CN114701030B

CN114701030B - Ski wood core processing equipment with prevent fracture

Info

Publication number: CN114701030B
Application number: CN202210244397.3A
Authority: CN
Inventors: 杨卉珠
Original assignee: Harbin Jingran Sports Technology Co ltd
Current assignee: Harbin Jingran Sports Technology Co ltd
Priority date: 2022-03-14
Filing date: 2022-03-14
Publication date: 2023-06-16
Anticipated expiration: 2042-03-14
Also published as: CN114701030A

Abstract

The invention relates to the field of snowboard machining, in particular to a snowboard wood core machining device with cracking prevention function. Technical problems: the wood core of the skis is generally formed by pressing wood chips, so that the wood core is often cracked and deformed when the wood core is pressed and deformed because the wood core is insufficiently soaked, and a large amount of time is consumed in conventional soaking operation, wherein holes in the wood core can influence the soaking degree of the wood core. The technical scheme is as follows: a kind of skis wood core processing equipment with cracking prevention, including shake the unit of positioning and self-tightening type fixing unit etc.; the middle part of the oscillating type positioning unit is connected with a self-tightening fixing unit. According to the invention, the snowboard wood core is fully vibrated in boiling water, so that the snowboard wood core is soaked by the boiling water more quickly, holes in the snowboard wood core can be treated, bubbles in the holes in the snowboard wood core can be removed, the boiling water can be heated and insulated, and the energy loss is reduced.

Description

Ski wood core processing equipment with prevent fracture

Technical Field

The invention relates to the field of snowboard machining, in particular to a snowboard wood core machining device with cracking prevention function.

Background

Skis are skiing sports equipment, and are generally divided into mountain boards, off-road winter two boards, jump boards, free boards, veneers and the like.

The snowboard needs to slide on the snow and can not be blocked, the front part of the snowboard needs to be bent appropriately, and the snowboard can be blocked by effectively avoiding obstacles, but because the wood core of the snowboard is generally formed by pressing wood chips, the wood core is often cracked and deformed due to insufficient infiltration of the wood core when the wood core is pressed and deformed, and a large amount of time is consumed in conventional infiltration operation to fully infiltrate the snowboard, bubbles remain in holes in the wood core, and the contact of water and the wood core is avoided, so that the infiltration degree of the wood core is affected.

In view of the above, there is a need to develop a snowboard wood core processing apparatus with crack protection to overcome the above problems.

Disclosure of Invention

In order to overcome the defects that a snowboard wood core is generally formed by pressing wood chips, and often because the wood core is insufficiently soaked, when the wood core is pressed and deformed, the wood core is cracked and deformed, and a large amount of time is consumed in conventional soaking operation, wherein holes in the wood core can influence the soaking degree of the wood core, the invention provides a snowboard wood core processing device with cracking prevention.

The technical scheme is as follows: a snowboard wood core processing device with anti-cracking function comprises a soaking box and a fixing buckle; the lower part of the front side and the lower part of the rear side of the infiltration box are respectively connected with two fixing buckles; the device also comprises an oscillating type position adjusting unit, a self-tightening type fixing unit, a heat preservation unit and a foam removing unit; the left part and the right part of the infiltration box are connected with oscillation type position adjusting units; the upper part of the infiltration box is connected with a heat preservation unit; the soaking box is internally connected with a bubble removing unit; the middle part of the oscillating type positioning unit is connected with a self-tightening type fixing unit; the middle part of the oscillating type position adjusting unit is connected with the heat preservation unit.

The oscillating type positioning unit comprises a vertical plate, an electric sliding rail, an I-shaped frame, a first support plate, a cross rod, a first sliding rod and a limiting plate; two vertical plates are fixedly connected to the left side and the right side of the infiltration box respectively through connecting plates; the upper parts of the opposite sides of the two vertical plates in front are respectively provided with an electric sliding rail; the upper parts of the opposite sides of the two vertical plates at the rear are respectively provided with an electric sliding rail; the four electric sliding rails are connected with an I-shaped frame in a sliding way through electric sliding blocks; the left part and the right part of the I-shaped frame are fixedly connected with two first support plates respectively; a cross rod is fixedly connected at the lower part between the two first support plates at the left side and the lower part between the two first support plates at the right side respectively; two first sliding rods slide on the two cross bars; the left part and the right part of the two first sliding rods are respectively provided with a limiting column; the lower surfaces of the two first sliding rods are connected with a self-tightening fixing unit; a limiting plate is fixedly connected to the left part of the inner bottom surface of the infiltration box and the right part of the inner bottom surface of the infiltration box respectively; the upper parts of the two limiting plates are respectively provided with a straight chute; the lower parts of the two limiting plates are respectively provided with an S chute; the left part and the right part of the two first slide bars are respectively connected with a limiting plate in a sliding way; the middle parts of the two limiting plates are connected with the heat preservation unit.

Further described, the lower parts of the two straight sliding grooves are respectively communicated with one S sliding groove.

