CN117154477B - Energy-saving power distribution interface system for stacker - Google Patents

Abstract

The invention relates to the technical field of power distribution systems, in particular to an energy-saving power distribution interface system for a stacker. The energy-saving power distribution interface system for the stacker comprises a track installation device, a machine body device, a cargo carrying platform installation device, a drag chain device and an electric device, wherein a power distribution interface is arranged in the electric device and comprises a power distribution shell, a shell upper cover, a circuit component, a socket component, a pull ring component and a locking component. According to the invention, the socket component and the locking component in the power distribution interface are used for further clamping and locking the wire plug after being inserted, so that the socket component and the wire plug are prevented from loosening and shifting caused by subsequent vibration, and the pull ring component is matched with the locking component, so that the wire plug inserted into one end of the hollow cavity can be abutted, clamped or coated and fixed when the pull ring component is subjected to vibration, the wire plug is prevented from being separated from the power distribution shell caused by vibration, and the stability and the reliability of connection are further ensured.

Description

Energy-saving power distribution interface system for stacker

Technical Field

The invention relates to the field of power distribution systems, in particular to an energy-saving power distribution interface system for a stacker.

Background

The stacker is also called a stacker crane, and is a special crane which adopts a fork or a string rod as an object taking device, and performs grabbing, carrying and stacking at a warehouse, a workshop and the like or takes and places unit cargos from a high-rise goods shelf. The stacker has the main function of running back and forth in the channel of the stereoscopic warehouse, and storing the goods at the roadway crossing into the goods grid of the goods shelf or taking out the goods in the goods grid and conveying the goods to the roadway crossing.

At present, as the stacker needs to grab, carry and stack frequently, the stacker is subjected to vibration and pulling with large impact force frequently, so that the connecting plug at the power distribution interface is frequently separated by the vibration force or the pulling force, the carrying operation is suspended, the production efficiency is seriously reduced, and meanwhile, the power consumption is also caused in the shutdown and restarting processes, and the energy expenditure and the operation cost are increased.

Disclosure of Invention

Based on this, there is a need to provide an energy-saving power distribution interface system for a stacker to solve at least one technical problem in the background art.

The utility model provides an energy-conserving electric power distribution interface system for stacker, including track installation device, organism device, cargo bed installation device, drag chain device, electric installation, track installation device includes ground rail assembly and sky rail assembly, ground rail assembly fixed mounting is on the installation bottom surface, sky rail assembly fixed mounting is on the storehouse roof, and ground rail assembly length direction is parallel with sky rail assembly length direction, organism device bottom slidingly installs in ground rail assembly, organism device roof slidingly installs in the sky rail assembly, organism device bottom one side is protruding to be equipped with travel switch, cargo bed installation device installs in organism device bottom opposite side, drag chain device one end is installed in cargo bed installation device, drag chain device other end is installed in organism device roof, electric installation is installed in organism device bottom proximity travel switch one side, be provided with the distribution interface in the electric installation, distribution interface and travel switch electric connection.

As a further improvement of the invention, the power distribution interface comprises a power distribution shell, a shell upper cover, a circuit component, a socket component, a pull ring component and a locking component, wherein a hollow cavity is formed in the power distribution shell, one end of the hollow cavity is penetrated and concavely provided with a power inserting groove, the other end of the hollow cavity is concavely provided with a power feeding groove, the top surface of the hollow cavity is penetrated and concavely provided with an upper cover groove adjacent to one end of the power feeding groove, two ends of the side wall of the power distribution shell adjacent to one side wall of the power inserting groove are respectively convexly provided with a mounting boss, the side walls of the two mounting bosses are respectively convexly provided with a first rotating column, the shell upper cover is fixedly arranged in the upper cover groove, the circuit component is fixedly arranged at one end of the hollow cavity adjacent to the power feeding groove, the socket component is arranged at the other end of the hollow cavity, the socket component is electrically connected with the circuit component, the bottom of the pull ring component is rotatably arranged in the two first rotating columns, and the locking component is arranged in the socket component.

As a further improvement of the invention, the middle parts of the two sides of the hollow cavity are respectively provided with a fastening groove in a penetrating way, the two fastening grooves are communicated with the upper cover groove, the middle part of the bottom surface of the hollow cavity is provided with a first sliding groove in a penetrating way, the middle part of the bottom surface of the hollow cavity is also provided with two second sliding grooves in a penetrating way, the two second sliding grooves are respectively positioned on the two sides of the first sliding groove, and a plurality of limit posts are respectively arranged at equal intervals on the middle part of the bottom surface of the hollow cavity and one end adjacent to the power feeding groove.

As a further improvement of the invention, a third sliding groove is arranged in the center of the bottom of the side wall of the distribution shell adjacent to the plug-in groove, a first limit groove is arranged in the bottom of the third sliding groove, a fourth sliding groove is arranged in the center of the bottom of the distribution shell, the fourth sliding groove is opposite to the first sliding groove, two second sliding grooves are respectively positioned on two sides of the fourth sliding groove, the fourth sliding groove is communicated with the first limit groove, and two buckles are respectively arranged at two ends of the top of the side wall of the distribution shell adjacent to the plug-in groove in a protruding mode.

As a further improvement of the invention, two sides of the bottom surface of the upper cover of the shell, which are adjacent to one end of the electric inserting groove, are respectively provided with an inserting block in a protruding way, the two inserting blocks are inserted and installed in the two fastening grooves, two sides of the other end of the bottom surface of the upper cover of the shell are respectively provided with a clamping column in a protruding way, and the middle part of the bottom surface of the upper cover of the shell is provided with a fastening block in a protruding way.

As a further improvement of the invention, the circuit component comprises a circuit board, a connecting silica gel block and a clamping block, wherein the circuit board is clamped and installed between a plurality of limit posts and two inserting blocks, the bottom surface of the connecting silica gel block is fixedly installed on one end of the top surface of the circuit board adjacent to the power feeding groove, the top surface of the connecting silica gel block is propped against the bottom surface of the fastening block, the bottom surface of the clamping block is fixedly installed on the other end of the top surface of the circuit board, and first elastic sheet clamping grooves are respectively concavely arranged on two sides of the top surface of the clamping block.

