CN112095538A

CN112095538A - Ice surface repairing device

Info

Publication number: CN112095538A
Application number: CN202010978649.6A
Authority: CN
Inventors: 程光南
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-09-17
Filing date: 2020-09-17
Publication date: 2020-12-18
Anticipated expiration: 2040-09-17
Also published as: CN112095538B; GB2590886A8; GB2590886B; GB202105531D0; GB2590886A

Abstract

The invention belongs to the field of ice surface repairing, and particularly relates to an ice surface repairing device which comprises an outer mounting frame, wherein three mounting rods are arranged on the lower part of the right end of the outer mounting frame, a transverse mounting plate is arranged in the middle of the left end of the outer mounting frame, the ice surface repairing device also comprises an ice drilling component, the ice drilling component comprises a driving motor, the driving motor is arranged on the lower part of the transverse mounting plate, and the ice drilling component drills an ice surface after being started; the water replenishing device is arranged at the lower parts of the three mounting rods and is used for replenishing water after a pit is dug on the ice surface; and the communicating pipe is connected with the ice drilling component and the water replenishing device. Can get prosthetic when drilling to the damaged department of ice surface, collect the ice cinder that drills out to turn into the warm water with it and later reuse in filling to the ice surface, energy saving and water resource.

Description

Ice surface repairing device

Technical Field

The invention belongs to the field of ice surface repairing, and particularly relates to an ice surface repairing device.

Background

Along with the improvement of the living standard of people, the movement modes pursued by people are more and more diversified, besides activities such as basketball, running and swimming, skating is also the choice of more and more people for movement, the requirement of the skating on the ice surface is high, once the ice surface is damaged such as pits, and safety accidents are easily caused, the traditional ice surface repairing machine is simple in structure and low in efficiency, energy is wasted, and meanwhile, water resources are wasted, so that the design of the ice surface repairing machine is very important for solving the problems.

Disclosure of Invention

The invention aims to solve the problems in the prior art, and provides an ice surface repairing machine which can collect drilled ice sand while drilling an ice surface and can reuse the collected ice sand after the collected ice sand is melted by heat absorption.

In order to achieve the purpose, the invention adopts the following technical scheme: the ice surface repairing device comprises an outer mounting frame, wherein three mounting rods are arranged on the lower portion of the right end of the outer mounting frame, a transverse mounting plate is arranged in the middle of the left end of the outer mounting frame, the ice surface repairing device further comprises an ice drilling component, the ice drilling component comprises a driving motor, the driving motor is arranged on the lower portion of the transverse mounting plate, and the ice drilling component drills an ice surface after being started;

the water replenishing device is arranged at the lower parts of the three mounting rods and is used for replenishing water after a pit is dug on the ice surface;

and the communicating pipe is connected with the ice drilling component and the water replenishing device.

The driving part of the integral device of the ice drilling part is a driving motor, the driving motor drives the ice drilling part to drill the ice surface, then the ice slag is absorbed, the communicating pipe is screwed through the driving motor, and the crushed ice slag is melted by using the waste heat of the driving motor and then is injected into the water supplementing device again for use. Not only be used for driving motor's heat dissipation with the ice sediment, can also be with the water reuse that becomes behind the ice sediment absorbed heat, the water economy resource promotes equipment life.

The ice drilling component further comprises a first gear, the first gear is arranged at the output end of the driving motor, the lower portion of the first gear is provided with an ice drilling outer cover, the ice drilling outer cover is fixedly connected with the mounting frame, the ice drilling outer cover is closed at the top and is provided with an opening at the lower portion, the ice drilling outer cover is inclined inwards from top to bottom, an axle sleeve is arranged in the middle of a top plate of the ice drilling outer cover, a rotating shell is arranged in the axle sleeve, a gear sleeve is arranged on the outer ring of the rotating shell, and the gear sleeve is in transmission with the first gear in a meshing mode. The axle sleeve with bore ice dustcoat fixed connection, rotate the shell and be connected with the axle sleeve rotation, when starting driving motor, driving motor drives first gear revolve, first gear with rotate the outside tooth meshing on the tooth cover of shell to the drive rotates the shell and rotates.

Rotate the shell middle part and be equipped with first sliding tray, first sliding tray link up towards the downside, be equipped with the sliding shaft that can reciprocating sliding in the first sliding tray, the sliding shaft upper end passes through the bellows with the rotation shell and is connected, sliding shaft lower extreme fixedly connected with secondary shaft, it is equipped with the rotation joint block to rotate the shell top, rotate the joint block and rotate the concentric setting of shell, rotate joint block, rotate shell, sliding shaft, the inside first through-hole that link up from top to bottom that is equipped with of secondary shaft. The rotary connecting block and the rotary shell are arranged in a rotating mode and can rotate relatively, and when the rotary shell rotates, the rotary connecting block does not rotate. The gas in the third communicating pipeline can blow gas to the lower space of the rotating shell through the first through hole. The design of the rotary connecting block ensures that the third communicating pipeline cannot be twisted along with the rotation of the rotary shell after being communicated with the rotary connecting block.

