixedly connected with the hydraulic lifting structure in an embedding manner; the protective guardrail assembly is fixedly connected with the upper end of the mounting and carrying structure through a flange; the PLC forward and backward rotating motor is fixedly connected with the flange at one side of the mounting structure; the signal receiving structure is fixedly connected with the upper end of the mounting structure through a flange; the laser signal emitter is connected with the mounting and carrying structure through a flange; and the clamping and fixing structure is fixedly connected to the transmission belt of the transmission belt assembly.

Description

Automatic control reciprocating type material conveyer belt

Technical Field

The invention relates to the technical field of material conveying belts, in particular to a material conveying belt capable of automatically controlling reciprocating type.

Background

The conveyer belt, also called conveyer belt, is used in belt conveyer belt for bearing and conveying material, is one kind of composite rubber, fiber and metal product or composite plastic and fabric product, and is widely used in cement, coking, metallurgical, chemical, steel and other fields.

The application number is as follows: 201721621446.1, named: a conveyor belt for transporting materials, the apparatus comprising: the conveyer belt body, transportation layer, go up wearing layer, go up the wire net layer, soften layer, firm layer, tensile layer, lower wire net layer, lower wearing layer, skid resistant course, first last connecting rope, second go up connecting rope, first connecting rope and second down connecting rope, conveyer belt body top is provided with the transportation layer, it is provided with the wire layer to go up the wearing layer below, it is provided with the softening layer to go up the wire net layer below, it is provided with firm layer to soften the layer below, firm layer below is provided with tensile layer, tensile layer below is provided with down the wire net layer, lower wire net layer below is provided with the wearing layer down, lower wearing layer below is provided with the skid resistant course, is provided with the transportation layer, and transportation layer inside is provided with the fold face, can increase the frictional force between material and the conveyer belt of transportation, is provided with the softening layer, can increase the pliability of conveyer belt.

The device is limited in that the device cannot carry out round trip operation in the using process, so that the practicability is poor.

Therefore, we propose an automatically controllable shuttle conveyor belt to solve the above-mentioned problems.

Disclosure of Invention

The invention aims to provide an automatic control reciprocating material conveyer belt, so as to solve the problem that the prior conveyer belt component device proposed in the background art is poor in practicability because the prior conveyer belt component device is limited in that the prior conveyer belt component device cannot reciprocate.

In order to achieve the above purpose, the present invention provides the following technical solutions: an automatically controllable reciprocating material conveyer belt comprises a conveyer belt device, wherein the conveyer belt device comprises a lifting supporting structure, a mounting carrying structure and a conveyer belt assembly, and the mounting carrying structure is provided with two groups;

further comprises:

the support base member is included in the lifting support structure, the two sides of the support base member are fixedly connected with reinforcing leg members, and the upper end of the support base member is embedded and fixedly connected with a hydraulic lifting structure;

the connecting block component is fixedly connected to the lower end of the mounting structure;

the protective guardrail assembly is fixedly connected with the upper end of the mounting and carrying structure through a flange;

the guardrail fixing structure is fixedly connected to one side of the protective guardrail assembly and one side of the mounting and carrying structure;

the PLC forward and backward rotating motors are fixedly connected to one side of the mounting structure through flanges, and the two groups of PLC forward and backward rotating motors on the mounting structure are respectively mounted on one side of each of the two groups of PLC forward and backward rotating motors and are mounted in a staggered manner;

the signal receiving structure is fixedly connected with the upper end of the mounting structure through a flange;

the laser signal emitter is connected with the mounting and carrying structure through a flange;

and the clamping and fixing structure is fixedly connected to the transmission belt of the transmission belt assembly.

Preferably, two groups all be provided with a groove on the installation carrying structure, and a groove and two groups the installation carrying structure is formed through the lathe dashes and mills, be provided with vice transmission band subassembly in the groove of installation carrying structure, and vice transmission band subassembly is embedded with the installation carrying structure to be connected, two groups one side of installation carrying structure all is provided with the motor shaft hole, and the motor shaft hole with two groups one side of installation carrying structure is formed through milling cutter dashes and mills, the transmission band surface of transmission band subassembly is provided with anti-skidding layer structure, and anti-skidding layer structure and the transmission band fixed surface of transmission band subassembly are connected.