As a further improvement of the invention, the socket assembly comprises an electric socket, a connecting frame and a clamping plate, wherein the connecting frame is fixedly arranged at the top part of one end of the electric socket adjacent to the power inlet groove, the clamping plate is fixedly arranged at the bottom part of the other end of the electric socket, the bottom surface of the connecting frame is propped against one end of the top surface of the circuit board adjacent to the power inlet groove, the bottom surface of the clamping plate is propped against the bottom part of the hollow cavity, the middle part of the top surface of the electric socket is concavely provided with a mounting groove, the bottom surface of the mounting groove is concavely provided with a fifth sliding groove, the bottom surface is concavely provided with a sixth sliding groove, the top part of one end of the electric socket adjacent to the clamping plate is concavely provided with a propping groove, the middle part of the side wall of the inner side of the propping groove is concavely provided with a connecting hole, the connecting hole is communicated with the mounting groove, the middle parts of the side walls of two sides of the connecting frame are concavely provided with second elastic sheet clamping grooves, and the two second elastic sheet clamping grooves are respectively oppositely arranged with the bottoms of the two fastening grooves.

As a further improvement of the invention, the pull ring component comprises a pull ring, a locking piece and a sliding locking plate, wherein the middle part of the side wall of one side of the pull ring is penetrated and provided with a through groove, the top surface of the through groove is penetrated and concavely provided with a clamping groove, two buckles are respectively clamped at two ends of the clamping groove, the corner of the outer side wall of the through groove is concavely provided with a first inclined surface, two sides of the bottom surface of the pull ring are respectively convexly provided with rotating rings, the two rotating rings are rotatably mounted at one ends of two first rotating columns, a clamping spring is further arranged between the two rotating rings and the two first rotating columns, the middle part of the bottom surface of the pull ring is convexly provided with a clamping arc-shaped block, the side wall of the clamping arc-shaped block is concavely provided with a clamping groove, the outer side of the bottom surface of the clamping groove is concavely provided with a second inclined surface, the locking piece is slidingly mounted in a third sliding groove, the other end of the locking piece is convexly provided with an inclined block at one end, the inclined block is concavely provided with a second limiting groove at one end of the other end, the inner side wall of the first connecting block is convexly provided with a clamping block, the two corner of the top of the side wall of the clamping block is convexly provided with an arc-shaped block, and the corner of the inner side wall is concavely provided with an arc-shaped surface at the inner side, and the corner of the inner side of the bottom, and the side of the sliding locking piece is adjacent to the clamping block is fixedly connected with the first connecting block.

As a further improvement of the invention, the locking component comprises a locking spring plate, a triggering element and a locking element, wherein the locking spring plate comprises a locking transverse plate, two locking vertical plates, two lateral arc-shaped spring plates and two lateral arc-shaped spring plates, the top surface of the locking transverse plate is fixedly arranged in the middle of the bottom surface of the upper cover of the shell, the top surfaces of the two locking vertical plates are respectively fixedly arranged at two ends of the bottom surface of the locking transverse plate, one ends of the two lateral arc-shaped spring plates are respectively fixedly arranged at the bottoms of one side wall of the two locking vertical plates adjacent to the inserting slot, the inner sides of the arc-shaped side of the two lateral arc-shaped spring plates are respectively provided with a first triangular block in a protruding manner, one ends of the two lateral arc-shaped spring plates are respectively fixedly arranged at two ends of one side of the locking transverse plate adjacent to the inserting slot, the two lateral arc-shaped spring plates are respectively provided with a second triangular block in a protruding manner, and the two second triangular blocks are respectively clamped in the two first spring plate clamping slots, and the triggering element and the locking element are respectively slidably arranged in the electric socket.

As a further improvement of the invention, the trigger element comprises a trigger plate, a trigger rod, a trigger sliding block and an extrusion block, wherein the middle part of the side wall at the inner side of the trigger plate is fixedly connected with one end of the trigger rod, the other end of the trigger rod is penetrated through and connected with the middle part of the side wall at one side of the trigger sliding block through a connecting hole, a third inclined surface is concavely arranged at the corner part of the side wall at the other side of the trigger sliding block, the extrusion block is slidably arranged at the top of the mounting groove, a fourth inclined surface is concavely arranged at the bottom of the extrusion block adjacent to the corner part at one side of the trigger sliding block, the fourth inclined surface is propped against the third inclined surface, the locking element comprises a first sliding block, two sliding connecting columns, a connecting transverse plate, two connecting vertical plates, two connecting springs and two second connecting blocks, the first sliding block is slidably arranged in a sixth sliding groove, the second sliding block is convexly arranged at one side of the bottom surface of the first sliding block adjacent to the plug-in groove, the second sliding block is slidingly arranged in the first sliding groove, the middle part of the top surface of the first sliding block is convexly provided with a connecting column, the top surface of the connecting column is fixedly connected with the bottom surface of the triggering sliding block, the top surfaces of the two sliding connecting columns are respectively fixedly arranged at two ends of the other side of the bottom surface of the first sliding block, a connecting transverse plate is respectively fixedly connected with the bottoms of the side walls of the inner sides of the two sliding connecting columns, one ends of two connecting vertical plates are respectively fixedly arranged at two ends of the side walls of the connecting transverse plate adjacent to one side of the inserting groove, one ends of two connecting springs are respectively fixedly arranged at the inner side walls of the two connecting vertical plates, the other ends of the two connecting springs are respectively fixedly arranged at the outer side walls of the two second connecting blocks, fifth inclined surfaces are concavely arranged at one ends of the inner side walls of the two second connecting blocks adjacent to the inserting groove, the two fifth inclined surfaces are respectively slidingly arranged at two sides of the triangular blocks, a rubber block is also arranged between the connecting transverse plate and the two second connecting blocks, the middle part of the side wall of the rubber block is concavely provided with a triangular groove.

The beneficial effects of the invention are as follows:

1. the socket assembly and the locking assembly in the power distribution interface are used for further clamping and locking the wire plug on the connecting wire after the wire plug is inserted into the power distribution shell, so that the socket assembly and the wire plug are prevented from loosening and shifting due to subsequent vibration, and the wire plug inserted into one end of the hollow cavity can be clamped or coated and fixed when the pull ring assembly is subjected to vibration caused by carrying and other reasons due to the cooperation of the pull ring assembly and the locking assembly, so that the wire plug is prevented from being separated from the power distribution shell due to vibration, the stability of the wire plug insertion is further ensured, and the stability and the reliability of connection are ensured.

2. When the power distribution interface is acted by a pulling force, the locking assembly is utilized to adaptively buffer the stress of the socket assembly, a similar triangle-shaped stable structure is formed in the hollow cavity to further clamp and stably provide a longitudinal supporting force and a transverse stable force for the socket assembly and the circuit assembly, the wire plug and the socket assembly are ensured not to be separated by the pulling force, and the fixing and the stability of the wire plug and the socket assembly are ensured.