Further, the self-tightening fixing unit comprises a second support plate, a transverse plate, a first clamping block, a second clamping block, a third support plate, a first elastic piece, a first L-shaped plate and a first connecting rod; four second support plates are fixedly connected to the lower surfaces of the two first slide bars at equal intervals respectively; a transverse plate is fixedly connected to the lower surfaces of every two second support plates respectively; the front part of the lower surface of the four transverse plates and the rear part of the lower surface are fixedly connected with a first clamping block respectively; the middle parts of the lower surfaces of the four transverse plates are respectively connected with a second clamping block in a sliding way; a third support plate is fixedly connected in the middle of the upper surfaces of the four transverse plates respectively; the upper parts of the left side and the upper parts of the right side of the four third support plates are fixedly connected with a first elastic piece respectively; the left side and the right side of the four second clamping blocks are fixedly connected with a first L-shaped plate respectively; the middle parts of the opposite sides of each two first L-shaped plates are fixedly connected with first connecting rods; the four first connecting rods are respectively connected with a third support plate in a sliding manner; the upper parts of the opposite sides of every two first L-shaped plates are fixedly connected with a first elastic piece respectively.

Further stated, the second clamping block is staggered from the first clamping block in the opening position, and the bayonet of the second clamping block is provided with an inclined plane.

Further described, the heat preservation unit comprises a baffle, a fourth support plate, an electric rotating shaft, a gear, a rack, a fifth support plate, a second elastic piece, a first sealing plate and a sixth support plate; the upper part of the infiltration box is connected with two baffles in a sliding way; the left part and the right part of the two baffles are respectively connected with a limiting plate in a sliding way; four corners of the upper surface of the infiltration box are fixedly connected with a fourth support plate respectively; an electric rotating shaft is rotatably connected to the upper part between the two front fourth support plates; an electric rotating shaft is rotatably connected to the upper part between the two rear fourth support plates; two gears are fixedly connected to the outer surfaces of the two electric rotating shafts respectively; a rack is respectively arranged at the left part of the upper surface and the right part of the upper surface of the two baffles; the four racks are respectively meshed with one gear; a fifth support plate is fixedly connected to the left part of the upper surface and the right part of the upper surface of each baffle; the opposite sides of the left two fifth support plates are fixedly connected with a second elastic piece respectively; the left part and the right part of the opposite sides of the two baffles are respectively provided with a sealing groove; the four sealing grooves are respectively connected with a first sealing plate in a sliding way; the rear parts of the upper surfaces of the front two first sealing plates are fixedly connected with a sixth support plate respectively; the front parts of the upper surfaces of the two first sealing plates at the rear are fixedly connected with a sixth support plate respectively; the four sixth support plates are fixedly connected with a second elastic piece respectively; the four sixth support plates are respectively in contact transmission with one first support plate; the middle parts of the opposite sides of the two baffles are respectively provided with a groove; four pressure relief chute are arranged at the front part of the baffle plate in front; four pressure relief chute are arranged at the rear part of the baffle at the rear part; each groove is respectively communicated with four pressure relief chute.

Further described, the openings of the two sets of pressure relief chutes are oppositely oriented.

Further stated, the bubble removal unit comprises a first U-shaped frame, a first bubble removal plate, a first T-shaped rod and a second bubble removal plate; five first U-shaped frames are fixedly connected in the middle of the inner bottom surface of the infiltration box at equal intervals; the upper parts of the opposite sides of the left and right first U-shaped frames are respectively provided with a first foam removing plate; two first foam removing plates are respectively arranged at the upper parts of the middle three first U-shaped frames; the middle parts of the five first U-shaped frames are fixedly connected with a first T-shaped rod respectively; the upper parts of the opposite sides of the left and right first T-shaped rods are fixedly connected with a second bubble removing plate respectively; two second bubble removing plates are fixedly connected to the upper parts of the middle three first T-shaped rods respectively.

Further, the opposite sides of the adjacent first foam removing plates are provided with fiber yarns which incline downwards; the opposite sides of the adjacent second bubble removing plates are provided with fiber filaments which incline upwards.

Further, the device also comprises a pressure relief unit; the front part and the rear part of the infiltration box are connected with pressure relief units; the opposite sides of the two baffles are connected with the pressure relief unit; the pressure relief unit comprises a third elastic piece, a second sliding rod, a disc, a second sealing plate, a second L-shaped plate, a second connecting rod and a fourth elastic piece; the middle part of the front side and the middle part of the rear side of the infiltration box are fixedly connected with a third elastic piece respectively; the opposite sides of the two third elastic pieces are fixedly connected with a second sliding rod respectively; the two second sliding rods respectively run through the middle of a third elastic piece; the two second sliding rods are both in sliding connection with the infiltration tank; two second slide bars are fixedly connected with a disc respectively on opposite sides; a second sealing plate is connected in each of the two grooves in a sliding way; four through grooves matched with the pressure relief chute are formed in the second sealing plate; the middle parts of the opposite sides of the two second sealing plates are fixedly connected with a second L-shaped plate respectively; the lower parts of the two second L-shaped plates are respectively in contact transmission with a second sliding rod; the upper parts of the left side and the right side of the two second L-shaped plates are fixedly connected with a second connecting rod respectively; the left parts of the opposite sides of the two second connecting rods at the left are fixedly connected with a fourth elastic piece respectively; the right parts of the opposite sides of the two second connecting rods on the right are fixedly connected with a fourth elastic piece respectively; the opposite sides of the left two fourth elastic pieces are fixedly connected with a baffle respectively; the opposite sides of the right two fourth elastic pieces are fixedly connected with a baffle respectively.