Preferably, the protection guardrail assembly comprises a guardrail base member, one side of the guardrail base member is provided with an embedded cutting member, the embedded cutting member is connected with one side of the guardrail base member in a welded mode, the upper end of the guardrail base member is provided with a protection plate member, the protection plate member is fixedly connected with the upper end of the guardrail base member, an L-shaped reinforcing structure is arranged at the joint of the guardrail base member and the protection plate member, the L-shaped reinforcing structure is fixedly connected with the guardrail base member and the protection plate member through fixing bolts, a reinforcing rod member is arranged between the guardrail base member and the protection plate member, and the reinforcing rod member is connected with the upper end of the guardrail base member and one side of the protection plate member in a flange mode.

Preferably, the guard plate member is provided with a viewing window member, and the viewing window member is connected with the guard plate member in a mosaic manner.

Preferably, the motor housing is included on the PLC forward and backward rotation motor, one end of the motor housing is provided with a mounting structure, and the mounting structure is connected with one end of the motor housing in a nested manner.

Preferably, the upper end of motor housing is provided with PLC control structure, and PLC control structure and motor housing's upper end fixed connection, motor housing's both sides all are provided with the heat dissipation component, and the both sides fixed connection of heat dissipation component and motor housing, be provided with the heat dissipation conducting strip component in the heat dissipation component, and the heat dissipation conducting strip component is embedded to be connected with the heat dissipation component.

Preferably, the upper end of guardrail fixed knot constructs is provided with the fastening knob component, and the fastening knob component inlays with guardrail fixed knot constructs's upper end and insert and be connected, one side of guardrail fixed knot constructs is provided with inlays the jack, and inlays the jack and forms through milling cutter punching and milling with guardrail fixed knot constructs one side, the below of inlaying the jack is provided with the installation key hole, and the installation key hole forms through milling cutter punching and milling with guardrail fixed knot constructs one side.

Preferably, the signal receiving structure comprises a mounting connection plate member, one side of the mounting connection plate member is provided with an integrated processor, the integrated processor is fixedly connected with one side of the mounting connection plate member, the other side of the mounting connection plate member is provided with a receiving head, and the receiving head is fixedly connected with the other side of the mounting connection plate member.

Preferably, the clamping and fixing structure comprises a frame structure, one side of the frame structure is provided with a micro-cylinder mounting frame, the micro-cylinder mounting frame is fixedly connected with one side of the frame structure, one side of the frame structure is provided with a clamping plate member, and the micro-cylinder mounting frame is provided with a fastening screw.

Preferably, the micro cylinder mounting frame is provided with a micro cylinder component, and the micro cylinder component is connected with the micro cylinder mounting frame in a nested manner.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the invention, through the arrangement of the laser signal emitter, the signal receiving structure and the PLC forward and backward motor, when a conveyor belt device is used, after goods reach a designated position, the auxiliary conveyor belt assembly which operates together with the conveyor belt assembly drives the laser signal emitter on the conveyor belt assembly to move to the designated position, after the laser signal emitter reaches the designated position, the laser signal emitter sends a laser signal to the signal receiving structure on the opposite side, the signal receiving structure processes the signals through the integrated processor of the signal receiving structure after receiving the signals, the processed signals are then sent to the PLC control structure of the PLC forward and backward motor on the opposite side, the PLC control structure executes the signals to command the PLC forward and backward motor to enable the PLC forward and backward motor to operate the conveyor belt assembly to enable the goods needing to be moved back, and the auxiliary conveyor belt assembly on the side drives the laser signal emitter to move to the initial position, and then the emitting head of the laser signal emitter also sends the laser signal to the signal receiving structure on the opposite side to enable the signal receiving structure on the opposite side to control the PLC forward and backward motor on the opposite side, so that the laser signal emitter on the two sides and the signal receiving structure on the opposite side are matched with the signal receiving structure to alternately rotate to realize forward and backward transportation of the conveyor belt.

2. Through the setting of frame construction, microcylinder installation frame, microcylinder component, grip block component, fastening screw, frame construction is the installation frame mechanism of centre gripping fixed knot constructs, microcylinder installation frame is used for the installation of microcylinder component fixedly, fastening screw on the microcylinder installation frame plays the connection between fastening microcylinder installation frame and the frame construction in addition, the frame that frame construction, microcylinder installation frame are constituteed is convenient for protect the installation of its upper part of guardrail subassembly, and install the microcylinder component on microcylinder installation frame and provide the drive power and cooperate grip block component and can fix the goods, do benefit to the transportation of goods on the conveyer belt device.

