CN115256302A

CN115256302A - Snowboard multipoint type pressing equipment based on ice and snow project

Info

Publication number: CN115256302A
Application number: CN202210861689.1A
Authority: CN
Inventors: 胡海涛
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-07-22
Filing date: 2022-07-22
Publication date: 2022-11-01

Abstract

The invention relates to the field of ice and snow projects, in particular to a multi-point type snowboard pressing device based on the ice and snow projects. The technical problem is that: nuclear core block does not carry out the normal position to timber group before the pressfitting, leads to nuclear core block to appear the dislocation, and the glue that will overflow simultaneously in time strikes off, leads to glue to bond lateral wall all around, influences the later stage and uses, and is difficult to the bubble discharge between the glue. The technical scheme is as follows: a snowboard multipoint type pressing device based on an ice and snow project comprises support legs, a bearing plate and the like; two support legs are arranged; the upper parts of the two support legs are fixedly connected with a bearing plate. The invention realizes the righting of the materials used by the placed core block, thereby preventing the dislocation of the formed core block, then carrying out multi-point type pressing on the materials used by the core block, discharging bubbles generated among glue water in time, avoiding the occurrence of gaps, scraping redundant glue water after pressing, and scraping burrs at the edges of four sides, thereby improving the quality of finished products and avoiding influencing later use.

Description

Snowboard multi-point type pressing equipment based on ice and snow project

Technical Field

The invention relates to the field of ice and snow projects, in particular to a multi-point type snowboard pressing device based on the ice and snow projects.

Background

The snowboard is a skiing sports apparatus, in the production and processing of the snowboard, a core block in the snowboard is firstly required to be prepared, the core block of the snowboard is generally formed by overlapping two or more kinds of woods, glue is coated between two adjacent woods, so that a plurality of woods are overlapped and formed, and then the overlapped and formed wood group is required to be placed at a pressure holding jig to be pressed and fixed, so that the required core block is prepared;

however, the existing snowboard pressure maintaining jig generally adopts a mode that a plurality of screws are connected with a pressing block to press, hold and fix the overlapped and spliced wood group, the overlapped and spliced wood group is placed on a corresponding station, and the pressing block moves towards the direction of the overlapped and spliced wood group by rotating each screw, so that the pressing block is pressed and held on the overlapped and spliced wood group, and thus, the stress of the wood group is uneven when the wood group is pressed, held and fixed, and gaps are formed among the compressed and fixed woods;

and the mode that removes in opposite directions through last pressfitting board and lower pressfitting board among the prior art avoids the atress uneven and the problem that the gap appears, but at this in-process, because do not carry out normal position processing to timber group before the pressfitting, and then very easily lead to the dislocation phenomenon to appear in the nuclear core block after the shaping, and simultaneously, because the coating has glue between the timber, and then cause timber group when the pressfitting, there is a large amount of glue to spill over, and among the prior art, the glue that will spill over in time strikes off, lead to glue will bond the lateral wall all around at timber group, thereby very big reduction the finished product quality, influence later stage use simultaneously, and through the mode that last pressfitting board and lower pressfitting board moved in opposite directions, be difficult to discharge the bubble that produces between the glue, and then lead to appear the gap between the timber group, and the existence in the space very easily makes the inside bearing capacity of piece receive serious influence, constitute the core-breaking phenomenon to appear even, and then very big influence later stage use.

In summary, there is a need to develop a multi-point snowboard stitching apparatus for snow and ice projects to overcome the above problems.

Disclosure of Invention

The invention provides a multi-point type snowboard stitching device based on an ice and snow project, aiming at overcoming the defects that the core block is staggered due to the fact that a wood group is not righted before stitching, meanwhile, overflowed glue is not scraped in time, the glue is bonded on the peripheral side walls, later use is affected, and air bubbles among the glue are difficult to discharge.

The technical scheme of the invention is as follows: a snowboard multi-point type pressing device based on an ice and snow project comprises support legs, a bearing plate, a baffle plate, a pressing unit, a glue scraping unit and a position correcting unit; two support legs are arranged; the upper parts of the two support legs are fixedly connected with a bearing plate; the front part and the rear part of the upper surface of the bearing plate are fixedly connected with a baffle plate; a pressing unit for pressing the core block of the snowboard in a multi-point mode is connected between the two baffles; the pressing unit is connected with the bearing plate; the middle part of the upper surface of the bearing plate is connected with a glue scraping unit used for scraping off redundant glue between core blocks of the snowboard; the glue scraping unit is connected with the pressing unit; the lower part of the pressing unit is connected with a correcting unit for correcting the core block of the snowboard; the righting unit is connected with the glue scraping unit.