The beneficial effects of the invention are as follows: according to the invention, the snowboard wood core is fully vibrated in boiling water, so that the snowboard wood core is soaked by the boiling water more quickly, meanwhile, in the vibration process of the snowboard wood core, the preset holes in the snowboard wood core can be processed, bubbles in the holes in the snowboard wood core are removed, the soaking process of the snowboard wood core is quickened, and after the soaking is covered before the soaking of the snowboard wood core is started, the boiling water can be heated and insulated, so that the energy loss is reduced.

Drawings

FIG. 1 is a schematic perspective view of a snowboard wood core processing apparatus with crack control according to the present invention;

FIG. 2 is a cross-sectional view of a snowboard wood core processing apparatus having crack control according to the present invention;

FIG. 3 is a front view of a snowboard wood core processing apparatus having crack control according to the present invention;

FIG. 4 is a schematic view of a first partially assembled perspective view of a snowboard core processing apparatus having crack control according to the present invention;

FIG. 5 is a schematic view of a second partial perspective view of a snowboard wood core processing apparatus having a crack control feature according to the present invention;

FIG. 6 is a schematic perspective view of an oscillating positioning unit of a snowboard wood core processing device with crack prevention function according to the present invention;

FIG. 7 is a schematic perspective view of a self-tightening fastening unit of a snowboard wood core processing apparatus with crack prevention according to the present invention;

FIG. 8 is a schematic perspective view of a self-tightening fastening unit portion of a snowboard core processing apparatus having a crack prevention structure according to the present invention;

FIG. 9 is a schematic view of a third partial assembled perspective view of a snowboard wood core processing apparatus having crack control according to the present invention;

FIG. 10 is a schematic perspective view of a thermal insulation unit of a snowboard wood core processing apparatus with crack prevention according to the present invention;

FIG. 11 is a schematic view of a fourth partially assembled perspective view of a snowboard core processing apparatus having crack control according to the present invention;

FIG. 12 is a schematic perspective view of a bubble removal unit of a snowboard wood core processing apparatus having a crack prevention structure according to the present invention;

FIG. 13 is a schematic perspective view of a pressure relief unit of a snowboard core processing apparatus with crack control according to the present invention.

In the above figures: 1-infiltration box, 2-fixing buckle, 101-vertical plate, 102-electric slide rail, 103-I-shaped frame, 104-first support plate, 105-cross bar, 106-first slide bar, 107-limit plate, 107 a-I-shaped slide groove, 107b-S slide groove, 201-second support plate, 202-cross plate, 203-first clamping block, 204-second clamping block, 205-third support plate, 206-first elastic piece, 207-first L-shaped plate, 208-first connecting rod, 301-baffle plate, 302-fourth support plate, 303-electric rotating shaft, 304-gear, 305-rack, 306-fifth support plate, 307-second elastic piece, 308-first sealing plate, 309-sixth support plate, 301 a-groove, 301 b-sealing groove, 301 c-pressure release chute, 401-first U-shaped frame, 402-first foam removing plate, 403-first T-shaped rod, 404-second foam removing plate, 501-third elastic piece, 502-second sealing plate, 503-disc, 503-second connecting rod, 505-second L-fourth connecting rod, 507-fourth sealing plate.

Detailed Description

The invention will be further described with reference to specific examples, illustrative examples and illustrations of which are provided herein to illustrate the invention, but are not to be construed as limiting the invention.

In the embodiment of the present invention, the first elastic member 206, the second elastic member 307, the third elastic member 501 and the fourth elastic member 507 are all springs.

Example 1

A snowboard wood core processing device with cracking prevention function, according to the figures 1-3, comprises a soaking box 1 and a fixing buckle 2; the lower part of the front side and the lower part of the rear side of the infiltration box 1 are respectively connected with two fixing buckles 2; the device also comprises an oscillating type position adjusting unit, a self-tightening type fixing unit, a heat preservation unit and a foam removing unit; the left part and the right part of the infiltration box 1 are connected with oscillating type position adjusting units; the upper part of the infiltration box 1 is connected with a heat preservation unit; the soaking box 1 is internally connected with a bubble removing unit; the middle part of the oscillating type positioning unit is connected with a self-tightening type fixing unit; the middle part of the oscillating type position adjusting unit is connected with the heat preservation unit.

Before using the anti-cracking snowboard wood core processing equipment, the snowboard wood core processing equipment is called as the self-tightening type fixing unit, firstly, the soaking box 1 is fixed in a snowboard processing workshop through four fixing buckles 2, a power supply is externally connected, boiling water is led into the soaking box 1, the boiling water is heated and kept warm through the soaking box 1, the boiling water of the soaking box 1 is sealed and kept warm by a heat-preserving unit, then an operator transfers the snowboard wood core to the position of the self-tightening type fixing unit through a transfer mechanism in the workshop, the self-tightening type fixing unit respectively clamps and fixes the snowboard wood core, then the heat-preserving unit is opened, the oscillating type positioning unit downwards places the snowboard wood core through the self-tightening type fixing unit, when the snowboard wood core enters into the boiling water of the soaking box 1, the heat-preserving unit can move back and forth in the process of up and down reciprocating in the boiling water, the foam removing unit stamps holes on the snowboard wood core, and air bubbles are prevented from being separated from the holes of the snowboard wood core, and the soaking wood core is fully soaked in the process of up and down reciprocating movement; according to the invention, the snowboard wood core is fully vibrated in boiling water, so that the snowboard wood core is soaked by the boiling water more quickly, meanwhile, in the vibration process of the snowboard wood core, the preset holes in the snowboard wood core can be processed, bubbles in the holes in the snowboard wood core are removed, the soaking process of the snowboard wood core is quickened, and after the cover soaking is carried out before the soaking of the snowboard wood core is not started, the boiling water can be heated and insulated, so that the energy loss is reduced.

