CN108747959B - Locking mechanism for butt joint and compaction of net sheets - Google Patents

Abstract

The invention provides a locking mechanism for butting and compacting a net sheet, which comprises the following components: the device comprises a rack, wherein a lock catch assembly is arranged in the middle of the rack along the vertical direction of the rack; the two positioning and clamping assemblies are respectively positioned at two sides of the lock catch assembly, wherein the positioning and clamping assemblies can move along the vertical direction of the frame; the two positioning and butting assemblies are respectively and correspondingly positioned at one side of the positioning and clamping assembly. According to the locking mechanism for butting and compacting the mesh, disclosed by the invention, the accurate butting and compacting of the opening and closing parts of the frame structure after bending can be realized, and the phenomenon of disengaging again is avoided, so that the reliability of the frame structure in manufacturing is improved.

Description

Locking mechanism for butt joint and compaction of net sheets

Technical Field

The invention belongs to the technical field of machinery, and relates to a locking mechanism, in particular to a locking mechanism for butting and compacting a net piece.

Background

The IBC ton barrel has the advantages of light weight, high strength, corrosion resistance and the like. Is widely used in the industries of chemical industry, medicine, food, paint, grease and the like, and is a necessary tool for modern storage and transportation of liquid products. The ton bucket is formed by combining an inner container and a metal frame, wherein the inner container is formed by adopting high molecular weight high density polyethylene for blow molding, and the ton bucket is high in strength, corrosion resistant and good in sanitation, and the metal frame is added outside the inner container, so that the ton bucket is safer and more reliable in use.

The existing metal frame is formed by welding a plurality of metal pipe fittings to form a screen plate structure, then bending is carried out on the metal pipe fittings through bending equipment to form a frame structure with a square section, but the frame structure formed at the moment is in an unsealed state and cannot bear the inner container of the IBC ton barrel, then the butt joint of the frame structure is required to be closed, and the frame structure is formed by welding a plurality of metal pipe fittings.

In summary, a latch mechanism with high docking accuracy and high docking speed is required.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides a locking mechanism with high butt joint precision and high butt joint speed.

The aim of the invention can be achieved by the following technical scheme: a mesh docking, compression latch mechanism, comprising: the frame is provided with a lock catch assembly in the middle of the frame along the vertical direction, so that the frame structure is tightly pressed at the butt joint position of the transverse ribs, and the phenomenon that the transverse ribs are separated again after the butt joint is avoided; the two positioning and clamping assemblies are respectively positioned at two sides of the lock catch assembly, and can move along the vertical direction of the frame to clamp the transverse ribs on the frame structure, so that the transverse ribs on the left side and the right side of the frame structure are positioned on the same straight line, the butt joint parts on the left transverse rib and the right transverse rib are forced to be aligned, and a coaxial condition is provided for butt joint; the two positioning butt joint assemblies are respectively and correspondingly positioned at one side of the positioning clamping assembly and are used for positioning the butt joint position of the frame structure and realizing nested butt joint of the frame structure at the butt joint position, wherein the positioning butt joint assemblies can move along the horizontal square of the frame.

In the above-mentioned locking mechanism that net piece dock, compress tightly, the hasp subassembly includes a base plate of installing in the frame to and the sliding plate who is connected mutually with the base plate, wherein, be provided with a plurality of sliding structure along the length direction of sliding plate, and first hydro-cylinder, wherein, the one end of first hydro-cylinder is connected on the base plate, and the other end of first hydro-cylinder is connected on the sliding plate.

In the above-mentioned locking mechanism for butt joint and compaction of meshes, two side-by-side sliding rails are arranged on the substrate, wherein two sides of the sliding plate are slidably connected to the sliding rails.

In the above mesh abutting and pressing locking mechanism, among the plurality of sliding structures, the distance between the sliding structure near one end of the ground and the adjacent sliding structure is larger than the distance between any two other adjacent sliding structures.