As an improvement of the scheme, the pressing unit comprises a cover plate, a pressurizing plate, a T-shaped frame, a first electric sliding rail, a first electric sliding block, a first fixing frame, a first fixing block, a connecting plate, a circular ring, a pressurizing rod and a spring; a cover plate is fixedly connected between the two baffle plates; the lower part of the cover plate is fixedly connected with a pressurizing plate; a T-shaped frame is fixedly connected to the opposite sides of the two baffles; the two T-shaped frames are fixedly connected with the bearing plate; the upper parts of the two T-shaped frames are fixedly connected with a first electric slide rail; a first electric sliding block is connected to each of the two first electric sliding rails in a sliding manner; two opposite sides of the first electric sliding blocks are fixedly connected with a first fixing frame; two opposite sides of the first fixing frames are fixedly connected with a first fixing block; a connecting plate is fixedly connected between the two first fixed blocks; a plurality of circular rings are fixedly connected to the middle part of the connecting plate at equal intervals; the middle part of each circular ring is connected with a pressurizing rod in a sliding way; a spring is fixedly connected between each circular ring and each pressurizing rod; the cover plate, the two T-shaped frames and the two first fixing frames are all connected with the position correcting unit; the connecting plate is connected with the frictioning unit.

As an improvement of the above scheme, the glue scraping unit comprises a first fixing plate, a placing plate, a first telescopic rod, a first bucket, a second fixing plate and a guide plate; the rectangular four corners of the upper surface of the bearing plate are fixedly connected with a first fixing plate respectively; a placing plate is fixedly connected among the four first fixing plates; two first telescopic rods are fixedly connected to the lower surface of the connecting plate; the two first telescopic rod telescopic parts are fixedly connected with a first bucket; a second fixing plate is fixedly connected to the middle of the lower surface of the placing plate; a guide plate is fixedly connected to the left part and the right part of the placing plate respectively; the placing plate and the second fixing plate are both connected with the righting unit.

As an improvement of the above scheme, the front part and the rear part of the placing plate are respectively provided with a through groove for the outflow of the excessive glue.

As the improvement of above-mentioned scheme, first scraper bowl is inside to be opened there is the through groove for unnecessary glue flows out, and shovels in the first scraper bowl and move the portion and set up comparatively acutely, is used for shoveling the burr with the border part when shoveling glue.

As an improvement of the scheme, the middle part of the guide plate is provided with an inclined plane for guiding redundant glue.

As an improvement of the above scheme, the righting unit comprises a second electric slide rail, a second electric slide block, a second fixed frame, a first connecting rod, a second telescopic rod, a second fixed block, a third fixed plate, a first extrusion plate, a second bucket, a fourth fixed plate, a first rack, a first transmission shaft, a straight gear, a second transmission shaft, a column gear, a second connecting rod, a second rack, a flow guide block, a bidirectional screw rod, a fixed rod, a fifth fixed plate, a telescopic plate and a second extrusion plate; a second electric slide rail is fixedly connected to the left part and the right part of the lower surface of the cover plate respectively; a second electric sliding block is connected to each of the two second electric sliding rails in a sliding manner; the lower surfaces of the two second electric sliding blocks are fixedly connected with a second fixing frame; the lower surfaces of the two second fixing frames are fixedly connected with a first connecting rod; the lower parts of the two first connecting rods are fixedly connected with a second telescopic rod; the upper surfaces of the telescopic parts of the two second telescopic rods are fixedly connected with a second fixed block; the left ends and the right ends of the two second fixed blocks are fixedly connected with a third fixed plate respectively, and the two left and right adjacent third fixed plates form a group; two first extrusion plates are fixedly connected to opposite sides of the two groups of third fixing plates respectively, and the two first extrusion plates which are adjacent to each other on the left and right are a group; a second bucket is fixedly connected to the telescopic parts of the two second telescopic rods; the two second buckets are fixedly connected with a second fixing block respectively; the lower parts of the two first fixing frames are fixedly connected with a fourth fixing plate; the lower surfaces of the two fourth fixing plates are fixedly connected with a first rack; the lower parts of the two T-shaped frames are rotationally connected with a first transmission shaft; a straight gear is fixedly connected to the middle parts of the two first transmission shafts; the two straight gears are respectively meshed with a first rack; the lower parts of the two T-shaped frames and the lower part of the first transmission shaft are both rotatably connected with a second transmission shaft; the middle parts of the two second transmission shafts are fixedly connected with a column gear; the two column gears are respectively meshed with a straight gear; a second connecting rod is fixedly connected to the back sides of the two first racks; the lower parts of the two second connecting rods are fixedly connected with a second rack; the front part and the rear part of the lower surface of the placing plate are respectively fixedly connected with a flow guide block; the upper parts of the two flow guide blocks are rotationally connected with a bidirectional screw rod; the bidirectional screw rod is rotationally connected with the second fixing plate; the bidirectional screw rod is fixedly connected with the two second transmission shafts; the lower parts of the two diversion blocks are fixedly connected with a fixed rod; the fixed rod is fixedly connected with the second fixed plate; the front part and the rear part of the bidirectional screw rod are respectively screwed with a fifth fixing plate; the two fifth fixing plates are both connected with the fixing rod in a sliding manner; the upper parts of the two fifth fixing plates are fixedly connected with a telescopic plate; and the two telescopic parts of the telescopic plates are fixedly connected with a second extrusion plate.