Example 2

On the basis of the embodiment 1, according to fig. 1 and fig. 4-6, the oscillating type positioning unit comprises a vertical plate 101, an electric sliding rail 102, an I-shaped frame 103, a first support plate 104, a cross rod 105, a first sliding rod 106 and a limiting plate 107; two vertical plates 101 are fixedly connected to the left side and the right side of the infiltration tank 1 through connecting plates respectively; the upper parts of the opposite sides of the two vertical plates 101 at the front are respectively provided with an electric sliding rail 102; the upper parts of the opposite sides of the two vertical plates 101 at the rear are respectively provided with an electric sliding rail 102; the four electric sliding rails 102 are connected with an I-shaped frame 103 in a sliding way through electric sliding blocks; two first support plates 104 are welded on the left part and the right part of the I-shaped frame 103 respectively; a cross bar 105 is welded at the lower part between the two first support plates 104 at the left side and the lower part between the two first support plates 104 at the right side respectively; two first slide bars 106 slide on the two cross bars 105; the left part and the right part of the two first sliding rods 106 are respectively provided with a limit column; the lower surfaces of the two first sliding rods 106 are connected with the self-tightening fixing units; the left part of the inner bottom surface and the right part of the inner bottom surface of the infiltration tank 1 are fixedly connected with a limiting plate 107 respectively; the upper parts of the two limiting plates 107 are respectively provided with a straight chute 107a; the lower parts of the two limiting plates 107 are respectively provided with an S chute 107b; the left part and the right part of the two first slide bars 106 are respectively connected with a limiting plate 107 in a sliding way; the middle parts of the two limiting plates 107 are connected with the heat preservation unit.

The lower parts of the two straight sliding grooves 107a are respectively communicated with one S sliding groove 107 b.

Referring to fig. 1 and 7 to 8, the self-tightening fixing unit includes a second support plate 201, a transverse plate 202, a first clamping block 203, a second clamping block 204, a third support plate 205, a first elastic member 206, a first L-shaped plate 207 and a first connecting rod 208; four second support plates 201 are welded on the lower surfaces of the two first slide bars 106 at equal intervals respectively; a transverse plate 202 is welded on the lower surfaces of each two second support plates 201; the front part of the lower surface and the rear part of the lower surface of the four transverse plates 202 are respectively welded with a first clamping block 203; the middle parts of the lower surfaces of the four transverse plates 202 are respectively connected with a second clamping block 204 in a sliding way; a third support plate 205 is welded in the middle of the upper surface of each of the four transverse plates 202; the upper left and right parts of the four third support plates 205 are fixedly connected with a first elastic piece 206 respectively; a first L-shaped plate 207 is welded on the left side and the right side of each of the four second clamping blocks 204; the middle parts of the opposite sides of each two first L-shaped plates 207 are welded with first connecting rods 208; the four first connecting rods 208 are respectively connected with a third support plate 205 in a sliding way; the upper parts of the opposite sides of each two first L-shaped plates 207 are fixedly connected with one first elastic piece 206.

The opening positions of the second clamping block 204 and the first clamping block 203 are staggered, and the bayonet of the second clamping block 204 is provided with an inclined plane.

Adaptive clamping stage: when an operator transfers the snowboard wood core to the lower parts of the four second clamping blocks 204, at this time, the snowboard wood core is arranged with the side faces upwards, the I-shaped frame 103 moves downwards through the four electric sliding blocks on the four electric sliding rails 102, the I-shaped frame 103 drives the four first supporting plates 104 to drive the two cross bars 105 to move downwards, the two cross bars 105 drive the two first sliding bars 106 to drive the four second supporting plates 201 to move downwards, each of the two second supporting plates 201 drives one transverse plate 202 to move downwards, the four transverse plates 202 drive the two first clamping blocks 203 and one second clamping block 204 to move downwards, when each of the two first clamping blocks 203 and one second clamping block 204 contact the wood core, the upper parts of the second clamping blocks 204 slide on the transverse plates 202 after the inclined surfaces on the clamping ports contact the snowboard wood core, at this time, the second clamping blocks 204 drive the two first L-shaped plates 207 to move, at this time, one first elastic piece 206 is stretched, the other first elastic piece 206 is compressed, and the wood core is fixed by the two first clamping blocks 203 and the two second clamping blocks 203 in a fixing mode.