3. Through guardrail base component, inlay cutting component, guard plate member, L type reinforced structure, reinforcing rod component, observation window component's setting, guardrail base component is the installation base mechanism of protection guardrail subassembly, can install protection guardrail subassembly on the transmission band device, inlay the supplementary guardrail base component installation of cutting component, and the guard plate member of installing on it plays certain guard action, the state of goods when the observation window component on it can observe the transportation, L type reinforced structure, reinforcing rod component all are used for strengthening the intensity of use of protection guardrail subassembly in addition, the protection guardrail subassembly that forms through the above introduction part has protected operating personnel's operation safety to a certain extent.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of the mounting structure and the conveyor belt assembly of the present invention;

FIG. 3 is a schematic view of a guard rail assembly according to the present invention;

FIG. 4 is a schematic diagram of the structure of the PLC reversible motor according to the present invention;

FIG. 5 is a schematic view of a guardrail fixing structure of the present invention;

fig. 6 is a schematic diagram of a signal receiving structure according to the present invention;

FIG. 7 is a schematic view of a clamping and fixing structure according to the present invention;

in the figure: 1. a conveyor belt device; 2. a lifting support structure; 3. mounting a carrying structure; 4. a conveyor belt assembly; 5. a support base member; 6. reinforcing the leg members; 7. a hydraulic lifting structure; 8. a connecting block member; 9. a protective barrier assembly; 10. a guardrail fixing structure; 11. a PLC forward and reverse rotation motor; 12. a signal receiving structure; 13. a laser signal emitter; 14. clamping and fixing structure; 15. a first groove; 16. a secondary conveyor belt assembly; 17. a motor shaft hole; 18. an anti-slip layer structure; 19. a guardrail base member; 20. a slip member; 21. a shield member; 22. an L-shaped reinforcing structure; 23. a reinforcing rod member; 24. a viewing window member; 25. a motor housing; 26. a mounting structure; 27. a PLC control structure; 28. a heat radiation member; 29. a heat radiation conductive sheet member; 30. fastening a knob member; 31. an insertion hole; 32. installing a bolt hole; 33. installing a connecting plate member; 34. an integrated processor; 35. a receiving head; 36. a frame structure; 37. a micro cylinder mounting frame; 38. a microcylinder member; 39. a clamping plate member; 40. and (5) fastening a screw.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments.

Referring to fig. 1-7, an embodiment of the present invention is provided: an automatically controllable reciprocating material conveyer belt comprises a conveyer belt device 1, wherein the conveyer belt device 1 comprises a lifting supporting structure 2, a mounting and carrying structure 3 and a conveyer belt assembly 4, and the mounting and carrying structure 3 is provided with two groups;

further comprises:

the support base member 5 is included in the lifting support structure 2, the two sides of the support base member 5 are fixedly connected with reinforcing leg members 6, and the upper end of the support base member 5 is inserted and fixedly connected with a hydraulic lifting structure 7;

a connection block member 8 fixedly connected to the lower end of the mounting structure 3;

the protective guardrail assembly 9 is fixedly connected to the upper end of the mounting structure 3 through a flange;

the guardrail fixing structure 10 is fixedly connected to one side of the protective guardrail assembly 9 and the mounting and carrying structure 3;

the PLC forward and backward rotating motors 11 are fixedly connected to one side of the mounting structure 3 through flanges, and the PLC forward and backward rotating motors 11 on the two groups of mounting structures 3 are respectively arranged on one side of each of the two groups of mounting structures and are arranged in a staggered manner;

the signal receiving structure 12 is fixedly connected with the upper end of the mounting and carrying structure 3 through a flange;

a laser signal emitter 13 flange-connected to the mounting structure 3;

the clamping and fixing structure 14 is fixedly connected to the conveyor belt of the conveyor belt assembly 4.

Referring to fig. 2, a first groove 15 is formed in each of the two sets of mounting structures 3, the first groove 15 and the two sets of mounting structures 3 are formed by milling by a lathe, a secondary transmission belt assembly 16 is arranged in the first groove 15 of each of the mounting structures 3, the secondary transmission belt assembly 16 is connected with the mounting structures 3 in an embedded manner, motor shaft holes 17 are formed in one sides of the two sets of mounting structures 3, the motor shaft holes 17 and one sides of the two sets of mounting structures 3 are formed by milling by a milling cutter, an anti-slip layer structure 18 is arranged on the surface of a transmission belt of each of the transmission belt assemblies 4, the anti-slip layer structure 18 is fixedly connected with the surface of the transmission belt of each of the transmission belt assemblies 4, the first groove 15 is used for mounting other components, the secondary transmission belt assembly 16 is used for mounting upper components of the secondary transmission belt assembly, the motor shaft holes 17 are used for mounting connection of motors, and the anti-slip layer structure 18 prevents cargoes from slipping.