As an improvement of the scheme, the upper part of the flow guide block is arc-shaped and used for guiding redundant glue and preventing the glue from flowing on the outer annular surface of the bidirectional screw rod.

As an improvement of the scheme, one side of the first extrusion plate, which is far away from the third fixing plate, is provided with a rubber anti-slip strip.

As the improvement of the scheme, one side of the second extrusion plate, which is far away from the expansion plate, is provided with a rubber anti-slip strip.

The invention has the beneficial effects that: the invention realizes the righting of the materials used by the placed core blocks, thereby preventing the dislocation of the formed core blocks, then carries out multi-point type pressing on the materials used by the core blocks, and timely discharges bubbles generated among glue water, thereby avoiding the occurrence of gaps, and simultaneously scrapes off the redundant glue water extruded after the pressing and scrapes burrs on the edges of four sides, thereby improving the quality of finished products and avoiding influencing the later use.

Drawings

FIG. 1 shows a first perspective view of a multi-point snowboard binding apparatus for snow and ice based projects according to the present invention;

FIG. 2 is a schematic view of a second perspective of the multi-point snowboard binding apparatus for snow and ice projects of the present invention;

FIG. 3 is a schematic view showing a first three-dimensional configuration of a pressing unit of the multi-point snowboard pressing device for snow and ice projects according to the present invention;

FIG. 4 is a second perspective view of a pressing unit of the multi-point snowboard pressing device for snow and ice projects according to the present invention;

FIG. 5 is a schematic view of a first partial perspective structure of a binding unit of a multi-point binding apparatus for snowboards used in snow and ice projects according to the present invention;

FIG. 6 is a schematic view showing a second partial perspective structure of a pressing unit of the multi-point snowboard pressing device for snow and ice projects according to the present invention;

FIG. 7 is a schematic view of a first three-dimensional configuration of a glue scraping unit of the snowboard multi-point type binding apparatus for snow and ice projects according to the present invention;

FIG. 8 is a schematic view showing a second three-dimensional configuration of a glue scraping unit of the multi-point ski binding apparatus for snow and ice projects according to the present invention;

FIG. 9 is a schematic view showing a first partial perspective structure of a glue scraping unit of the multi-point ski binding apparatus for snow and ice projects according to the present invention;

FIG. 10 is a partial exploded view of a glue scraping unit of the multi-point snowboard stitching apparatus for snow and ice projects according to the present invention;

FIG. 11 is a schematic perspective view of a second partial structure of the glue scraping unit of the multi-point ski binding apparatus for ice and snow events according to the present invention;

FIG. 12 is a schematic perspective view of a positioning unit of the snowboard multi-point binding apparatus for snow and ice projects according to the present invention;

FIG. 13 is a schematic view of a first partial perspective configuration of a righting unit of a snowboard multi-point binding apparatus for snow and ice projects in accordance with the present invention;

FIG. 14 is a schematic view of a second partial perspective view of a righting unit of the snowboard multi-point binding apparatus for snow and ice projects;

FIG. 15 is a third schematic partial perspective view of a righting unit of the snowboard multi-point binding apparatus for snow and ice projects according to the present invention;

fig. 16 is a schematic perspective view of a fourth partial structure of a righting unit of the snowboard multi-point binding apparatus for snow and ice projects according to the present invention.