Vibration type snowboard wood core infiltration stage: after the fixation of the snowboard wood core is completed, the transferring mechanism withdraws from the lower part of the second clamping block 204, then the I-shaped frame 103 moves downwards at the four electric sliding rails 102 through the four electric sliding blocks, the snowboard wood core is synchronously driven to move downwards, when the snowboard wood core enters into boiling water of the infiltration box 1, two ends of the first sliding rod 106 enter into the position of the S sliding groove 107b, along with the continuous downwards movement of the I-shaped frame 103, the first sliding rod 106 moves downwards along the S sliding groove 107b in an S shape, the periodic oscillation of the snowboard wood core in the boiling water is realized, the snowboard wood core is convenient to fully contact with the boiling water, the infiltration process of the snowboard wood core is accelerated, after the snowboard wood core contacts with the bottom of the infiltration box 1, the I-shaped frame 103 moves upwards at the four electric sliding rails 102 through the four electric sliding blocks, the oscillation of the snowboard wood core is carried out in the boiling water again, the infiltration efficiency of the snowboard wood core is effectively improved, after the infiltration of the snowboard wood core is completed, the I-shaped frame 103 continues to move upwards, the snowboard wood core is synchronously driven to withdraw from the infiltration box 1, and then the worker moves away from the infiltration box 1.

According to fig. 1 and 9-10, the heat preservation unit comprises a baffle 301, a fourth support plate 302, an electric rotating shaft 303, a gear 304, a rack 305, a fifth support plate 306, a second elastic member 307, a first sealing plate 308 and a sixth support plate 309; the upper part of the infiltration tank 1 is connected with two baffles 301 in a sliding way; the left part and the right part of the two baffles 301 are respectively connected with a limiting plate 107 in a sliding way; four corners of the upper surface of the infiltration tank 1 are welded with a fourth support plate 302 respectively; an electric rotating shaft 303 is rotatably connected to the upper part between the front two fourth support plates 302; an electric rotating shaft 303 is rotatably connected to the upper part between the two rear fourth support plates 302; two gears 304 are fixedly connected to the outer surfaces of the two electric rotating shafts 303 respectively; a rack 305 is respectively arranged at the left part of the upper surface and the right part of the upper surface of the two baffles 301; four racks 305 each engage one of the gears 304; a fifth support plate 306 is fixedly connected to the left part of the upper surface and the right part of the upper surface of the two baffles 301 respectively; a second elastic piece 307 is fixedly connected to the opposite sides of the left two fifth support plates 306 respectively; the left part and the right part of the opposite sides of the two baffles 301 are respectively provided with a sealing groove 301b; the four sealing grooves 301b are respectively connected with a first sealing plate 308 in a sliding manner; a sixth support plate 309 is welded at the rear part of the upper surfaces of the front two first sealing plates 308; a sixth support plate 309 is welded at the front part of the upper surfaces of the rear two first sealing plates 308; four sixth support plates 309 are fixedly connected with one second elastic member 307 respectively; four sixth support plates 309 are in contact transmission with one first support plate 104 each; the middle parts of the opposite sides of the two baffles 301 are respectively provided with a groove 301a; four pressure relief chute 301c are arranged at the front part of the baffle 301 in front; four pressure relief chute 301c are arranged at the rear part of the rear baffle 301; each recess 301a communicates with four pressure relief chutes 301 c.

The openings of the two sets of pressure relief chutes 301c are facing opposite directions.

And (3) heat preservation: before the snowboard wood core is soaked, an operator injects boiling water into the soaking box 1, heats and keeps the temperature of the boiling water through an external heater, so that after the water temperature is prevented from falling, the soaking effect of the snowboard wood core is reduced, then two electric rotating shafts 303 are started, the two electric rotating shafts 303 drive two gears 304 to rotate, the rotating directions of the two electric rotating shafts 303 are opposite, the four gears 304 drive one rack 305 to move, the two racks 305 in front can drive one baffle 301 to move, the two racks 305 in the rear drive the other baffle 301 to move, the moving directions of the two baffles 301 are opposite, after the opposite sides of the two baffles 301 are contacted, the two electric rotating shafts 303 are closed, the upper part of the soaking box 1 is sealed by the two baffles 301, the heat is prevented from passing too fast, energy resources are effectively saved, when the snowboard wood core is required to be put into the soaking box 1, starting two electric rotating shafts 303, synchronously driving two baffle plates 301 to move in the direction away from each other, so that a snowboard wood core can pass through the middle of the two baffle plates 301, closing the two electric rotating shafts 303, after the snowboard wood core enters the infiltration box 1, starting the two electric rotating shafts 303, synchronously driving the two baffle plates 301 to move in the direction close to each other, respectively contacting four sixth support plates 309 with one first support plate 104, along with the movement of the two baffle plates 301 in the direction close to each other, compressing four second elastic pieces 307, enabling the four sixth support plates 309 to abut against the four first support plates 104, closing the two electric rotating shafts 303 after the two baffle plates 301 are contacted at opposite sides, wherein a gap between the two first support plates 104 at the same side is used for generating a large amount of water vapor in the process of vibrating and infiltrating the snowboard wood core, the two electric rotating shafts 303 are started after the wood core of the snowboard is soaked, the two baffle plates 301 are opened, the two electric rotating shafts 303 are closed, the wood core of the snowboard is withdrawn from the soaking box 1, the two electric rotating shafts 303 are started, the four second elastic pieces 307 are restored, the four second elastic pieces 307 respectively drive one sixth support plate 309 to move, the four sixth support plates 309 respectively drive one first sealing plate 308 to move, the four first sealing plates 308 seal grooves 301a for escaping water vapor on the baffle plates 301, then the two baffle plates 301 seal the soaking box 1, and when the water vapor reaches the pressure relief chute 301c, the water vapor is partially condensed and flows back into the soaking box 1 along the pressure relief chute 301c in the heating and heat preservation process.