In the above-mentioned locking mechanism that net piece dock, compress tightly, sliding structure is including installing the U type support on the sliding plate, is provided with a bar recess that is the curve state in one side of U type support open end, is provided with a bar arch that is the curve state in the opposite side of U type support open end, and wherein, bar recess and the protruding position of bar are corresponding.

In the above locking mechanism for butting and compacting the net sheets, an elastic module is arranged on the U-shaped bracket, wherein the strip-shaped groove is arranged on the elastic module.

In the above-mentioned locking mechanism that net piece dock, compress tightly, location clamp assembly is including installing the pneumatic structure in the frame to and the clamp structure who links to each other with pneumatic structure, wherein, clamp structure includes two locating plates that set up from top to bottom, and is provided with two clamping pieces side by side between two locating plates, wherein, a clamping piece fixed link is between two locating plates, and another clamping piece links to each other with pneumatic structure.

In the above-mentioned locking mechanism that net piece dock, compress tightly, the clamping piece of both ends rigid coupling on the locating plate is first clamping piece, and the clamping piece that links to each other with pneumatic structure is the second clamping piece, and wherein, first clamping piece is including location support mounting, and along the length direction of location support mounting to can dismantle a plurality of location support piece of connecting on the location support mounting, the second clamping piece is including location briquetting mounting, and along the length direction of location briquetting mounting, and can dismantle a plurality of location briquetting of connecting on the location briquetting mounting, wherein, location briquetting and location support piece interval setting.

In the above locking mechanism for butting and compacting the mesh, the surface of the positioning support piece on the side opposite to the positioning press piece is a plane, and the surface of the positioning press piece on the side opposite to the positioning support piece is a fold line concave surface.

In the above-mentioned locking mechanism that net piece dock, compress tightly, location butt joint subassembly is including the butt joint support that slides in the frame, and is provided with a slip module on the butt joint support, wherein, is provided with a plurality of positioning seat along the length direction of slip module, and is provided with a pair of locating rack on every positioning seat.

In the above-mentioned locking mechanism for butt joint and compaction of meshes, two separators are arranged at one side of the sliding module, and the two separators are respectively positioned at two ends of the butt joint support, wherein a second oil cylinder is arranged on the butt joint support at the same side as the separators.

In the above-mentioned locking mechanism for butt joint and compaction of meshes, the action ends of the separators are arranged in a horizontal arc structure, wherein, on the same horizontal plane, the arc structures of the separators on the butt joint brackets at the left and right sides are combined to form a embracing structure.

In the above locking mechanism for butting and compacting the meshes, each pair of positioning frames is arranged in an up-down symmetrical structure, wherein an inclined plane is arranged on the opposite side of each pair of positioning frames.

In the locking mechanism for butting and compacting the net sheets, the sliding module close to one end of the ground is provided with the bracket which is positioned on the same vertical plane with the plurality of positioning seats.

In the above-mentioned locking mechanism for butt joint and compaction of meshes, the locking mechanism further comprises a bottom frame assembly, and a guide rail is respectively arranged at two sides of the bottom frame assembly, wherein the frame is arranged on the bottom frame assembly, and a trolley assembly is arranged on the guide rail.

In the mesh abutting and pressing locking mechanism, a buffer part is arranged on each corner of the underframe assembly.

Compared with the prior art, the mesh abutting joint and pressing locking mechanism provided by the invention can realize accurate abutting joint and pressing of the abutting joint of the frame structure after bending, so that the phenomenon of disengaging again is avoided, and the reliability of the frame structure during manufacturing is improved.

Drawings

Fig. 1 is a schematic structural view of a locking mechanism for mesh docking and compaction according to the present invention.

FIG. 2 is a schematic view of a latch assembly according to a preferred embodiment of the present invention.

FIG. 3 is a schematic view of a latch assembly according to another embodiment of the present invention.