In the reference symbols: 1-support leg, 2-bearing plate, 3-baffle plate, 201-cover plate, 202-pressure plate, 203-T-shaped frame, 204-first electric sliding rail, 205-first electric sliding block, 206-first fixing frame, 207-first fixing block, 208-connecting plate, 209-circular ring, 210-pressure rod, 211-spring, 301-first fixing plate, 302-placing plate, 302 a-placing groove, 303-first telescopic rod, 304-first bucket, 304 a-shoveling part, 305-second fixing plate, 306-guide plate, 401-second electric sliding rail, 402-second electric sliding block, 403-second fixing frame, 404-first connecting rod, 405-second telescopic rod, 406-second fixing block, 407-third fixing plate, 408-first extrusion plate, 409-second bucket, 410-fourth fixing plate, 411-first rack, 412-first transmission shaft, 413-straight-tooth wheel, 414-second transmission shaft, 415-column gear, 416-second connecting rod, 417-second connecting rod, 418-second rack, 418-second fixing plate, 410-fourth fixing plate, 411-first extrusion plate, 412-first transmission shaft, 413-second extrusion plate, 422-bidirectional extrusion plate, and fifth telescopic rod.

Detailed Description

The invention is further described with reference to the following figures and detailed description.

Example 1

A snowboard multi-point type pressing device based on an ice and snow project is shown in figures 1-2 and comprises supporting legs 1, a bearing plate 2, a baffle 3, a pressing unit, a glue scraping unit and a righting unit; two support legs 1 are arranged; the upper parts of the two support legs 1 are fixedly connected with a bearing plate 2; the front part and the rear part of the upper surface of the bearing plate 2 are fixedly connected with a baffle plate 3; a pressing unit is connected between the two baffles 3; the pressing unit is connected with the bearing plate 2; the middle part of the upper surface of the bearing plate 2 is connected with a glue scraping unit; the glue scraping unit is connected with the pressing unit; the lower part of the pressing unit is connected with a position aligning unit; the righting unit is connected with the glue scraping unit.

When the snowboard is in work, a worker moves the bearing plate 2 and the two baffles 3 to the position to be used, the two support legs 1 are kept horizontal, then the worker places the materials used by the core block of the snowboard coated with glue in the glue scraping unit, wherein the materials used by the core block of the snowboard are formed by splicing and pressing two or more kinds of wood through glue, the materials used by the core block of the snowboard are called the core block for short, then the pressing unit operates and drives the righting unit to operate, the righting unit operates and righting the placed core block, therefore, the dislocation of the formed core block is prevented, then the righting pressing unit operates and carries out multi-point pressing on the core block, the transmission glue scraping unit operates and scrapes the redundant glue extruded after pressing, meanwhile, the glue scraping unit operates and scrapes burrs on the front side edge and the rear side edge of the core block simultaneously, the righting unit operates and scrapes the redundant glue and burrs on the left side edge and the right side edge of the core block, and finally, the core block is taken out by the worker.

Example 2

On the basis of embodiment 1, as shown in fig. 1 and fig. 3 to 16, the pressing unit includes a cover plate 201, a pressing plate 202, a T-shaped frame 203, a first electric slide rail 204, a first electric slide block 205, a first fixing frame 206, a first fixing block 207, a connecting plate 208, a ring 209, a pressing rod 210, and a spring 211; a cover plate 201 is fixedly connected between the two baffles 3; a pressure plate 202 is fixedly connected to the lower part of the cover plate 201; the opposite sides of the two baffles 3 are fixedly connected with a T-shaped frame 203; the two T-shaped frames 203 are fixedly connected with the bearing plate 2; the upper parts of the two T-shaped frames 203 are fixedly connected with a first electric slide rail 204; a first electric sliding block 205 is connected to each of the two first electric sliding rails 204 in a sliding manner; two opposite sides of the first electric sliding blocks 205 are fixedly connected with a first fixing frame 206; a first fixing block 207 is fixedly connected to the opposite sides of the two first fixing frames 206; a connecting plate 208 is fixedly connected between the two first fixing blocks 207; a plurality of rings 209 are fixedly connected in the middle of the connecting plate 208 at equal intervals; the middle part of each circular ring 209 is connected with a pressurizing rod 210 in a sliding way; a spring 211 is fixedly connected between each circular ring 209 and each pressurizing rod 210; the cover plate 201, the two T-shaped frames 203 and the two first fixing frames 206 are all connected with a positioning unit; the connecting plate 208 connects the squeegee units.