Referring to fig. 1 and 11-12, the bubble removal unit includes a first U-shaped frame 401, a first bubble removal plate 402, a first T-bar 403, and a second bubble removal plate 404; five first U-shaped frames 401 are fixedly connected in the middle of the inner bottom surface of the infiltration tank 1 at equal intervals; the upper parts of the opposite sides of the left and right first U-shaped frames 401 are respectively provided with a first foam removing plate 402; two first foam removal plates 402 are respectively arranged at the upper parts of the middle three first U-shaped frames 401; a first T-shaped rod 403 is welded at the middle part of each of the five first U-shaped frames 401; the upper parts of the opposite sides of the left and right first T-shaped rods 403 are fixedly connected with a second foam removing plate 404 respectively; two second foam removal plates 404 are fixedly connected to the upper parts of the middle three first T-shaped rods 403 respectively.

The opposite sides of the adjacent first bubble removal plates 402 are provided with fiber yarns which incline downwards; the opposite side of the adjacent second bubble removal plate 404 is provided with upwardly inclined filaments.

The stage of removing bubbles of the wood core of the snowboard: when the snowboard wood core is immersed in boiling water in a vibration manner, the holes in the snowboard wood core are left with air residues, air bubbles can be formed in the holes of the snowboard wood core, the holes can separate the immersing process of the boiling water and the snowboard wood core, when the snowboard wood core is immersed in the boiling water, the left side and the right side of the snowboard wood core can be contacted with fiber bundles of two adjacent first bubble removal plates 402, the fiber bundles of the two adjacent first bubble removal plates 402 are adhered to the surface of the snowboard wood core, when the fiber bundles are contacted with the holes of the snowboard wood core, the air bubbles in the holes are punctured, so that the boiling water can infiltrate the holes of the snowboard wood core conveniently, the immersing process of the snowboard wood core is accelerated, and when the snowboard wood core is immersed in the boiling water again, air is reserved in the holes, the vibrating process of each time of the snowboard wood core is fixed, the snowboard wood core can be contacted with the fiber bundles of the first bubble removal plates 402, the immersing process of the holes of the wood core is removed, when the fiber bundles of the snowboard wood core are contacted with the surface of the snowboard wood core is completely, and the fiber bundles of the two sides of the snowboard core are removed by evaporating the fiber bundles after the two side of the snowboard core are contacted with the fiber bundles of the snowboard core, and the fiber bundles of the surface of the snowboard core is completely, and the fiber bundles of the surface of the snowboard core is completely and the fiber bundles of the fiber bundles are completely and the fiber bundles of the surface is completely and the fiber bundles of the fiber bundles.

Example 3

On the basis of embodiment 2, according to fig. 1 and 13, a pressure relief unit is further included; the front part and the rear part of the infiltration box 1 are connected with pressure relief units; the opposite sides of the two baffles 301 are connected with the pressure relief unit; the pressure relief unit comprises a third elastic piece 501, a second sliding rod 502, a disc 503, a second sealing plate 504, a second L-shaped plate 505, a second connecting rod 506 and a fourth elastic piece 507; a third elastic piece 501 is fixedly connected to the middle part of the front side and the middle part of the rear side of the infiltration tank 1 respectively; a second slide bar 502 is fixedly connected to the opposite sides of the two third elastic pieces 501 respectively; two second slide bars 502 each run through the middle of one third elastic piece 501; the two second slide bars 502 are both in sliding connection with the infiltration tank 1; two discs 503 are welded on the opposite sides of the two second slide bars 502 respectively; a second sealing plate 504 is slidably connected in each of the two grooves 301a; four through grooves matched with the pressure relief chute 301c are formed in the second sealing plate 504; a second L-shaped plate 505 is welded at the middle parts of the opposite sides of the two second sealing plates 504 respectively; the lower parts of the two second L-shaped plates 505 are respectively in contact transmission with one second sliding rod 502; a second connecting rod 506 is welded at the left upper part and the right upper part of the two second L-shaped plates 505 respectively; a fourth elastic piece 507 is fixedly connected to the left part of the opposite sides of the two second connecting rods 506 at the left side; the right parts of the opposite sides of the two right second connecting rods 506 are fixedly connected with a fourth elastic piece 507 respectively; the opposite sides of the left two fourth elastic pieces 507 are fixedly connected with one baffle 301 respectively; the opposite sides of the right two fourth elastic members 507 are fixedly connected with one baffle 301 respectively.