FIG. 4 is a schematic view of a positioning and clamping assembly according to a preferred embodiment of the present invention.

FIG. 5 is a schematic view of a positioning docking assembly according to a preferred embodiment of the present invention.

100, a rack; 200. a latch assembly; 210. a substrate; 220. a sliding plate; 230. a first cylinder; 240. a U-shaped bracket; 241. a bar-shaped protrusion; 250. an elastic module; 251. a strip-shaped groove; 300. positioning and clamping the assembly; 310. a pneumatic structure; 320. a positioning plate; 330. positioning the support mounting member; 340. positioning the support; 350. positioning a press block mounting piece; 360. positioning a pressing block; 400. positioning the butt joint assembly; 410. a sliding module; 420. a positioning seat; 430. a positioning frame; 440. a separator; 450. a second cylinder; 460. a bracket; 470. a butt joint bracket; 500. a chassis assembly; 600. a trolley assembly; 700. and a buffer member.

Detailed Description

The following are specific embodiments of the present invention and the technical solutions of the present invention will be further described with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

As shown in fig. 1 to 5, the latch mechanism for butting and compacting a mesh provided by the invention comprises: the frame 100 is provided with a lock catch assembly 200 in the middle of the frame 100 along the vertical direction, so that the frame structure is tightly pressed at the butt joint position of the transverse ribs, and the phenomenon that the transverse ribs are separated again after the butt joint is avoided; the two positioning and clamping assemblies 300 are respectively positioned at two sides of the lock catch assembly 200, wherein the positioning and clamping assemblies 300 can move along the vertical direction of the frame 100 and are used for clamping transverse ribs on the frame structure, so that the transverse ribs at the left side and the right side of the frame structure are positioned on the same straight line, butt joint parts on the left transverse rib and the right transverse rib are forced to be aligned, and a coaxial condition is provided for butt joint; the two positioning and docking assemblies 400 are respectively and correspondingly located at one side of the positioning and clamping assembly 300 and are used for positioning the docking position of the frame structure and realizing nested docking of the frame structure at the docking position, wherein the positioning and docking assemblies 400 can move along the horizontal square of the frame 100.

According to the mesh abutting and pressing locking mechanism, after the frame structure is bent, the abutting position of the frame structure is accurately abutted and pressed, the phenomenon of disengaging again is avoided, and therefore reliability of the frame structure in manufacturing is improved.

Preferably, as shown in fig. 1 to 5, the latch assembly 200 includes a base plate 210 mounted on the frame 100, and a sliding plate 220 slidably connected with the base plate 210, wherein a plurality of sliding structures are disposed along a length direction of the sliding plate 220, and a first cylinder 230, wherein one end of the first cylinder 230 is connected to the base plate 210, and the other end of the first cylinder 230 is connected to the sliding plate 220, and the sliding plate 220 is moved on the base plate 210 through the first cylinder 230, and since the plurality of sliding structures are detachably connected to the sliding plate 220, when the sliding plate 220 moves up and down along the base plate 210, the plurality of sliding structures move up and down along the base plate 210 synchronously along with the sliding plate 220, thereby achieving synchronous locking at each butt joint position on the frame structure.

Further preferably, as shown in fig. 1 to 5, two slide rails are disposed side by side on the base plate 210, wherein both sides of the slide plate 220 are slidably connected to the slide rails, so that the slide plate 220 moves up and down along the vertical direction of the base plate 210. Further preferably, in the plurality of sliding structures, the distance between the sliding structure close to one end of the ground and the adjacent sliding structure is larger than the distance between any two other adjacent sliding structures, wherein the structure is adopted to lock the transverse ribs close to the upper layer on the frame structure after the transverse ribs are butted, so that the transverse ribs of the lowest layer of the frame structure are not locked, and the position of the transverse ribs is used as the position of the discharge hole of the IBC ton barrel.