The glue scraping unit comprises a first fixing plate 301, a placing plate 302, a first telescopic rod 303, a first bucket 304, a second fixing plate 305 and a guide plate 306; the rectangular four corners of the upper surface of the bearing plate 2 are fixedly connected with a first fixing plate 301 respectively; a placing plate 302 is fixedly connected among the four first fixing plates 301; two first telescopic rods 303 are fixedly connected to the lower surface of the connecting plate 208; the telescopic parts of the two first telescopic rods 303 are fixedly connected with a first bucket 304; a second fixing plate 305 is fixedly connected to the middle of the lower surface of the placing plate 302; a guide plate 306 is fixedly connected to the left part and the right part of the placing plate 302 respectively; the placing plate 302 and the second fixing plate 305 are connected to the righting unit.

The placing plate 302 is provided with a through slot at the front and the rear for the outflow of excess glue.

The through groove is formed in the first bucket 304, so that redundant glue flows out, and the shoveling part 304a in the first bucket 304 is sharp and used for shoveling the glue and simultaneously shoveling burrs on the edge part.

The middle part of the guide plate 306 is provided with an inclined plane for guiding the redundant glue.

The righting unit comprises a second electric slide rail 401, a second electric slide block 402, a second fixing frame 403, a first connecting rod 404, a second telescopic rod 405, a second fixing block 406, a third fixing plate 407, a first extrusion plate 408, a second bucket 409, a fourth fixing plate 410, a first rack 411, a first transmission shaft 412, a straight gear 413, a second transmission shaft 414, a column gear 415, a second connecting rod 416, a second rack 417, a flow guide block 418, a bidirectional screw rod 419, a fixing rod 420, a fifth fixing plate 421, an expansion plate 422 and a second extrusion plate 423; a second electric slide rail 401 is fixedly connected to the left part and the right part of the lower surface of the cover plate 201 respectively; a second electric sliding block 402 is connected to each of the two second electric sliding rails 401 in a sliding manner; the lower surfaces of the two second electric sliding blocks 402 are fixedly connected with a second fixing frame 403; the lower surfaces of the two second fixing frames 403 are fixedly connected with a first connecting rod 404; the lower parts of the two first connecting rods 404 are fixedly connected with a second telescopic rod 405; the upper surfaces of the telescopic parts of the two second telescopic rods 405 are fixedly connected with a second fixed block 406; the left end and the right end of each of the two second fixed blocks 406 are fixedly connected with a third fixed plate 407, and the two left and right adjacent third fixed plates 407 form a group; two first extrusion plates 408 are fixedly connected to opposite sides of the two groups of third fixing plates 407, and the two first extrusion plates 408 adjacent to each other on the left and right are a group; a second bucket 409 is fixedly connected to the telescopic parts of the two second telescopic rods 405; the two second buckets 409 are fixedly connected with a second fixed block 406 respectively; a fourth fixing plate 410 is fixedly connected to the lower parts of the two first fixing frames 206; the lower surfaces of the two fourth fixing plates 410 are fixedly connected with a first rack 411; the lower parts of the two T-shaped frames 203 are rotatably connected with a first transmission shaft 412; a straight gear 413 is fixedly connected to the middle parts of the two first transmission shafts 412; two spur gears 413 each engaged with one first rack 411; a second transmission shaft 414 is rotatably connected to the lower parts of the two T-shaped frames 203 and below the first transmission shaft 412; a column gear 415 is fixedly connected to the middle parts of the two second transmission shafts 414; two spur gears 415 each mesh with one spur gear 413; a second connecting rod 416 is fixedly connected to the opposite sides of the two first racks 411; the lower parts of the two second connecting rods 416 are fixedly connected with a second rack 417; the front part and the rear part of the lower surface of the placing plate 302 are respectively fixedly connected with a flow guide block 418; the upper parts of the two flow guide blocks 418 are rotatably connected with a bidirectional screw rod 419; the bidirectional screw rod 419 is rotatably connected with the second fixing plate 305; the bidirectional screw rod 419 is fixedly connected with the two second transmission shafts 414; the lower parts of the two flow guide blocks 418 are fixedly connected with fixing rods 420; the fixing rod 420 is fixedly connected with the second fixing plate 305; the front part and the rear part of the bidirectional screw rod 419 are respectively screwed with a fifth fixing plate 421; the two fifth fixing plates 421 are both slidably connected to the fixing rod 420; the upper parts of the two fifth fixing plates 421 are fixedly connected with a telescopic plate 422; two expansion plates 422 are fixedly connected with a second extrusion plate 423.