Pressure adjustment stage: in the heating and heat preservation process of boiling water in the infiltration tank 1, in order to avoid the concentration of a large amount of vapor in the infiltration tank 1, the pressure in the infiltration tank 1 is too high, when the snowboard wooden core is put into the infiltration tank 1, a large amount of vapor escapes, safety hazards are caused to operators, so when vapor in the infiltration tank 1 reaches a certain value, the vapor pushes two discs 503 to move in the direction away from each other, the two discs 503 respectively drive a second slide bar 502 to move, two third elastic pieces 501 are compressed, the two second slide bars 502 respectively contact with a second L-shaped plate 505, and respectively drive a second L-shaped plate 505 to move in the direction away from each other, four fourth elastic pieces 507 are compressed, after the through grooves of the second sealing plates 504 are matched and conducted with the pressure release chute 301c, the vapor in the infiltration tank 1 is prevented from escaping from the pressure release chute 301c, the two discs 503 respectively drive a second L-shaped plate 505 to move in the direction away from each other, two second sealing plates 505 are respectively driven by the two second L-shaped plates 505 to move in the direction away from each other, and the two elastic pieces 506 are simultaneously driven by the two elastic pieces 506 to move in the direction away from each other, and the two elastic pieces 506 are simultaneously restored, the two elastic pieces are simultaneously driven by the two elastic pieces 506 to move in the direction of the second sealing plates to move in the direction away from each other, and the second sealing plates are simultaneously, and the two elastic pieces are simultaneously driven by the two elastic pieces are respectively and the two elastic pieces are simultaneously driven to move in the pressure and move.

It is to be understood that the above description is intended to be illustrative only and is not intended to be limiting. Those skilled in the art will appreciate variations of the present invention that are intended to be included within the scope of the claims herein.

Claims

1. A snowboard wood core processing device with cracking prevention comprises a soaking box (1) and a fixing buckle (2); the lower part of the front side and the lower part of the rear side of the infiltration box (1) are respectively connected with two fixing buckles (2); the method is characterized in that: the device also comprises an oscillating type position adjusting unit, a self-tightening type fixing unit, a heat preservation unit and a foam removing unit; the left part and the right part of the infiltration box (1) are connected with oscillating type position adjusting units; the upper part of the infiltration box (1) is connected with a heat preservation unit; the soaking box (1) is internally connected with a bubble removing unit; the middle part of the oscillating type positioning unit is connected with a self-tightening type fixing unit; the middle part of the oscillating type position adjusting unit is connected with the heat preservation unit;

the oscillating type positioning unit comprises a vertical plate (101), an electric sliding rail (102), an I-shaped frame (103), a first support plate (104), a cross rod (105), a first sliding rod (106) and a limiting plate (107); two vertical plates (101) are fixedly connected to the left side and the right side of the infiltration box (1) respectively through connecting plates; the upper parts of the opposite sides of the two vertical plates (101) at the front are respectively provided with an electric sliding rail (102); the upper parts of the opposite sides of the two vertical plates (101) at the rear are respectively provided with an electric sliding rail (102); the four electric sliding rails (102) are connected with an I-shaped frame (103) in a sliding way through electric sliding blocks; the left part and the right part of the I-shaped frame (103) are fixedly connected with two first support plates (104) respectively; a cross rod (105) is fixedly connected between the lower part between the two first support plates (104) at the left side and the lower part between the two first support plates (104) at the right side; two first sliding rods (106) slide on the two cross bars (105); the left part and the right part of the two first sliding rods (106) are respectively provided with a limiting column; the lower surfaces of the two first sliding rods (106) are connected with a self-tightening fixing unit; the left part of the inner bottom surface and the right part of the inner bottom surface of the infiltration box (1) are fixedly connected with a limiting plate (107) respectively; the upper parts of the two limiting plates (107) are respectively provided with a straight chute (107 a); the lower parts of the two limiting plates (107) are respectively provided with an S chute (107 b); the left part and the right part of the two first slide bars (106) are respectively connected with a limiting plate (107) in a sliding way; the middle parts of the two limiting plates (107) are connected with the heat preservation unit;

the lower parts of the two straight sliding grooves (107 a) are respectively communicated with one S sliding groove (107 b).

2. A snowboard wood core processing apparatus having crack protection as claimed in claim 1, wherein: the self-tightening fixing unit comprises a second support plate (201), a transverse plate (202), a first clamping block (203), a second clamping block (204), a third support plate (205), a first elastic piece (206), a first L-shaped plate (207) and a first connecting rod (208); four second support plates (201) are fixedly connected to the lower surfaces of the two first slide bars (106) at equal intervals respectively; the lower surfaces of every two second support plates (201) are fixedly connected with a transverse plate (202) respectively; the front part of the lower surface and the rear part of the lower surface of the four transverse plates (202) are fixedly connected with a first clamping block (203) respectively; the middle parts of the lower surfaces of the four transverse plates (202) are respectively connected with a second clamping block (204) in a sliding way; a third support plate (205) is fixedly connected in the middle of the upper surfaces of the four transverse plates (202); the upper parts of the left side and the upper parts of the right side of the four third support plates (205) are fixedly connected with a first elastic piece (206) respectively; the left side and the right side of the four second clamping blocks (204) are fixedly connected with a first L-shaped plate (207) respectively; the middle parts of the opposite sides of every two first L-shaped plates (207) are fixedly connected with first connecting rods (208); the four first connecting rods (208) are respectively connected with a third support plate (205) in a sliding way; the upper parts of the opposite sides of each two first L-shaped plates (207) are fixedly connected with one first elastic piece (206).

3. A snowboard wood core processing apparatus having crack control as claimed in claim 2, wherein: the second clamping block (204) is staggered with the opening of the first clamping block (203), and the bayonet of the second clamping block (204) is provided with an inclined plane.