3. When the power distribution interface receives extrusion force and acts on, make the link keep away from the fastening piece that insert electric tank one end wall will support in the shell upper cover, prevent that it from further removing and lead to circuit board pressurized to destroy, utilize locking component and pull ring subassembly cooperation simultaneously, make the trigger plate apply the thrust of opposite direction effect to the electric wire plug top, prevent that the too big electric socket that leads to of extrusion force from removing, lead to circuit board pressurized to destroy, guarantee stability and the security of connection.

Drawings

Fig. 1 is a schematic perspective view of an embodiment of the present invention.

Fig. 2 is a schematic perspective view of another embodiment of the present invention.

Fig. 3 is a schematic perspective view of a power distribution interface according to an embodiment of the invention.

Fig. 4 is an exploded view of a power distribution interface in accordance with an embodiment of the present invention.

Fig. 5 is a schematic perspective view of a power distribution housing according to an embodiment of the present invention.

Fig. 6 is a schematic perspective view of a power distribution housing in accordance with another embodiment of the present invention.

Fig. 7 is a cross-sectional view of a power distribution interface in an embodiment of the invention.

Fig. 8 is an enlarged view at a in fig. 7.

Fig. 9 is a schematic perspective view of a locking element according to an embodiment of the invention.

Fig. 10 is a schematic perspective view of a locking element and a locking element according to an embodiment of the invention.

In the figure: 10. a track mounting device; 11. a body device; 12. cargo bed mounting means; 13. a drag chain device; 14. an electrical device; 15. a ground rail assembly; 16. a head rail assembly; 17. a travel switch; 18. a power distribution interface; 20. a power distribution housing; 201. a mounting boss; 202. a first rotating column; 203. a third sliding groove; 205. a first limit groove; 206. a fourth sliding groove; 207. a buckle; 21. a hollow cavity; 211. a power-on slot; 212. a power feeding groove; 213. an upper cover groove; 214. a fastening groove; 215. a first sliding groove; 216. a second sliding groove; 217. a limit column; 30. an upper cover of the housing; 31. inserting a block; 32. a fastening block; 33. clamping the column; 40. a circuit assembly; 41. a circuit board; 42. connecting a silica gel block; 43. a block is clamped; 431. the first elastic sheet is clamped with the groove; 50. a receptacle assembly; 51. an electrical outlet; 511. a mounting groove; 512. a fifth sliding groove; 513. a sixth sliding groove; 514. a holding groove; 515. a connection hole; 52. a connecting frame; 521. the second elastic sheet is clamped with the groove; 53. a clamping plate; 60. a pull ring assembly; 61. a pull ring; 611. a pass through slot; 612. a clamping groove is formed; 614. a rotating ring; 615. clamping the arc-shaped block; 616. a locking groove; 617. a second inclined surface; 62. a locking piece; 621. a tilting block; 622. the second limit groove; 623. a first connection block; 624. a locking block; 625. an arc surface; 63. a slip locking plate; 631. triangular blocks; 70. a locking assembly; 71. a locking spring plate; 711. locking the transverse plate; 712. locking the riser; 713. a lateral arc-shaped elastic sheet; 714. a transverse arc-shaped elastic sheet; 72. a trigger element; 721. a trigger plate; 722. a trigger lever; 723. triggering a sliding block; 724. extruding a block; 725. a third inclined surface; 726. a fourth inclined surface; 73. a locking element; 731. a first slider; 732. a sliding connecting column; 733. a connecting transverse plate; 734. connecting a vertical plate; 735. a connecting spring; 736. a second connection block; 737. a connecting column; 738. a second slider; 739. a fifth inclined surface; 740. a rubber block; 741. triangular grooves.

Detailed Description

In order that the invention may be readily understood, a more complete description of the invention will be rendered by reference to the appended drawings. The drawings illustrate preferred embodiments of the invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

In the description of the present invention, it should be noted that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 to 10, the present invention provides an energy-saving power distribution interface system for a stacker, which includes a track installation device 10, a body device 11, a loading platform installation device 12, a drag chain device 13, and an electrical device 14, wherein the track installation device 10 includes a ground rail assembly 15 and a top rail assembly 16, the ground rail assembly 15 is fixedly installed on a bottom surface, the top rail assembly 16 is fixedly installed on a garage roof, the length direction of the ground rail assembly 15 is parallel to the length direction of the top rail assembly 16, the bottom of the body device 11 is slidably installed in the ground rail assembly 15, the top plate of the body device 11 is slidably installed in the top rail assembly 16, one side of the bottom of the body device 11 is convexly provided with a travel switch 17, the loading platform installation device 12 is installed on the other side of the bottom of the body device 11, one end of the drag chain device 13 is installed in the loading platform installation device 12, the other end of the drag chain device 13 is installed on the top plate of the body device 11, the electrical device 14 is installed on one side of the bottom of the body device 11 adjacent to the travel switch 17, a power distribution interface 18 is provided in the electrical device 14, and the power distribution interface 18 is electrically connected with the travel switch 17.

The power distribution interface 18 comprises a power distribution shell 20, a shell upper cover 30, a circuit component 40, a socket component 50, a pull ring component 60 and a locking component 70, wherein a hollow cavity 21 is formed in the power distribution shell 20, one end of the hollow cavity 21 is penetrated and concavely provided with a power inserting groove 211, the other end of the hollow cavity 21 is concavely provided with a power feeding groove 212, one end, adjacent to the power feeding groove 212, of the top surface of the hollow cavity 21 is penetrated and concavely provided with an upper cover groove 213, two ends, adjacent to the bottom of one side wall of the power inserting groove 211, of the power distribution shell 20 are respectively convexly provided with a mounting boss 201, the side walls of the two mounting bosses 201 are respectively convexly provided with a first rotating column 202, the shell upper cover 30 is fixedly mounted in the upper cover groove 213, the circuit component 40 is fixedly mounted at one end, adjacent to the power feeding groove 212, the socket component 50 is mounted at the other end of the hollow cavity 21, the socket component 50 is electrically connected with the circuit component 40, the bottom of the pull ring component 60 is rotatably mounted in the two first rotating columns 202, and the locking component 70 is mounted in the socket component 50.