The upper part of the flow guide block 418 is arc-shaped and used for guiding redundant glue and preventing the glue from flowing on the outer annular surface of the bidirectional screw rod 419.

One side of the first pressing plate 408 away from the third fixing plate 407 is provided with a rubber anti-slip strip.

One side of the second extrusion plate 423 away from the expansion plate 422 is provided with a rubber anti-slip strip.

During operation, a worker places a core block coated with glue in the placement groove 302a, then the two first electric sliders 205 are started to move right along the two first electric sliding rails 204, the two first electric sliders 205 move to drive the two first fixing frames 206 to move, the two first fixing frames 206 move to drive the two first fixing blocks 207 and the two fourth fixing plates 410 to move synchronously, at this time, the two fourth fixing plates 410 move to drive the two first racks 411 to move right, the two first racks 411 move right to drive the two spur gears 413 to rotate, the two spur gears 413 rotate to drive the two column gears 415 to rotate in opposite directions, the two column gears 415 rotate to drive the two second transmission shafts 414 to rotate, the two second transmission shafts 414 rotate to drive the two second lead screws 419 to rotate, the two fifth fixing plates 421 rotate to drive the two telescopic plates 422 to move in opposite directions along the fixing rods 420, the two telescopic plates 422 move to drive the two second extrusion plates 423 to move in opposite directions, further, the front side and the rear side of the core block are aligned through the two second extrusion plates 423, the two second fixing plates 421 move to drive the two second extrusion plates 406 to move along the two second fixing frames 403, the two second extrusion rods 406, the two second extrusion plates 406 move to drive the two second fixing frames 403 to move, the two second extrusion plates 406 to move, the two second extrusion rods 405 move to drive the two second fixing frames 406, the two second extrusion plates 406 to move along the two second fixing frames 403, the two second extrusion plates 406, the two second extrusion rods 408, the two second extrusion plates 406, the front side and the rear side of the core block are aligned through the two groups of first extrusion plates 408, so that the placed core block is aligned through the two second extrusion plates 423 and the two groups of first extrusion plates 408, and dislocation of the molded core block is prevented;

then, after the core block is positioned, the two first fixing frames 206 move to drive the two first fixing blocks 207 to continuously move rightwards, at the moment, the two first fixing blocks 207 move to drive the connecting plate 208 to move rightwards, the connecting plate 208 moves to drive the plurality of rings 209 to move rightwards, the plurality of rings 209 move to drive the plurality of pressure rods 210 to move rightwards, at the moment, the plurality of pressure rods 210 move rightwards to touch the pressure plate 202 and move downwards under the extrusion of the pressure plate, so that the plurality of pressure rods 210 move downwards to extrude the core block and compress the plurality of springs 211, then the plurality of pressure rods 210 move to press the core block in a multi-point mode, meanwhile, the connecting plate 208 moves to drive the two first telescopic rods 303 to move, the two first telescopic rods 303 move to drive the two first buckets 304 to move, at the moment, the two first buckets 304 respectively move against the front side and the rear side of the core block, and then the two scraping parts 304a scrape off redundant glue squeezed glue after pressing, and scrape burrs along the front side and the rear side of the core block;

meanwhile, when the plurality of pressurizing rods 210 move to press the core block in a multi-point manner, the two first racks 411 continuously move rightward to be separated from the two straight gears 413, at this time, the two first racks 411 move to drive the two second connecting rods 416 to move, the two second connecting rods 416 move to drive the two second racks 417 to move, the second racks 417 move to be meshed with the two column gears 415, so that the two column gears 415 rotate, the two column gears 415 rotate to drive the two second transmission shafts 414 to rotate in opposite directions, the two second transmission shafts 414 rotate to drive the two-way screw rod 419 to rotate in opposite directions, the two-way screw rod 419 rotates in opposite directions to drive the two fifth fixing plates 421 to move in opposite directions, the two fifth fixing plates 421 move to drive the two expansion plates 422 to move in opposite directions, the two expansion plates 422 move to drive the two second extrusion plates 423 to move in opposite directions, so that the two second extrusion plates 423 move in opposite directions to be separated from the front side and the rear side of the core block, and further, the two first bucket 304 smoothly scrape off glue burrs and the burrs on the front side and the rear side of the core block;

meanwhile, when the glue and burrs on the front side and the rear side of the core block are scraped by the two first buckets 304, the two second electric sliders 402 are started to move forwards along the two second electric sliding rails 401, the two second electric sliders 402 move to drive the two second fixing frames 403 to move, the two second fixing frames 403 move to drive the two first connecting rods 404 to move, the two first connecting rods 404 move to drive all associated parts to move forwards, and then the two second buckets 409 are driven to move forwards, and further the two second buckets 409 scrape the redundant glue extruded after pressing, and scrape the burrs on the left side and the right side edges of the core block, at the moment, the scraped glue and burrs flow into the two guide plates 306, and then the glue and the burrs are guided to the two through grooves formed in the placing plate 302 by the two guide plates 306, and are collected by a worker, and finally the pressed core block is taken out by the worker.