Further preferably, as shown in fig. 1 to 5, the sliding structure includes a U-shaped bracket 240 mounted on the sliding plate 220, a bar-shaped groove 251 in a curved state is provided on one side of an opening end of the U-shaped bracket 240, and a bar-shaped protrusion 241 in a curved state is provided on the other side of the opening end of the U-shaped bracket 240, wherein the bar-shaped groove 251 corresponds to the position of the bar-shaped protrusion 241, and when a horizontal bar in the frame structure is embedded into the opening end of the U-shaped bracket 240, the reliability and safety of the butt joint of the frame structure in locking are ensured by the cooperation between the bar-shaped groove 251 and the bar-shaped protrusion 241. Further preferably, an elastic module 250 is disposed on the U-shaped bracket 240, wherein a strip-shaped groove 251 is formed on the elastic module 250, and the elastic module 250 is deformed by compression to achieve a buffering effect when clamping and loosening between the strip-shaped groove 251 and the strip-shaped protrusion 241.

Preferably, as shown in fig. 1 to 5, the positioning and clamping assembly 300 includes a pneumatic structure 310 mounted on the frame 100, and a clamping structure connected to the pneumatic structure 310, wherein the clamping structure includes two positioning plates 320 disposed up and down, and two clamping members are disposed side by side between the two positioning plates 320, wherein one clamping member is fixedly connected between the two positioning plates 320, and the other clamping member is connected to the pneumatic structure 310, and the clamping member moves up and down through the pneumatic structure 310, so as to clamp left and right transverse ribs on the frame structure, so that the left and right transverse ribs on the frame structure are aligned in a straight line, forcing the left and right abutting portions to align, and providing coaxial conditions for abutting.

Further preferably, as shown in fig. 1 to 5, the clamping members with two ends fixedly connected to the positioning plate 320 are first clamping members, the clamping members connected to the pneumatic structure 310 are second clamping members, wherein the first clamping members include positioning support mounting members 330, and are detachably connected to a plurality of positioning support members 340 on the positioning support mounting members 330 along the length direction of the positioning support mounting members 330, the second clamping members include positioning press block mounting members 350, and are detachably connected to a plurality of positioning press blocks 360 on the positioning press block mounting members 350 along the length direction of the positioning press block mounting members 350, wherein the positioning press blocks 360 are arranged at intervals with the positioning support members 340, and up-and-down movement of the positioning press block mounting members 350 is realized through the pneumatic structure 310, so that the relative distance between the positioning press blocks 360 and the positioning support members 340 is changed, and further coaxial conditions are provided for butt joint of left and right transverse ribs. The positioning press block mounting member 350 is driven by the pneumatic structure 310, so that the plurality of positioning press blocks 360 connected to the positioning press block mounting member 350 move up and down synchronously along with the positioning press block mounting member 350, that is, the relative distance between two adjacent positioning press blocks 360 and the positioning support member 340 is changed synchronously.

It is further preferred that the surface of the positioning support 340 on the side opposite to the positioning support 340 is planar and the surface of the positioning support 340 on the side opposite to the positioning support 340 is concave in a broken line, as shown in fig. 1 to 5, so as to ensure that the left and right transverse ribs on the frame structure are in a straight line, forcing the left and right abutting portions to align, providing coaxial conditions for abutting.