The middle parts of the two sides of the hollow cavity 21 are respectively provided with a fastening groove 214 in a penetrating way, the two fastening grooves 214 are respectively communicated with the upper cover groove 213, the middle part of the bottom surface of the hollow cavity 21 is provided with a first sliding groove 215 in a penetrating way, the middle part of the bottom surface of the hollow cavity 21 is also provided with two second sliding grooves 216 in a penetrating way, the two second sliding grooves 216 are respectively positioned on the two sides of the first sliding groove 215, and a plurality of limiting columns 217 are respectively arranged at equal intervals on the middle part of the bottom surface of the hollow cavity 21 and one end adjacent to the power feeding groove 212.

The power distribution shell 20 is adjacent to the bottom of the side wall of the power plug-in slot 211 and is provided with a third sliding slot 203 in a central concave manner, the bottom of the third sliding slot 203 is provided with a first limiting slot 205 in a concave manner, the bottom of the power distribution shell 20 is provided with a fourth sliding slot 206 in a central concave manner, the fourth sliding slot 206 is opposite to the first sliding slot 215, two second sliding slots 216 are respectively positioned on two sides of the fourth sliding slot 206, the fourth sliding slot 206 is communicated with the first limiting slot 205, and two buckles 207 are respectively and convexly arranged at two ends of the top of the side wall of the power distribution shell 20 adjacent to the power plug-in slot 211.

The two sides of the bottom surface of the upper cover 30 adjacent to one end of the power inserting groove 211 are respectively provided with an inserting block 31 in a protruding mode, the two inserting blocks 31 are inserted and installed in the two fastening grooves 214, the two sides of the other end of the bottom surface of the upper cover 30 are respectively provided with a clamping column 33 in a protruding mode, and the middle of the bottom surface of the upper cover 30 is provided with a fastening block 32 in a protruding mode.

The circuit assembly 40 comprises a circuit board 41, a connecting silica gel block 42 and a clamping block 43, wherein the circuit board 41 is clamped and installed between a plurality of limit posts 217 and two inserting blocks 31, the bottom surface of the connecting silica gel block 42 is fixedly installed at one end of the top surface of the circuit board 41 adjacent to the power feeding groove 212, the top surface of the connecting silica gel block 42 is propped against the bottom surface of the fastening block 32, the bottom surface of the clamping block 43 is fixedly installed at the other end of the top surface of the circuit board 41, and first elastic sheet clamping grooves 431 are respectively concavely arranged at two sides of the top surface of the clamping block 43.

The socket assembly 50 comprises an electric socket 51, a connecting frame 52 and a clamping plate 53, wherein the connecting frame 52 is fixedly arranged at the top of one end of the electric socket 51 adjacent to the electric inlet groove 212, the clamping plate 53 is fixedly arranged at the bottom of the other end of the electric socket 51, the bottom surface of the connecting frame 52 is propped against one end of the top surface of the circuit board 41 adjacent to the electric inlet groove 211, the bottom surface of the clamping plate 53 is propped against the bottom of the hollow cavity 21, a mounting groove 511 is concavely formed in the middle of the top surface of the electric socket 51, a fifth sliding groove 512 is concavely formed in the bottom surface of the mounting groove 511, a sixth sliding groove 513 is concavely formed in the bottom surface of the clamping plate 53, a propping groove 514 is concavely formed in the top of one end of the electric socket 51 adjacent to the clamping plate 53, a connecting hole 515 is concavely formed in the middle of the inner side wall of the propping groove 514, the connecting hole 515 is communicated with the mounting groove 511, second spring clamping grooves 521 are concavely formed in the middle of the side walls of the two sides of the connecting frame 52, and the two second spring clamping grooves 521 are respectively oppositely arranged with the bottoms of the two fastening grooves 214.

The pull ring assembly 60 comprises a pull ring 61, a locking piece 62 and a sliding locking plate 63, wherein a through groove 611 is penetrated through the middle part of one side wall of the pull ring 61, a clamping groove 612 is penetrated through the top surface of the through groove 611, two buckles 207 are respectively clamped at two ends of the clamping groove 612, a first inclined surface is concavely arranged at the corner of the outer side wall of the top surface of the through groove 611, two rotating rings 614 are respectively convexly arranged at two sides of the bottom surface of the pull ring 61, the two rotating rings 614 are rotatably arranged at one ends of the two first rotating columns 202, a clamping spring is further arranged between the two rotating rings 614 and the two first rotating columns 202, a clamping arc-shaped block 615 is convexly arranged at the middle part of the bottom surface of the pull ring 61, a clamping groove 616 is concavely arranged at the side wall of the clamping arc-shaped block 615, a second inclined surface 617 is concavely arranged at the outer side of the bottom surface of the clamping groove 616, the locking piece 62 is slidably arranged in the third sliding groove 203, the locking piece 62 is kept away from through groove 611 one end protruding be equipped with tilting block 621, tilting block 621 keeps away from through groove 611 one end concave be equipped with second spacing groove 622, locking piece 62 other end protruding be equipped with first connecting block 623, first connecting block 623 inboard lateral wall protruding be equipped with the clamping piece 624, clamping piece 624 lateral wall top two bight department and bottom inboard bight department all concave be equipped with arcwall face 625, locking piece 62's first connecting block 623 wears to establish and gets into between one of them rotation ring 614 and the clamping arcwall block 615, and the clamping piece 624 card of first connecting block 623 locates in the clamping groove 616, sliding locking plate 63 slidingly installs in fourth sliding groove 206, sliding locking plate 63 bottom surface is adjacent locking piece 62 one end protruding be equipped with triangular block 631, sliding locking plate 63 end wall and second spacing groove 622 inboard lateral wall fixed connection.

The locking assembly 70 comprises a locking spring 71, a triggering element 72 and a locking element 73, wherein the locking spring 71 comprises a locking transverse plate 711, two locking vertical plates 712, two lateral arc spring 713 and two lateral arc spring 714, the top surface of the locking transverse plate 711 is fixedly mounted at the middle of the bottom surface of the upper cover 30 of the shell, the top surfaces of the two locking vertical plates 712 are respectively fixedly mounted at two ends of the bottom surface of the locking transverse plate 711, one ends of the two lateral arc spring 713 are respectively fixedly mounted at the bottoms of the side walls of the two locking vertical plates 712 adjacent to the side wall of the power socket 211, the inner sides of the arc of the two lateral arc spring 713 are respectively provided with a first triangular block in a protruding mode, the two first triangular blocks are respectively clamped in two second spring clamping grooves 521, one ends of the two lateral arc spring 714 are respectively fixedly mounted at two ends of the locking transverse plate 711 adjacent to one side of the power socket 211, the inner sides of the arc 714 are respectively provided with a second triangular block in a protruding mode, the two second triangular blocks are respectively clamped in the two first clamping grooves 431, and the triggering element 72 and the locking element 73 are respectively slidably mounted in the power socket 51.