The second shaft lower extreme bilateral symmetry is equipped with two first hydraulic grooves, every first hydraulic groove is equipped with reciprocating sliding's hydraulic stem, every the hydraulic stem outer end rotates and is connected with bores the ice claw, every it is close to the hydraulic stem and bores the inner rotation that the ice claw rotated the junction and be connected with the head rod, every to bore the ice claw the head rod other end and second shaft bottom surface fixed connection, be equipped with the ring channel on the second shaft lateral wall, be equipped with the annular block in the ring channel, the annular block can rotate the second shaft relatively in the ring channel, bilateral symmetry is equipped with two rope hooks on the annular block, every be equipped with the connection rope on the rope hook. Before drilling the ice surface, the position of the ice drilling claw is adjusted according to the width and the shape of the ice surface to be drilled. When the drilling range is small, but when the ice surface with the deep drilling depth is drilled, the hydraulic rod is upwards sucked in the first hydraulic groove, the joint of the rear end of the ice drilling claw and the hydraulic rod is lifted, the ice drilling claw rotates downwards around the joint of the ice drilling claw and the first connecting rod towards the end of the second shaft axis, the downward inclination angle of the ice drilling claw is large, and the ice surface drilling capacity is strong. The annular block is arranged in the annular groove of the second shaft, and the annular block does not need to rotate when the second shaft rotates, but can lift along with the second shaft.

The connecting rope other end is equipped with the sliding door, the sliding door slides and sets up in the third sliding tray, the third sliding tray about pile up to set up on the slope side about the brill ice dustcoat, every third sliding tray up end with be equipped with first spring between the sliding door, penetrating connection shell around every third sliding tray outside is equipped with, every connect the shell external orifice and be equipped with second well shut pipe, every the second well shut pipe other end and upper end UNICOM of communicating pipe. The annular block on the second shaft moves downwards to drive the sliding door to move downwards, the first spring is stretched, and the height of an air suction opening formed by connecting the sliding door with the shell is reduced. The suction opening is smaller as the drilling depth of the ice surface is deeper, because the suction force is increased when the opening at the suction end is reduced and the same amount of air needs to be sucked under the condition that the suction force of the same pump is the same, so that the reduced opening can provide larger suction force and can suck the ice slag generated by drilling in a deeper position.

Bore ice dustcoat roof rear side and still be equipped with the second gear, the second gear with first gear engagement transmission, the second gear is kept away from axle center certain distance department and is equipped with a rotation connecting rod, the rotation connecting rod other end rotates with the cylinder push pedal to be connected, bore ice dustcoat roof right side and fixedly be equipped with cylinder shell, sliding seal connects in cylinder push pedal and the cylinder shell, cylinder shell end is equipped with first check valve, be connected with third communicating pipe on the first individual valve, third communicating pipe and rotation joint piece fixed connection, its inner tube and first through-hole UNICOM, cylinder shell end still is equipped with the second check valve. The first one-way valve is communicated with the third communicating pipe and is a one-way valve which unidirectionally gives air to the direction of the communicating pipe, and the second one-way valve is a one-way valve which unidirectionally gives air to the cylinder shell.

The middle part of the communicating pipe is spirally and circularly arranged on the outer side of the side wall of the driving motor. Every second that connects the shell and connect all is connected to communicating pipe and is located driving motor's top edge, later communicating pipe around driving motor design, bigger increase communicating pipe and driving motor's heat exchange, can give driving motor more comprehensive heat dissipation, make the more quick melting of the ice sediment in the communicating pipe simultaneously.

The moisturizing device includes the storage water tank body, storage water tank body fixed connection is three the installation pole lower part, storage water tank body upper portion is equipped with first pump, first pump input end is connected with communicating pipe, first pump output end even has fourth communicating pipe, fourth communicating pipe and the internal portion of storage water tank are connected, fourth communicating pipe end is equipped with the filter core, storage water tank body lower extreme is equipped with the delivery port, delivery port upper portion is equipped with the valve, storage water tank body lateral wall is equipped with the water filling port, storage water tank body upper portion is equipped with two blow vents. The wind blown out from the first pump can blow the water in the water storage tank body to prevent the water from being solidified, and the blown wind in the water storage tank body is finally discharged from the air vent. When the water is replenished at the pit position drilled on the ice surface, the water can be injected by only aligning the water outlet hole with the position needing water replenishment and opening the valve, and the valve is closed after the water injection is finished. Liquid water is subsequently solidified into ice surface, and materials such as liquid nitrogen can be used, so that the water surface can be quickly solidified.