Referring to fig. 3, the guard rail assembly 9 includes a guard rail base member 19, an insert member 20 is disposed on one side of the guard rail base member 19, the insert member 20 is welded to one side of the guard rail base member 19, a guard plate member 21 is disposed at an upper end of the guard rail base member 19, the guard plate member 21 is fixedly connected to an upper end of the guard rail base member 19, an L-shaped reinforcing structure 22 is disposed at a connection portion between the guard rail base member 19 and the guard plate member 21, the L-shaped reinforcing structure 22 is fixedly connected to the guard rail base member 19 and the guard plate member 21 through a fixing bolt, a reinforcing rod member 23 is disposed between the guard rail base member 19 and the guard plate member 21, the reinforcing rod member 23 is in flange connection with an upper end of the guard rail base member 19 and one side of the guard plate member 21, the guard rail base member 19 is a base mechanism, the insert member 20 is convenient for mounting and fixing the guard rail assembly 9, the guard plate member 21 plays a role in protecting, the L-shaped reinforcing structure 22 plays a role in reinforcing and connecting, and the reinforcing rod member 23 plays a role in reinforcing and supporting.

Referring to fig. 3, the guard plate member 21 is provided with an observation window member 24, and the observation window member 24 is connected with the guard plate member 21 in a inlaid manner, and the observation window member 24 is convenient for observing the cargo transportation state.

Referring to fig. 4, the PLC reversible motor 11 includes a motor housing 25, one end of the motor housing 25 is provided with a mounting structure 26, and the mounting structure 26 is connected with one end of the motor housing 25 in a nested manner, the motor housing 25 is a motor housing mechanism, and the mounting structure 26 is beneficial to the mounting connection of the PLC reversible motor 11.

Referring to fig. 4, a PLC control structure 27 is disposed at an upper end of the motor housing 25, the PLC control structure 27 is fixedly connected with an upper end of the motor housing 25, heat dissipation members 28 are disposed on two sides of the motor housing 25, the heat dissipation members 28 are fixedly connected with two sides of the motor housing 25, heat dissipation conductive sheet members 29 are disposed in the heat dissipation members 28, the heat dissipation conductive sheet members 29 are connected with the heat dissipation members 28 in an embedded manner, the PLC control structure 27 is used for controlling the PLC reversible motor 11, and the heat dissipation members 28 and the heat dissipation conductive sheet members 29 are combined for heat dissipation of the PLC reversible motor 11.

Referring to fig. 5, a fastening knob member 30 is disposed at an upper end of the guardrail fixing structure 10, the fastening knob member 30 is inserted and connected with an upper end of the guardrail fixing structure 10, an insertion hole 31 is disposed at one side of the guardrail fixing structure 10, the insertion hole 31 is formed by milling with one side of the guardrail fixing structure 10 through a milling cutter, a mounting bolt hole 32 is disposed below the insertion hole 31, the mounting bolt hole 32 is formed by milling with one side of the guardrail fixing structure 10 through a milling cutter, the fastening knob member 30 plays a fastening role, the insertion hole 31 is used for inserting the insertion strip member 20 of the guardrail assembly 9, and the mounting bolt hole 32 is beneficial to mounting connection of the guardrail fixing structure 10.

Referring to fig. 6, the signal receiving structure 12 includes a mounting connection board member 33, one side of the mounting connection board member 33 is provided with an integrated processor 34, the integrated processor 34 is fixedly connected with one side of the mounting connection board member 33, the other side of the mounting connection board member 33 is provided with a receiving head 35, the receiving head 35 is fixedly connected with the other side of the mounting connection board member 33, the mounting connection board member 33 facilitates the mounting connection of other components, and the integrated processor 34 is used for processing the received signal, and the receiving head 35 receives the signal.