The trigger element 72 comprises a trigger plate 721, a trigger rod 722, a trigger sliding block 723 and a squeezing block 724, wherein the middle part of the inner side wall of the trigger plate 721 is fixedly connected with one end of the trigger rod 722, the other end of the trigger rod 722 is penetrated through a connecting hole 515 and is connected with the middle part of one side wall of the trigger sliding block 723, a third inclined surface 725 is concavely arranged at the corner part of the top of the other side wall of the trigger sliding block 723, the squeezing block 724 is slidably arranged at the top of the mounting groove 511, a fourth inclined surface 726 is concavely arranged at the bottom of the squeezing block 724 adjacent to the corner part of one side of the trigger sliding block 723, the fourth inclined surface 726 is propped against the third inclined surface 725, the locking element 73 comprises a first sliding block 731, two sliding connecting posts 732, a connecting transverse plate 733, two connecting vertical plates 734, two connecting springs 735 and two second connecting blocks 736, the first sliding block 731 is slidably arranged in the sixth sliding groove 513, the bottom surface of the first sliding block 731 is provided with a second sliding block 738 in a protruding way near one side of the inserting slot 211, the second sliding block 738 is installed in the first sliding slot 215 in a sliding way, the middle part of the top surface of the first sliding block 731 is provided with a connecting column 737 in a protruding way, the top surface of the connecting column 737 is fixedly connected with the bottom surface of the triggering sliding block 723, the top surfaces of the two sliding connecting columns 732 are respectively fixedly installed at two ends of the other side of the bottom surface of the first sliding block 731, the connecting diaphragm 733 is respectively fixedly connected with the bottoms of the inner side walls of the two sliding connecting columns 732, one ends of the two connecting risers 734 are respectively fixedly installed at two ends of the connecting diaphragm 733 near one side wall of the inserting slot 211, one ends of the two connecting springs 735 are respectively fixedly installed at the inner side walls of the two connecting risers 734, the other ends of the two connecting springs 735 are respectively fixedly installed at the outer side walls of the two second connecting blocks 736, one ends of the inner side walls of the two second connecting blocks 736 are respectively concavely provided with a fifth inclined surface 739 near one end of the inserting slot 211, the two fifth inclined surfaces 739 are slidably mounted on two sides of the triangular block 631 respectively, a rubber block 740 is further disposed between the connection diaphragm 733 and the two second connection blocks 736, and a triangular groove 741 is concavely formed in the middle of the side wall of the rubber block 740.

For example, in one embodiment: when the stacker is required to carry the warehouse goods, the electric device 14 drives the body device 11 to start, so that the body device 11 moves along the ground rail assembly 15 and the ceiling rail assembly 16, when the preset place is reached, the travel switch 17 recognizes the preset place signal and sends the place signal to the power distribution interface 18 along the connecting wire, the power distribution interface 18 drives the drag chain device 13 to start, so that the loading platform mounting device 12 moves up and down along the body device 11, and the goods are carried.

For example, in one embodiment: when the electric wire plug on the connecting electric wire needs to be connected with the electric wire distribution interface 18, the electric wire distribution interface 18 is penetrated into the hollow cavity 21 through the through groove 611 and the electric inserting groove 211, and is inserted into the side wall of the electric socket 51, the bottom surface of the electric wire plug is clamped on the top surface of the clamping plate 53, and the inner wall of the groove 611 is clamped on the outer wall of the electric wire plug, when the electric wire plug is inserted into the side wall of the electric socket 51, the trigger plate 721 moves towards one end of the electric wire inserting groove 212, the trigger rod 722 moves along with the electric wire plug, the trigger sliding block 723 moves along the bottom of the installation groove 511, and the fourth inclined surface 726 abuts against the third inclined surface, so that the extrusion block 724 moves upwards along the height direction of the installation groove 511, the top surface of the extrusion block 724 abuts against the top surface of the hollow cavity 21, the socket assembly 50 and the electric wire plug are further clamped and locked integrally, and the socket assembly 50 and the electric wire plug are prevented from loosening and shifting caused by subsequent vibration.

Simultaneously, trigger the removal of sliding block 723 will lead to spliced pole 737 to follow the removal, will make first sliding block 731 follow the removal, make two sliding spliced poles 732, connect diaphragm 733 and two connect riser 734 follow the removal in step, make two connecting springs 735 and two second connecting blocks 736 follow the removal in step, make the triangular block 631 of sliding locking plate 63 slide along fifth inclined plane 739, and sliding locking plate 63 keeps stopping, when receiving strong vibrations, will make the card of pull ring 61 establish groove 612 and drop from two buckles 207, make pull ring 61 will rotate around first pivoted column 202 under the restoring effort of jump ring, make the synchronous rotation of card arc piece 615, make the outer wall of card arc piece 615 will abut against the locking piece 62 end wall and rotate, make locking piece 62 slide along third sliding groove 203 inboard, make locking piece 62 promote sliding locking plate 63 inwards to hold, make two connecting springs 735 compress, for the kinetic energy that the vibrations absorbed a part, simultaneously 61 pass through groove 611 rotates along with the rotation of pull ring 61, will be in order to guarantee the electric wire and insert the electric wire from the stability of the plug, make the electric wire can be connected to the plug from the outer wall of plug-in the power distribution box 21 through groove, the cable connection performance of electric wire and plug-wire, the plug is further guaranteed, plug connection stability is guaranteed from the plug-wire, plug connection is guaranteed, plug connection is made to be connected to the cable connection is stable from the plug 20, plug connection is made to the wire.

For example, in one embodiment: when the stacker is used for carrying, vibration and pulling force received in the body device 11 and the travel switch 17 are possibly transmitted to the distribution interface 18 along the connecting wire, when the pulling force applied to the wire plug generates an outward movement trend, the clamping plate 53 is applied with the pulling force applied to the wire plug, the pulling force is transmitted to the connecting frame 52 along the electric socket 51, the connecting frame 52 is slightly moved by the pulling force, and as the first triangular blocks of the two lateral arc-shaped spring plates 713 are respectively clamped in the two second spring plate clamping grooves 521, one end of the lateral arc-shaped spring plates 713 adjacent to the locking transverse plate 711 is stressed and tensioned, the other end of the lateral arc-shaped spring plates 713 is pressed against the side wall of the hollow cavity 21 by the pulling force, the lateral arc-shaped spring plates 713 form a triangle-like stable structure clamped in the hollow cavity 21, the lateral stable structure provides a transverse stable force for the connecting frame 52, the wire plug and the socket assembly 50 is ensured not to be pulled by the pulling force, and simultaneously, the two lateral arc-shaped spring plates 713 are also supported by the two lateral arc-shaped spring plates 714 and are further clamped on the wire plug and the wire plug assembly 50, and the wire plug assembly is further ensured to be clamped by the connecting frame and the wire plug assembly 50, and the wire plug assembly is further stably supported by the wire plug assembly is supported by the wire plug and the wire assembly and the wire plug 50.