4. A snowboard wood core processing apparatus having crack control as claimed in claim 2, wherein: the heat preservation unit comprises a baffle plate (301), a fourth support plate (302), an electric rotating shaft (303), a gear (304), a rack (305), a fifth support plate (306), a second elastic piece (307), a first sealing plate (308) and a sixth support plate (309); the upper part of the infiltration box (1) is connected with two baffles (301) in a sliding way; the left part and the right part of the two baffles (301) are respectively connected with a limiting plate (107) in a sliding way; four corners of the upper surface of the infiltration box (1) are fixedly connected with a fourth support plate (302) respectively; an electric rotating shaft (303) is rotatably connected to the upper part between the front two fourth support plates (302); an electric rotating shaft (303) is rotatably connected to the upper part between the two rear fourth support plates (302); two gears (304) are fixedly connected to the outer surfaces of the two electric rotating shafts (303) respectively; a rack (305) is arranged at the left part of the upper surface and the right part of the upper surface of each baffle (301); four racks (305) are meshed with one gear (304) respectively; a fifth support plate (306) is fixedly connected to the left part of the upper surface and the right part of the upper surface of the two baffles (301) respectively; the opposite sides of the left two fifth support plates (306) are fixedly connected with a second elastic piece (307) respectively; the left part and the right part of the opposite sides of the two baffles (301) are respectively provided with a sealing groove (301 b); the four sealing grooves (301 b) are respectively connected with a first sealing plate (308) in a sliding way; the rear parts of the upper surfaces of the front two first sealing plates (308) are fixedly connected with a sixth support plate (309) respectively; the front parts of the upper surfaces of the two first sealing plates (308) at the rear are fixedly connected with a sixth support plate (309) respectively; the four sixth support plates (309) are fixedly connected with a second elastic piece (307) respectively; the four sixth support plates (309) are respectively in contact transmission with one first support plate (104); the middle parts of the opposite sides of the two baffles (301) are respectively provided with a groove (301 a); four pressure relief chute (301 c) are arranged at the front part of the baffle (301) at the front part; four pressure relief chute (301 c) are arranged at the rear part of the rear baffle (301); each groove (301 a) is respectively communicated with four pressure relief chute (301 c).

5. A snowboard wood core processing apparatus having crack control as claimed in claim 4, wherein: the openings of the two groups of pressure relief chute (301 c) are opposite.

6. A snowboard wood core processing apparatus having crack control as claimed in claim 4, wherein: the foam removing unit comprises a first U-shaped frame (401), a first foam removing plate (402), a first T-shaped rod (403) and a second foam removing plate (404); five first U-shaped frames (401) are fixedly connected in the middle of the inner bottom surface of the infiltration box (1) at equal intervals; the upper parts of the opposite sides of the left and right first U-shaped frames (401) are respectively provided with a first foam removing plate (402); two first foam removing plates (402) are respectively arranged at the upper parts of the middle three first U-shaped frames (401); the middle parts of the five first U-shaped frames (401) are fixedly connected with a first T-shaped rod (403) respectively; the upper parts of the opposite sides of the left and right first T-shaped rods (403) are fixedly connected with a second foam removing plate (404) respectively; two second foam removing plates (404) are fixedly connected to the upper parts of the middle three first T-shaped rods (403) respectively.

7. A snowboard wood core processing apparatus having crack control as claimed in claim 6, wherein: the opposite sides of the adjacent first bubble removal plates (402) are provided with fiber filaments which incline downwards; the opposite sides of the adjacent second bubble removing plates (404) are provided with fiber filaments which incline upwards.

8. A snowboard wood core processing apparatus having crack control as claimed in claim 6, wherein: the device also comprises a pressure relief unit; the front part and the rear part of the infiltration box (1) are connected with pressure relief units; the opposite sides of the two baffles (301) are connected with the pressure relief unit; the pressure relief unit comprises a third elastic piece (501), a second sliding rod (502), a disc (503), a second sealing plate (504), a second L-shaped plate (505), a second connecting rod (506) and a fourth elastic piece (507); the middle part of the front side and the middle part of the rear side of the infiltration box (1) are fixedly connected with a third elastic piece (501) respectively; the opposite sides of the two third elastic pieces (501) are fixedly connected with a second sliding rod (502) respectively; two second slide bars (502) each run through the middle of a third elastic piece (501); the two second slide bars (502) are both in sliding connection with the infiltration box (1); two second slide bars (502) are fixedly connected with a disc (503) at the opposite sides respectively; a second sealing plate (504) is connected in each of the two grooves (301 a) in a sliding way; four through grooves matched with the pressure relief chute (301 c) are formed in the second sealing plate (504); the middle parts of the opposite sides of the two second sealing plates (504) are fixedly connected with a second L-shaped plate (505) respectively; the lower parts of the two second L-shaped plates (505) are respectively in contact transmission with a second sliding rod (502); the upper parts of the left side and the right side of the two second L-shaped plates (505) are fixedly connected with a second connecting rod (506) respectively; the left parts of the opposite sides of the two second connecting rods (506) at the left are fixedly connected with a fourth elastic piece (507) respectively; the right parts of the opposite sides of the two second connecting rods (506) at the right side are fixedly connected with a fourth elastic piece (507) respectively; the opposite sides of the left two fourth elastic pieces (507) are fixedly connected with one baffle plate (301) respectively; the opposite sides of the right two fourth elastic pieces (507) are fixedly connected with one baffle plate (301) respectively.