Although embodiments of the present invention have been shown and described, it would be appreciated by those skilled in the art that changes may be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the claims and their equivalents.

Claims

1. A snowboard multipoint type pressing device based on an ice and snow project comprises support legs (1), a bearing plate (2) and a baffle plate (3); two support legs (1) are arranged; the upper parts of the two support legs (1) are fixedly connected with a bearing plate (2); the front part and the rear part of the upper surface of the bearing plate (2) are fixedly connected with a baffle plate (3); the device is characterized by also comprising a pressing unit, a glue scraping unit and a position correcting unit; a pressing unit for pressing the core block of the snowboard in a multi-point manner is connected between the two baffles (3); the pressing unit is connected with the bearing plate (2); the middle part of the upper surface of the bearing plate (2) is connected with a glue scraping unit used for scraping redundant glue between core blocks of the snowboard; the glue scraping unit is connected with the pressing unit; the lower part of the pressing unit is connected with a correcting unit for correcting the core block of the snowboard; the righting unit is connected with the glue scraping unit.

2. The snowboard multipoint press-fit device for snow and ice projects according to claim 1, wherein the press-fit unit comprises a cover plate (201), a pressure plate (202), a T-shaped frame (203), a first electric slide rail (204), a first electric slide block (205), a first fixing frame (206), a first fixing block (207), a connecting plate (208), a ring (209), a pressure rod (210) and a spring (211); a cover plate (201) is fixedly connected between the two baffle plates (3); a pressure plate (202) is fixedly connected to the lower part of the cover plate (201); the opposite sides of the two baffles (3) are fixedly connected with a T-shaped frame (203); the two T-shaped frames (203) are fixedly connected with the bearing plate (2); a first electric slide rail (204) is fixedly connected to the upper parts of the two T-shaped frames (203); a first electric sliding block (205) is connected to each of the two first electric sliding rails (204) in a sliding manner; two opposite sides of the first electric sliding blocks (205) are fixedly connected with a first fixing frame (206); two opposite sides of the first fixing frames (206) are fixedly connected with a first fixing block (207); a connecting plate (208) is fixedly connected between the two first fixed blocks (207); a plurality of circular rings (209) are fixedly connected with the middle part of the connecting plate (208) at equal intervals; the middle part of each circular ring (209) is connected with a pressurizing rod (210) in a sliding way; a spring (211) is fixedly connected between each circular ring (209) and each pressurizing rod (210); the cover plate (201), the two T-shaped frames (203) and the two first fixing frames (206) are all connected with a righting unit; the connecting plate (208) is connected with the glue scraping unit.

3. The snowboard multi-point binding apparatus for snow and ice projects as claimed in claim 2, wherein the glue scraping unit comprises a first fixing plate (301), a placing plate (302), a first telescopic rod (303), a first bucket (304), a second fixing plate (305) and a guide plate (306); four rectangular corners of the upper surface of the bearing plate (2) are fixedly connected with a first fixing plate (301) respectively; a placing plate (302) is fixedly connected among the four first fixing plates (301); two first telescopic rods (303) are fixedly connected to the lower surface of the connecting plate (208); the telescopic parts of the two first telescopic rods (303) are fixedly connected with a first bucket (304); a second fixing plate (305) is fixedly connected to the middle of the lower surface of the placing plate (302); a guide plate (306) is fixedly connected to the left part and the right part of the placing plate (302) respectively; the placing plate (302) and the second fixing plate (305) are both connected with the righting unit.

4. A snowboard multi-point binding apparatus for snow and ice projects according to claim 3, wherein the front and rear parts of the placing plate (302) are each provided with a through slot for excess glue to flow out.

5. A snowboard multipoint press fit device for snow and ice projects according to claim 3, characterized in that the first bucket (304) is internally provided with a through slot for excess glue to flow out, and the shoveling part (304 a) of the first bucket (304) is arranged to be relatively sharp for shoveling away glue and simultaneously shoveling away burrs at the edge part.