For example, in one embodiment: when the wire plug is pushed to the inside of the hollow cavity 21 by the extrusion force, the electric socket 51 is slightly extruded to the inner end by the extrusion force, so that the connecting frame 52 slightly moves, the end wall of one end of the connecting frame 52 far away from the electric inserting groove 211 is abutted against the fastening block 32 of the upper cover 30 of the shell, further movement of the connecting frame is prevented from being pressed and destroyed, meanwhile, the pull ring 61 is caused to rotate inwards around the first rotating column 202, the clamping arc-shaped block 615 rotates along with the pull ring, the second inclined face 617 of the clamping arc-shaped block 615 moves upwards, the arc-shaped face 625 at the bottom of the clamping block 624 moves outwards by extrusion, the locking piece 62 moves outwards, the sliding locking plate 63 moves along, the second connecting block 736 moves along, the two connecting vertical plates 734 move along, the first sliding block 731 moves along one end of the electric inserting groove 211, the triggering sliding block 723 moves along, the triggering plate 721 applies a pushing force acting in the opposite direction on the top of the wire plug, the clamping arc-shaped block 615 moves along with the elastic force, the electric socket 51 is prevented from being caused by overlarge extrusion force, and the circuit board 41 is caused to destroy, and stability and safety of connection are ensured.

The installation process comprises the following steps: the ground rail assembly 15 is fixedly arranged on the installation bottom surface, the top rail assembly 16 is fixedly arranged on the top plate of the storehouse, the length direction of the ground rail assembly 15 is parallel to the length direction of the top rail assembly 16, the bottom of the machine body device 11 is slidably arranged in the ground rail assembly 15, the top plate of the machine body device 11 is slidably arranged in the top rail assembly 16, the loading platform installation device 12 is arranged on the other side of the bottom of the machine body device 11, one end of the drag chain device 13 is arranged in the loading platform installation device 12, the other end of the drag chain device 13 is arranged on the top plate of the machine body device 11, the electric device 14 is arranged on one side of the bottom of the machine body device 11 adjacent to the travel switch 17, the distribution interface 18 is electrically connected with the travel switch 17, the circuit board 41 is clamped and arranged between the limiting posts 217 and the two inserting blocks 31, the bottom surface of the connecting silicone block 42 is fixedly arranged on one end of the top surface of the circuit board 41 adjacent to the power feeding groove 212, the top surface of the connecting silica gel block 42 is propped against the bottom surface of the fastening block 32, the bottom surface of the clamping block 43 is fixedly arranged at the other end of the top surface of the circuit board 41, the connecting frame 52 is fixedly arranged at the top part of one end of the electric socket 51 adjacent to the electric inlet groove 212, the clamping plate 53 is fixedly arranged at the bottom of the other end of the electric socket 51, the bottom surface of the connecting frame 52 is propped against one end of the top surface of the circuit board 41 adjacent to the electric inlet groove 211, the bottom surface of the clamping plate 53 is propped against the bottom of the hollow cavity 21, the locking piece 62 is slidingly arranged in the third sliding groove 203, the two rotating rings 614 are rotationally arranged at one end of the two first rotating columns 202, the first connecting block 623 of the locking piece 62 is penetrated between one rotating ring 614 and the locking arc-shaped block 615, the locking block 624 of the first connecting block 623 is blocked in the locking groove 616, the sliding locking plate 63 is slidingly arranged in the fourth sliding groove 206, the end wall of the sliding locking plate 63 is propped against the inner side wall of the second limiting groove 622, the top surface of the locking transverse plate 711 is fixedly arranged in the middle of the bottom surface of the upper cover 30 of the shell, the top surfaces of the two locking vertical plates 712 are respectively and fixedly arranged at two ends of the bottom surface of the locking transverse plate 711, one end of the two lateral arc-shaped elastic plates 713 are respectively and fixedly arranged at the bottom of one side wall of the two locking vertical plates 712 adjacent to the electric inserting groove 211, two first triangular blocks are respectively clamped in two second elastic plate clamping grooves 521, one end of the two lateral arc-shaped elastic plates 714 are respectively and fixedly arranged at two ends of one side of the locking transverse plate 711 adjacent to the electric inserting groove 211, two second triangular blocks are respectively clamped in the two first elastic plate clamping grooves 431, the middle of the side wall of the inner side of the trigger plate 721 is fixedly connected with one end of the trigger rod 722, the other end of the trigger rod 722 is penetrated through the connecting hole 515 and is connected with the middle of one side wall of the trigger sliding block 723, the extrusion block 724 is slidingly arranged at the top of the mounting groove 511, the fourth inclined surface 726 is abutted against the third inclined surface 725, the first sliding block 731 is slidably mounted in the sixth sliding groove 513, the second sliding block 738 is slidably mounted in the first sliding groove 215, the top surface of the connecting post 737 is fixedly connected with the bottom surface of the trigger sliding block 723, the top surfaces of the two sliding connecting posts 732 are respectively fixedly mounted at two ends of the other side of the bottom surface of the first sliding block 731, the connecting diaphragm 733 is respectively fixedly connected with the bottoms of the inner side walls of the two sliding connecting posts 732, one ends of the two connecting risers 734 are respectively fixedly mounted at two ends of the side wall of the connecting diaphragm 733 adjacent to one side wall of the inserting groove 211, one ends of the two connecting springs 735 are respectively fixedly mounted at the inner side walls of the two connecting risers 734, the other ends of the two connecting springs 735 are respectively fixedly mounted at the outer side walls of the two second connecting posts 736, and the two fifth inclined surfaces 739 are respectively slidably mounted at two sides of the triangular block 631.

1. The socket assembly 50 and the locking assembly 70 in the power distribution interface 18 are used for further clamping and locking the wire plug on the connecting wire after the wire plug is inserted into the power distribution shell 20, so that the socket assembly 50 and the wire plug are prevented from loosening and shifting due to subsequent vibration, and meanwhile, when the pull ring assembly 60 is subjected to vibration caused by carrying and other reasons due to the cooperation of the pull ring assembly 60 and the locking assembly 70, the wire plug inserted into one end of the hollow cavity 21 can be abutted and clamped or clad and fixed, the wire plug is prevented from being separated from the power distribution shell 20 due to vibration, the stability of the wire plug insertion is further ensured, and the stability and the reliability of connection are ensured.