In conclusion, the ice-making machine is simple in structure, can use the ice slag drilled on the ice surface for heat dissipation of the driving motor, can recycle water obtained by absorbing heat of the ice slag, saves water resources, and prolongs the service life of equipment.

When drilling, the size of the air suction opening can be automatically adjusted according to the drilling depth so as to adjust the suction force to the deeper part of the drilled ice surface

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a top view of the present invention;

FIG. 3 is a cross-sectional view taken at A-A of FIG. 2;

FIG. 4 is an enlarged view of a portion of FIG. 3 at D;

FIG. 5 is an enlarged view of a portion E of FIG. 3;

FIG. 6 is an enlarged view of a portion of FIG. 3 at F;

FIG. 7 is a side view of the present invention;

FIG. 8 is a cross-sectional view taken at B-B of FIG. 7;

fig. 9 is a perspective sectional view at C-C in fig. 7.

In the figure: the ice drilling device comprises an outer mounting frame 1, a mounting rod 2, a transverse mounting plate 3, an ice drilling component 5, a driving motor 501, a water supplementing device 6, a communication pipe 4, a first gear 502, an ice drilling outer cover 509, a shaft sleeve 527, a rotating shell 520, a gear sleeve 521, a first sliding groove 525, a sliding shaft 526, a telescopic hose 524, a second shaft 526, a rotating connecting block 522, a first through hole 529, a first hydraulic groove 533, a hydraulic rod 534, an ice drilling claw 535, a first connecting rod 536, an annular groove 556, an annular block 555, a rope hook 531, a connecting rope 511, a sliding door 513, a third sliding groove 510, a first spring 512, a connecting shell 508, a second communication pipe 503, a second gear 542, a rotating connecting rod 543, an air cylinder push plate 547, an air cylinder shell 545, a first one-way valve 505, a third communication pipe 504, a second one-way valve 546, a water storage tank body 602, a first pump 601, a fourth communication pipe 603, a filter core 604, a water outlet 606, a valve, Vent 608.

Detailed Description

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

As shown in fig. 1, the ice surface repairing device comprises an outer mounting frame 1, three mounting rods 2 are arranged on the lower portion of the right end of the outer mounting frame 1, a transverse mounting plate 3 is arranged in the middle of the left end of the outer mounting frame 1, the ice drilling component 5 comprises a driving motor 501, the driving motor 501 is arranged on the lower portion of the transverse mounting plate, and the ice drilling component drills an ice surface after being started;

the water replenishing device 6 is arranged at the lower parts of the three mounting rods 2, and water is replenished after the pit is dug on the ice surface;

and a communication pipe 4 and the communication pipe 4 are connected with an ice drilling component 5 and a water replenishing device 6.

The driving part of the integral device of the ice drilling part 5 is a driving motor 501, the driving motor drives the ice drilling part to drill the ice surface, then the ice slag is absorbed, the communicating pipe 4 spirally passes through the driving motor 501, and the crushed ice slag is melted by the waste heat of the driving motor 501 and then is injected into the water supplementing device again for use. Not only be used for driving motor 501's heat dissipation with the ice sediment, can also be with the water reuse that becomes behind the ice sediment absorbed heat, the water economy resource promotes equipment life.

As shown in fig. 3 and 4, the ice drilling component 5 further comprises a first gear 502, the first gear 502 is arranged at the output end of the driving motor 501, an ice drilling outer cover 509 is arranged on the lower portion of the first gear 502, the ice drilling outer cover 509 is fixedly connected with the mounting frame 1, the ice drilling outer cover 509 is closed at the top and is open at the lower portion, the ice drilling outer cover 509 inclines inwards from top to bottom, a shaft sleeve 527 is arranged in the middle of a top plate of the ice drilling outer cover 509, a rotating shell 520 is arranged in the shaft sleeve 527, a gear sleeve 521 is arranged on the outer ring of the rotating shell 520, and the gear sleeve 521 is in meshing. The axle sleeve 527 and the outer cover 509 of brill ice are fixed connection, rotate shell 520 and axle sleeve 527 and rotate and be connected, and when starting driving motor 501, driving motor 501 drives first gear and revolves 502 rotatoryly, and first gear 502 meshes with the tooth on the outside tooth cover 521 of rotation shell 520 to the drive rotates the shell and rotates.