Referring to fig. 7, the clamping and fixing structure 14 includes a frame structure 36, a micro-cylinder mounting frame 37 is disposed on one side of the frame structure 36, the micro-cylinder mounting frame 37 is fixedly connected with one side of the frame structure 36, a clamping plate member 39 is disposed on one side of the frame structure 36, a fastening screw 40 is disposed on the micro-cylinder mounting frame 37, the frame structure 36 is a mounting frame mechanism, the micro-cylinder mounting frame 37 is convenient for mounting and fixing the micro-cylinder member 38, the clamping plate member 39 is matched with the micro-cylinder member 38 for fixing goods, and the fastening screw 40 fastens the frame structure 36.

Referring to fig. 7, a micro cylinder member 38 is provided on the micro cylinder mounting frame 37, and the micro cylinder member 38 is nested with the micro cylinder mounting frame 37, and the micro cylinder member 38 provides driving force.

Working principle: when in use, firstly, goods are clamped and fixed by the clamping and fixing structure 14 on the conveyor belt device 1, then, the switch of the PLC positive and negative rotating motor 11 on one side of the conveyor belt device 1 is opened to start the operation, then, the PLC positive and negative rotating motor 11 drives the conveyor belt of the conveyor belt assembly 4 on the conveyor belt device 1 to operate, the conveyor belt drives the goods on the conveyor belt to move to a designated position, the auxiliary conveyor belt assembly 16 which operates together with the conveyor belt assembly 4 when the goods arrive at the designated position drives the laser signal transmitter 13 on the conveyor belt assembly to move to the designated position, the laser signal transmitter 13 emits a laser signal to the signal receiving structure 12 on the opposite side after arriving at the designated position, the signal receiving structure 12 processes the signal by the integrated processor 34 of the signal receiving structure 12 after receiving the signal, the processed signals are sent to the PLC control structure 27 of the PLC forward and backward motor 11 at the side, the PLC control structure 27 executes signal commands to control the PLC forward and backward motor 11, the PLC forward and backward motor 11 operates the conveyor belt assembly 4 to enable the conveyor belt to transport goods to be transported back, the auxiliary conveyor belt assembly 16 at the side drives the laser signal transmitter 13 on the auxiliary conveyor belt assembly to move to the initial position, then the transmitting head of the laser signal transmitter 13 also sends laser signals to the signal receiving structure 12 at the opposite side of the auxiliary conveyor belt assembly, the transmitting head sends signals to control the PLC forward and backward motor 11 at the side to operate, and accordingly the laser signal transmitters 13 and the signal receiving structure 12 at the two sides are matched with the PLC forward and backward motor 11 at the respective side to be used alternately, and reciprocating transportation of the conveyor belt is achieved.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims

1. An automatically controllable reciprocating material conveyer belt comprises a conveyer belt device (1), wherein the conveyer belt device (1) comprises a lifting supporting structure (2), a mounting and carrying structure (3) and a conveyer belt assembly (4), and the mounting and carrying structure (3) is provided with two groups;

the method is characterized in that: further comprises:

the support base member (5) is arranged in the lifting support structure (2), the two sides of the support base member (5) are fixedly connected with reinforcing leg members (6), and the upper end of the support base member (5) is fixedly connected with a hydraulic lifting structure (7) in an embedding and inserting manner;

a connection block member (8) fixedly connected to the lower end of the mounting structure (3);

the protective guardrail assembly (9) is fixedly connected with the upper end of the mounting and carrying structure (3) through a flange;

the guardrail fixing structure (10) is fixedly connected to one side of the protective guardrail assembly (9) and one side of the mounting and carrying structure (3);

the PLC forward and backward rotating motors (11) are fixedly connected to one side of the mounting and carrying structure (3) through flanges, and the PLC forward and backward rotating motors (11) on the two groups of mounting and carrying structures (3) are respectively arranged on one side of each of the two groups of mounting and carrying structures and are arranged in a staggered manner;

the signal receiving structure (12) is fixedly connected with the upper end of the mounting and carrying structure (3) through a flange;

a laser signal emitter (13) which is flange-connected to the mounting structure (3);

a clamping and fixing structure (14) fixedly connected to the conveyor belt of the conveyor belt assembly (4);

the two groups of installation carrying structures (3) are provided with first grooves (15), the first grooves (15) and the two groups of installation carrying structures (3) are formed by punching and milling through a lathe, the first grooves (15) of the installation carrying structures (3) are internally provided with auxiliary transmission belt assemblies (16), and the auxiliary transmission belt assemblies (16) are connected with the installation carrying structures (3) in an embedded mode;

the PLC positive and negative rotation motor (11) drives a transmission belt of the transmission belt assembly (4) on the transmission belt device (1) to operate, the transmission belt drives goods on the transmission belt to move to a specified position, and the auxiliary transmission belt assembly (16) which runs together with the transmission belt assembly (4) drives a laser signal transmitter (13) on the transmission belt assembly to move to the specified position when the goods reach the specified position.