2. When the power distribution interface 18 receives a pulling force, the locking assembly 70 is utilized to adaptively buffer the socket assembly 50, and a triangle-like stable structure is formed in the hollow cavity 21 to further clamp and stabilize the socket assembly 50 and the circuit assembly 40 to provide a longitudinal supporting force and a transverse stabilizing force, so that the wire plug and the socket assembly 50 can not be pulled out by the pulling force, and the fixation and stability of the wire plug and the socket assembly 50 are ensured.

3. When the power distribution interface 18 is acted by extrusion force, the end wall of one end of the connecting frame 52 far away from the electric inserting groove 211 is abutted against the fastening block 32 of the upper cover 30 of the shell, so that the circuit board 41 is prevented from being damaged by further movement, meanwhile, the locking assembly 70 is matched with the pull ring assembly 60, so that the trigger plate 721 applies an opposite-direction pushing force to the top of the electric wire plug, the electric socket 51 is prevented from moving due to overlarge extrusion force, the circuit board 41 is prevented from being damaged by compression, and the stability and the safety of connection are ensured.

The above embodiments represent only a few embodiments of the present invention, which are described in more detail and are not to be construed as limiting the scope of the present invention. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (5)

1. An energy-conserving electric power distribution interface system for stacker, characterized in that: the electric power distribution system comprises a track installation device (10), a machine body device (11), a cargo carrying platform installation device (12), a drag chain device (13) and an electric device (14), wherein the track installation device (10) comprises a ground track assembly (15) and a top track assembly (16), the ground track assembly (15) is fixedly installed on the installation bottom surface, the top track assembly (16) is fixedly installed on a warehouse top plate, the length direction of the ground track assembly (15) is parallel to the length direction of the top track assembly (16), the bottom of the machine body device (11) is slidably installed in the ground track assembly (15), the top plate of the machine body device (11) is slidably installed in the top track assembly (16), one side of the bottom of the machine body device (11) is convexly provided with a travel switch (17), the cargo carrying platform installation device (12) is installed on the other side of the bottom of the machine body device (11), one end of the drag chain device (13) is installed in the installation device (12), the other end of the drag chain device (13) is installed on the top plate of the machine body device (11) and the bottom of the electric device (14) is adjacent to one side of the travel switch (17), a power distribution interface (18) is arranged in the electric device (14), the electric device (18) is electrically connected with a power distribution interface (20) and a power distribution module (30) comprises an electric circuit assembly The socket assembly (50), pull ring assembly (60) and locking assembly (70), the cavity is formed with cavity (21) in the inside cavity of distribution shell (20), cavity (21) one end runs through concave electric slot (211) that is equipped with, cavity (21) other end concave electric slot (212) that is equipped with, cavity (21) top surface is adjacent to electric slot (212) one end run through concave upper cover groove (213) that is equipped with, distribution shell (20) is adjacent to electric slot (211) one side lateral wall bottom both ends protruding respectively are equipped with installation boss (201), two installation boss (201) lateral wall protruding respectively are equipped with first rotation post (202), shell upper cover (30) fixed mounting is in upper cover groove (213), circuit assembly (40) fixed mounting is in cavity (21) one end adjacent to electric slot (212), socket assembly (50) are installed in cavity (21) other end, and socket assembly (50) are connected with circuit assembly (40) electrical connection, installation in two first rotation posts (202) are run through to the bottom of pull ring assembly (60), locking assembly (70) are installed in socket assembly (50) lateral wall bottom, install circuit board (41) and are established between circuit board (41) and circuit board (41) are established in connection between two limit blocks (41) and circuit board (41), and the bottom surface of the connecting silica gel block (42) is fixedly arranged at one end of the top surface of the circuit board (41) adjacent to the power feeding groove (212), the top surface of the connecting silica gel block (42) is propped against the bottom surface of the fastening block (32), the bottom surface of the clamping block (43) is fixedly arranged at the other end of the top surface of the circuit board (41), the two sides of the top surface of the clamping block (43) are respectively concavely provided with a first elastic sheet clamping groove (431), the socket assembly (50) comprises an electric socket (51), a connecting frame (52) and a clamping plate (53), the connecting frame (52) is fixedly arranged at the top part of one end of the electric socket (51) adjacent to the power feeding groove (212), the clamping plate (53) is fixedly arranged at the bottom of the other end of the electric socket (51), the bottom surface of the connecting frame (52) is propped against one end of the top surface of the circuit board (41) adjacent to the electric inserting groove (211), the bottom surface of the clamping plate (53) is propped against the bottom of the hollow cavity (21), the middle part of the top surface of the electric socket (51) is concavely provided with a mounting groove (511), the bottom surface of the mounting groove (511) is concavely provided with a fifth sliding groove (512), the bottom surface is concavely provided with a sixth sliding groove (513) in a penetrating way, the top part of one end of the electric socket (51) adjacent to the clamping plate (53) is concavely provided with a propping groove (514), the middle part of the side wall of the inner side of the propping groove (514) is concavely provided with a connecting hole (515), the connecting hole (515) is communicated with the mounting groove (511), the middle parts of the side walls of two sides of the connecting frame (52) are concavely provided with second elastic sheet clamping grooves (521), the two second elastic sheet clamping grooves (521) are respectively oppositely arranged with the bottoms of the two fastening grooves (214), the pull ring assembly (60) comprises a pull ring (61), a locking piece (62) and a sliding locking plate (63), a through groove (611) is formed in the middle part of the side wall of one side of the pull ring (61), a clamping groove (612) is formed in the through groove (611) in a penetrating manner, two buckles (207) are respectively clamped at two ends of the clamping groove (612), a first inclined surface is concavely formed in the corner of the side wall of the outer side of the bottom surface of the clamping groove (611), rotating rings (614) are respectively convexly arranged at two sides of the bottom surface of the pull ring (61), clamping springs are rotatably arranged at one ends of the two first rotating posts (202), clamping springs are further arranged between the two rotating rings (614) and the two first rotating posts (202), a clamping arc block (615) is convexly arranged in the middle part of the bottom surface of the pull ring (61), a clamping arc block (615) is concavely provided with a clamping groove (616), the side wall of the clamping arc block (616) is concavely provided with a first inclined surface (621), the outer side of the bottom surface of the clamping groove (616) is provided with a second inclined surface (62) and is far away from the first inclined surface (621), the first inclined surface (621) and is far away from the first inclined surface (611) through the first inclined surface (62), the other end of the locking piece (62) is convexly provided with a first connecting block (623), the inner side wall of the first connecting block (623) is convexly provided with a clamping block (624), two corners at the top of the side wall of the clamping block (624) and the inner side corner at the bottom are both concavely provided with arc surfaces (625), the first connecting block (623) of the locking piece (62) is penetrated between one rotating ring (614) and the clamping arc block (615), the clamping block (624) of the first connecting block (623) is clamped in the clamping groove (616), the sliding locking plate (63) is slidably arranged in the fourth sliding groove (206), one end of the bottom surface of the sliding locking plate (63) adjacent to the inner side wall of the second limiting groove (622) is convexly provided with a triangular block (631), the end wall of the sliding locking plate (63) is fixedly connected with the inner side wall of the second limiting groove (622), the locking assembly (70) comprises a locking spring plate (71), a triggering element (72) and a locking spring plate (73), the locking spring plate (71) comprises a locking transverse plate (711), two locking vertical plates (712), two lateral spring plates (713) and two side surfaces and two side spring plates (713) are clamped in the clamping grooves (616), the bottom surface (711) are fixedly arranged on the two side surfaces of the locking plate (714) respectively, and the two side surfaces (714) are fixedly arranged on the middle surfaces of the two side surfaces of the locking plate (712 respectively, one end of each of the two lateral arc-shaped elastic pieces (713) is fixedly arranged at the bottom of one side wall of the two locking vertical plates (712) adjacent to the inserting groove (211), first triangular blocks are respectively arranged on the inner sides of the two lateral arc-shaped elastic pieces (713) in a protruding mode, the two first triangular blocks are respectively clamped in two second elastic piece clamping grooves (521), one end of each of the two transverse arc-shaped elastic pieces (714) is fixedly arranged at two ends of one side of the locking transverse plate (711) adjacent to the inserting groove (211), second triangular blocks are respectively arranged on the inner sides of the two transverse arc-shaped elastic pieces (714) in a protruding mode, the two second triangular blocks are respectively clamped in the two first elastic piece clamping grooves (431), and the trigger element (72) and the locking element (73) are respectively and slidably arranged in the electric socket (51).