Preferably, as shown in fig. 1 to 5, the positioning docking assembly 400 includes a docking bracket 470 slidably connected to the frame 100, and a sliding module 410 is disposed on the docking bracket 470, wherein a plurality of positioning seats 420 are disposed along a length direction of the sliding module 410, and a pair of positioning frames 430 are disposed on each positioning seat 420, and positioning of the frame structure during docking is achieved by the positioning frames 430 on the positioning seats 420. It is further preferred that two separators 440 are disposed at one side of the sliding module 410, and the two separators 440 are respectively disposed at two ends of the docking bracket 470, wherein a second cylinder 450 is disposed on the docking bracket 470 at the same side as the separators 440, and the two positioning docking assemblies 400 are disposed at the left and right sides of the frame 100, so that when the second cylinders 450 on the two positioning docking assemblies 400 are simultaneously operated, the separators 440 respectively connected to the left and right docking brackets 470 synchronously move in opposite directions or relatively, thereby changing the relative distance between two ends of the docking portion of the frame structure, and because the two ends of the frame structure are influenced by their own gravity, the pipe orifices of the transverse ribs at the two ends are not on the same horizontal plane, the relative positions of the transverse ribs at the two ends are pulled by the separators 440, and under the action of the positioning clamping assembly 300 and the positioning seat 420, the transverse ribs with smaller diameters on the frame structure are ensured to be on the same straight line, thereby realizing the accurate docking operation of the transverse ribs at the left and right sides. Therefore, the second cylinder 450 in this embodiment acts as a power source for pulling the separator 440 apart the two ends of the frame structure where they butt against each other, and as a power source for the two ends of the frame structure where they butt against each other.

Further preferably, as shown in fig. 1 to 5, the active ends of the separator 440 are disposed in a horizontal arc structure, wherein the arc structures of the separator 440 on the left and right docking brackets 470 are combined to form a cohesive structure on the same horizontal plane, thereby improving reliability when the opposite distances of the two ends of the docking of the frame structure are separated by the separator 440, and preventing the separator 440 from being separated from the frame structure.

Further preferably, as shown in fig. 1 to 5, each pair of positioning frames 430 is arranged in a vertically symmetrical structure, wherein opposite sides of two positioning frames 430 are in a duckbill structure shape, i.e., opposite sides of each pair of positioning frames 430 are provided with an inclined plane, so that transverse ribs on the frame structure can be smoothly embedded into gaps between the two positioning frames 430, and the positioning speed of the frame structure is improved.

It is further preferable that, as shown in fig. 1 to 5, a bracket 460 is provided on the sliding module 410 near one end of the ground, and is positioned on the same vertical plane as the plurality of positioning seats 420 for supporting the bottom of the frame structure, thereby improving the accuracy of the butt joint of the two ends of the frame structure.

Preferably, as shown in fig. 1 to 5, the latch mechanism further includes a chassis assembly 500, and a guide rail is provided at each side of the chassis assembly 500, wherein the frame 100 is mounted on the chassis assembly 500, and a trolley assembly 600 is provided on the guide rail for receiving the butted and compacted frame structure and conveying it to the next mechanism (punching mechanism).

Further preferably, as shown in fig. 1 to 5, a buffer member 700 is provided at each corner of the chassis assembly 500, and downward pressure is generated when the frame structure is docked and compressed, and impact to the chassis assembly 500 is relieved by the buffer member 700, thereby improving safety and life of the latch mechanism.

The working principle of the invention is as follows: firstly, the bent frame structure moves forwards through the trolley assembly 600, in the running process, the frame structure touches the separator 400, the abutting part on the frame structure is separated through the separator 400, so that the abutting part is positioned on a straight line, a gap of more than half a centimeter is reserved in the middle, and when the trolley assembly 600 runs to the bottom, transverse ribs on the frame structure are restrained by the positioning seat 420 up and down, and the vertical directions are kept to be basically aligned; then, the pneumatic structure 310 drives the positioning press block mounting piece 350 to move downwards, and clamps the transverse ribs on the frame structure, so that the left transverse rib and the right transverse rib are on the same straight line, the left butt joint part and the right butt joint part are forced to be aligned, and a coaxial condition is provided for butt joint; then, the left and right second cylinders 450 respectively push the docking bracket 470 to move relatively, so that the transverse ribs on the left and right docking portions are mutually spliced, and when the second cylinders 450 travel to the bottom, the docking portions are spliced in place; then the U-shaped bracket 240 is pushed to ascend by the first oil cylinder 230 in the lock catch assembly 200, and the butted transverse ribs are riveted; finally, the docked frame structure is brought back to the original position by the trolley assembly 600.