6. A multi-point snowboard binding apparatus for snow and ice projects as claimed in claim 3, wherein the deflector (306) has a slope in the middle for guiding excess glue.

7. The snowboard multipoint press-fit device for the ice and snow project according to claim 6, wherein the righting unit comprises a second electric slide rail (401), a second electric slide block (402), a second fixing frame (403), a first connecting rod (404), a second telescopic rod (405), a second fixing block (406), a third fixing plate (407), a first extrusion plate (408), a second bucket (409), a fourth fixing plate (410), a first rack (411), a first transmission shaft (412), a spur gear (413), a second transmission shaft (414), a column gear (415), a second connecting rod (416), a second rack (417), a flow guide block (418), a bidirectional screw rod (419), a fixing rod (420), a fifth fixing plate (421), an expansion plate (422) and a second extrusion plate (423); a second electric slide rail (401) is fixedly connected to the left part and the right part of the lower surface of the cover plate (201) respectively; a second electric sliding block (402) is connected to each of the two second electric sliding rails (401) in a sliding manner; the lower surfaces of the two second electric sliding blocks (402) are fixedly connected with a second fixing frame (403); the lower surfaces of the two second fixing frames (403) are fixedly connected with a first connecting rod (404); the lower parts of the two first connecting rods (404) are fixedly connected with a second telescopic rod (405); the upper surfaces of the telescopic parts of the two second telescopic rods (405) are fixedly connected with a second fixed block (406); the left end and the right end of each of the two second fixed blocks (406) are fixedly connected with a third fixed plate (407), and the two left and right adjacent third fixed plates (407) form a group; two first extrusion plates (408) are fixedly connected to opposite sides of the two groups of third fixing plates (407), and the two first extrusion plates (408) adjacent to each other on the left and right are a group; the telescopic parts of the two second telescopic rods (405) are fixedly connected with a second bucket (409); two second buckets (409) are fixedly connected with a second fixed block (406) respectively; the lower parts of the two first fixing frames (206) are fixedly connected with a fourth fixing plate (410); the lower surfaces of the two fourth fixing plates (410) are fixedly connected with a first rack (411); the lower parts of the two T-shaped frames (203) are respectively and rotatably connected with a first transmission shaft (412); a straight gear (413) is fixedly connected to the middle parts of the two first transmission shafts (412); two straight gears (413) are respectively meshed with a first rack (411); a second transmission shaft (414) is rotatably connected to the lower parts of the two T-shaped frames (203) and is positioned below the first transmission shaft (412); the middle parts of the two second transmission shafts (414) are fixedly connected with a column gear (415); two column gears (415) are respectively meshed with a straight gear (413); a second connecting rod (416) is fixedly connected to the back sides of the two first racks (411); the lower parts of the two second connecting rods (416) are fixedly connected with a second rack (417); the front part and the rear part of the lower surface of the placing plate (302) are respectively fixedly connected with a flow guide block (418); the upper parts of the two flow guide blocks (418) are rotationally connected with a bidirectional screw rod (419); the bidirectional screw rod (419) is rotationally connected with the second fixing plate (305); the bidirectional screw rod (419) is fixedly connected with the two second transmission shafts (414); the lower parts of the two flow guide blocks (418) are fixedly connected with a fixing rod (420); the fixed rod (420) is fixedly connected with the second fixed plate (305); the front part and the rear part of the bidirectional screw rod (419) are respectively screwed with a fifth fixing plate (421); the two fifth fixing plates (421) are both connected with the fixing rod (420) in a sliding manner; the upper parts of the two fifth fixing plates (421) are fixedly connected with a telescopic plate (422); the two expansion plates (422) are fixedly connected with a second extrusion plate (423).

8. A multi-point snowboard binding apparatus for snow and ice projects as claimed in claim 7, wherein the upper portion of the deflector block (418) is formed in an arc shape for guiding the excessive glue and preventing the glue from flowing around the outer circumferential surface of the two-way screw (419).

9. A multi-point snowboard binding apparatus for snow and ice projects as claimed in claim 7, wherein the first pressing plate (408) is provided with a rubber anti-slip strip on a side away from the third fixing plate (407).

10. A multi-point snowboard binding apparatus for snow and ice projects as claimed in claim 7, wherein the second pressing plate (423) is provided with a rubber anti-slip strip on a side away from the retractable plate (422).