2. The energy efficient power distribution interface system for a stacker of claim 1 wherein: the middle parts of two sides of the hollow cavity (21) are all penetrated and concavely provided with fastening grooves (214), the two fastening grooves (214) are all communicated with the upper cover groove (213), the middle part of the bottom surface of the hollow cavity (21) is concavely provided with a first sliding groove (215), the middle part of the bottom surface of the hollow cavity (21) is also penetrated and concavely provided with two second sliding grooves (216), the two second sliding grooves (216) are respectively positioned at two sides of the first sliding groove (215), and a plurality of limiting columns (217) are respectively arranged at equal intervals at the middle part of the bottom surface of the hollow cavity (21) and one end adjacent to the power feeding groove (212).

3. The energy efficient power distribution interface system for a stacker of claim 2 wherein: the power distribution shell (20) is adjacent to a third sliding groove (203) arranged in the center of the bottom of one side wall of the power insertion groove (211), a first limiting groove (205) is arranged in the bottom of the third sliding groove (203), a fourth sliding groove (206) is arranged in the center of the bottom of the power distribution shell (20), the fourth sliding groove (206) and the first sliding groove (215) are oppositely arranged, two second sliding grooves (216) are respectively arranged on two sides of the fourth sliding groove (206), the fourth sliding groove (206) is communicated with the first limiting groove (205), and two buckles (207) are respectively arranged at two ends of the top of one side wall of the power distribution shell (20) in a protruding mode.

4. The energy efficient power distribution interface system for a stacker of claim 3 wherein: the two sides of the bottom surface of the upper cover (30) adjacent to one end of the power inserting groove (211) are respectively provided with an inserting block (31) in a protruding mode, the two inserting blocks (31) are inserted and installed in the two fastening grooves (214), the two sides of the other end of the bottom surface of the upper cover (30) are respectively provided with a clamping column (33) in a protruding mode, and the middle of the bottom surface of the upper cover (30) is provided with a fastening block (32) in a protruding mode.

5. The energy efficient power distribution interface system for a stacker as in claim 4 wherein: the triggering element (72) comprises a triggering plate (721), a triggering rod (722), a triggering sliding block (723) and an extrusion block (724), the middle part of the inner side wall of the triggering plate (721) is fixedly connected with one end of the triggering rod (722), the other end of the triggering rod (722) is penetrated through a connecting hole (515) and is connected with the middle part of one side wall of the triggering sliding block (723), a third inclined surface (725) is concavely arranged at the top corner of the side wall of the other side of the triggering sliding block (723), the extrusion block (724) is slidingly arranged at the top of the mounting groove (511), a fourth inclined surface (726) is concavely arranged at the bottom of the extrusion block (724) adjacent to the corner of one side of the triggering sliding block (723), the fourth inclined surface (726) is propped against the third inclined surface (725), the locking element (73) comprises a first sliding block (731), two sliding connecting columns (732), a connecting transverse plate (733), two connecting vertical plates (734), two connecting springs (735) and two second connecting blocks (736), the first sliding block 731) is slidingly arranged in the sixth sliding groove (513), the bottom surface of the first sliding block (731) is adjacently to the top of the second sliding block (211) is provided with a second connecting block (738), the connecting column (737) top surface and trigger sliding block (723) bottom surface fixed connection, two sliding connecting column (732) top surfaces are fixed mounting respectively in first sliding block (731) bottom surface opposite side both ends, connect diaphragm (733) respectively with two sliding connecting column (732) inboard lateral wall bottom fixed connection, two connecting riser (734) one end fixed mounting respectively in connecting diaphragm (733) are adjacent to one side lateral wall both ends of inserting electric tank (211), two connecting spring (735) one end fixed mounting respectively in two connecting riser (734) inboard lateral walls, two connecting spring (735) other end fixed mounting respectively in two second connecting block (736) outside lateral walls, two second connecting block (736) inboard lateral walls all concave are equipped with fifth inclined plane (739) adjacent to inserting electric tank (211) one end, two fifth inclined plane (739) are installed in triangle piece (631) both sides respectively in a sliding way, still be provided with rubber piece (740) between connecting diaphragm (733) and two second connecting block (736), rubber piece (740) lateral wall middle part concave be equipped with triangle groove (741).