The specific embodiments described herein are offered by way of example only to illustrate the spirit of the invention. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions thereof without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (7)

1. The utility model provides a locking mechanism that net piece dock, compress tightly which characterized in that includes:

a frame, a latch component is arranged in the middle of the frame along the vertical direction of the frame and used for pressing the butt joint of the frame structure on the transverse ribs, wherein,

the lock catch assembly comprises a base plate arranged on the frame and a sliding plate in sliding connection with the base plate, wherein a plurality of sliding structures and a first oil cylinder are arranged along the length direction of the sliding plate, one end of the first oil cylinder is connected to the base plate, and the other end of the first oil cylinder is connected to the sliding plate;

the sliding structure comprises a U-shaped bracket arranged on a sliding plate, one side of the opening end of the U-shaped bracket is provided with a strip-shaped groove in a curve state, and the other side of the opening end of the U-shaped bracket is provided with a strip-shaped protrusion in a curve state, wherein the strip-shaped groove corresponds to the strip-shaped protrusion in position;

an elastic module is arranged on the U-shaped bracket, wherein the strip-shaped groove is formed in the elastic module;

the two positioning and clamping assemblies are respectively positioned at two sides of the lock catch assembly, and can move along the vertical direction of the frame to clamp the transverse ribs on the frame structure so as to force the butt joint parts on the left transverse rib and the right transverse rib to be aligned;

the two positioning butt joint assemblies are respectively and correspondingly positioned at one side of the positioning clamping assembly and are used for positioning the butt joint of the frame structure and realizing nested butt joint of the frame structure at the butt joint;

wherein the positioning butt-joint assembly can move along the horizontal direction of the frame;

the locking mechanism further comprises a bottom frame assembly, two sides of the bottom frame assembly are respectively provided with a guide rail, wherein the frame is arranged on the bottom frame assembly, and a trolley assembly is arranged on the guide rails and used for receiving the butted and pressed frame structure.

2. The mesh docking and compression latch mechanism of claim 1 wherein the distance between the slide adjacent to the ground is greater than the distance between any two other adjacent slide among the plurality of slide structures.

3. The mesh docking and compression latch mechanism according to claim 1, wherein the positioning and clamping assembly comprises a pneumatic structure mounted on the frame and a clamping structure connected to the pneumatic structure, wherein the clamping structure comprises two positioning plates arranged up and down, and two clamping members are arranged side by side between the two positioning plates, wherein one clamping member is fixedly connected between the two positioning plates, and the other clamping member is connected to the pneumatic structure.

4. The mesh docking and compacting latch mechanism according to claim 3, wherein the clamping members fixedly connected to the positioning plate are first clamping members, the clamping members connected to the pneumatic structure are second clamping members, the first clamping members comprise positioning support mounting members and are detachably connected to a plurality of positioning support members on the positioning support mounting members along the length direction of the positioning support mounting members, the second clamping members comprise positioning press block mounting members and are detachably connected to a plurality of positioning press blocks on the positioning press block mounting members along the length direction of the positioning press block mounting members, and the positioning press blocks are arranged at intervals with the positioning support members.

5. The mesh docking and compression latch mechanism according to claim 4 wherein the surface of the positioning support opposite the positioning press is planar and the surface of the positioning press opposite the positioning support is concave.

6. The mesh docking and compression latch mechanism according to claim 1, wherein the positioning docking assembly comprises a docking bracket slidably coupled to the frame, and a sliding module is disposed on the docking bracket, wherein a plurality of positioning seats are disposed along a length direction of the sliding module, and a pair of positioning frames are disposed on each positioning seat.

7. The mesh docking and compression latch mechanism according to claim 6, wherein two separators are disposed on one side of the sliding module and are respectively disposed at two ends of the docking bracket, and wherein a second cylinder is disposed on the docking bracket on the same side as the separators.