2. An automatically controllable shuttle as in claim 1 wherein: two sets of one side of installation carrying structure (3) all is provided with motor shaft hole (17), and motor shaft hole (17) and two sets of one side of installation carrying structure (3) are through milling cutter punching and milling, the transmission band surface of transmission band subassembly (4) is provided with anti-skidding layer structure (18), and anti-skidding layer structure (18) and transmission band surface fixed connection of transmission band subassembly (4).

3. An automatically controllable shuttle as in claim 1 wherein: include guardrail base member (19) on guardrail subassembly (9), one side of guardrail base member (19) is provided with inlays cutting member (20), and inlays one side welded connection of cutting member (20) and guardrail base member (19), the upper end of guardrail base member (19) is provided with guard plate member (21), and guard plate member (21) and the upper end fixed connection of guardrail base member (19), guardrail base member (19) and guard plate member (21) junction is provided with L type reinforced structure (22), and L type reinforced structure (22) and guardrail base member (19) and guard plate member (21) pass through dead bolt fixed connection, be provided with stiffening rod member (23) between guardrail base member (19) and guard plate member (21), and stiffening rod member (23) are with the upper end of guardrail base member (19) and one side flange joint of guard plate member (21).

4. An automatically controlled shuttle as in claim 3 wherein: an observation window component (24) is arranged on the protection plate component (21), and the observation window component (24) is connected with the protection plate component (21) in an inlaid mode.

5. An automatically controllable shuttle as in claim 1 wherein: the PLC forward and reverse rotation motor (11) comprises a motor housing (25), one end of the motor housing (25) is provided with a mounting structure (26), and the mounting structure (26) is connected with one end of the motor housing (25) in a nested mode.

6. An automatically controllable shuttle as in claim 5 wherein: the upper end of motor housing (25) is provided with PLC control structure (27), and PLC control structure (27) and motor housing's (25) upper end fixed connection, motor housing's (25) both sides all are provided with heat dissipation component (28), and heat dissipation component (28) and motor housing's (25) both sides fixed connection, be provided with heat dissipation conducting strip component (29) in heat dissipation component (28), and heat dissipation conducting strip component (29) are embedded to be connected with heat dissipation component (28).

7. An automatically controllable shuttle as in claim 1 wherein: the upper end of guardrail fixed knot constructs (10) is provided with fastening knob component (30), and fastening knob component (30) inlays with the upper end of guardrail fixed knot construct (10) and insert and be connected, one side of guardrail fixed knot constructs (10) is provided with inlays jack (31), and inlays jack (31) and one side of guardrail fixed knot construct (10) and dash and mill through milling cutter and form, the below of inlaying jack (31) is provided with installation keyhole (32), and one side of installation keyhole (32) and guardrail fixed knot constructs (10) is through milling cutter and dash and mill and form.

8. An automatically controllable shuttle as in claim 1 wherein: the signal receiving structure (12) comprises a mounting connection plate member (33), one side of the mounting connection plate member (33) is provided with an integrated processor (34), the integrated processor (34) is fixedly connected with one side of the mounting connection plate member (33), the other side of the mounting connection plate member (33) is provided with a receiving head (35), and the receiving head (35) is fixedly connected with the other side of the mounting connection plate member (33).

9. An automatically controllable shuttle as in claim 1 wherein: the clamping and fixing structure is characterized in that the clamping and fixing structure (14) comprises a frame structure (36), a micro cylinder mounting frame (37) is arranged on one side of the frame structure (36), the micro cylinder mounting frame (37) is fixedly connected with one side of the frame structure (36), a clamping plate member (39) is arranged beside the frame structure (36), and a fastening screw (40) is arranged on the micro cylinder mounting frame (37).

10. An automatically controllable shuttle as in claim 9 wherein: the micro cylinder mounting frame (37) is provided with a micro cylinder component (38), and the micro cylinder component (38) is connected with the micro cylinder mounting frame (37) in a nested manner.