As shown in fig. 3 and 4, a first sliding groove 525 is formed in the middle of the rotating housing 520, the first sliding groove 525 penetrates downward, a sliding shaft 526 capable of sliding back and forth is arranged in the first sliding groove 525, the upper end of the sliding shaft 526 is connected with the rotating housing 520 through a flexible hose 524, a second shaft 526 is fixedly connected to the lower end of the sliding shaft 526, a rotating joint block 522 is arranged at the top end of the rotating housing 520, the rotating joint block 522 and the rotating housing 520 are concentrically arranged, and a first through hole 529 penetrating up and down is formed in the rotating joint block 522, the rotating housing 520, the sliding shaft 526 and the second shaft 526. The first sliding groove 525 and the sliding shaft 526 in the rotating housing 520 are telescopic rod structures, and belong to the prior art, which are not described herein, the rotating joint block and the rotating housing are rotatably disposed and can rotate relatively, and when the rotating housing 520 rotates, the rotating joint block 522 does not rotate. The gas in the third communicating pipe 504 can blow the lower space of the rotary case 520 through the first through hole 529. The rotation joint 522 is designed such that the third communication channel 504 is not twisted by the rotation of the rotating housing 520 after communicating with the rotation joint 522.

As shown in fig. 4-6, two first hydraulic grooves 533 are symmetrically arranged at the lower end of the second shaft 526 left and right, each first hydraulic groove 533 is provided with a hydraulic rod 534 capable of sliding back and forth, the outer end of each hydraulic rod 534 is rotatably connected with an ice drilling claw 535, the inner end of each ice drilling claw 535, which is close to the rotary connection position of the hydraulic rod 534 and the ice drilling claw 535, is rotatably connected with a first connecting rod 536, the other end of each first connecting rod 536 is fixedly connected with the bottom surface of the second shaft 526, the side wall of the second shaft 526 is provided with an annular groove 556, an annular block 555 is arranged in the annular groove 556, the annular block 555 can rotate relative to the second shaft 526 in the annular groove 556, two rope hooks 531 are symmetrically arranged on the annular block 555, and. The first hydraulic tank 533 and the hydraulic rod 534 are hydraulic telescopic rod structures, and belong to the prior art, and are not described herein. Before drilling the ice surface, the position of the ice-drilling claws 535 are adjusted according to the width and shape of the drilled surface as required. When the drilling range is small but the drilling depth is deep, the hydraulic rod 534 is sucked upwards in the first hydraulic groove 534, the joint of the rear end of the ice drilling claw 535 and the hydraulic rod 534 is lifted, the ice drilling claw 535 rotates downwards around the joint of the ice drilling claw 535 and the first connecting rod 536 towards the end of the axis of the second shaft 526, and the downward inclination angle of the ice drilling claw is larger, so that the ice drilling capability is stronger. The ring 555 is disposed in the annular groove 556 of the second shaft 526 such that the ring 555 does not follow rotation of the second shaft 526 as it rotates, but can be raised and lowered along with the second shaft 526.

The other end of the connecting rope 511 is provided with a sliding door 513, the sliding door 513 is arranged in a third sliding groove 510 in a sliding manner, the left side and the right side of the third sliding groove 510 are stacked on the inclined side surfaces of the left side and the right side of the ice drilling outer cover 509, a first spring 512 is arranged between the upper end surface of each third sliding groove 510 and the sliding door 513, the outer side of each third sliding groove 510 is provided with a connecting outer shell 508 which is through from front to back, the outer opening of each connecting outer shell 508 is provided with a second communicating pipe 503, and the other end 3 of each second communicating pipe 50 is communicated with the upper end of the communicating pipe 4. When the second shaft 526 is going to drill downward to get ice, it is lowered relative to the rotating housing 520, and the ice-drilling housing 509 is at the original position, and the ring block 555 on the second shaft 526 moves downward to drive the sliding door 513 to move downward in the third sliding slot 510, stretching the first spring 512, and reducing the height of the air suction opening formed by the sliding door 510 connected with the housing 508. The suction opening is smaller as the drilling depth of the ice surface is deeper, because the suction force is increased when the opening at the suction end is reduced and the same amount of air needs to be sucked under the condition that the suction force of the same pump is the same, so that the reduced opening can provide larger suction force and can suck the ice slag generated by drilling in a deeper position.

As shown in fig. 8, a second gear 542 is further disposed on the rear side of the top plate of the ice drilling housing 509, the second gear 542 is in meshing transmission with the first gear 502, a rotary connecting rod 543 is disposed at a position of the second gear 542 away from the axis by a certain distance, the other end of the rotary connecting rod 543 is rotatably connected with a cylinder push plate 547, a cylinder housing 545 is fixedly disposed on the right side of the top plate of the ice drilling housing 509, the cylinder push plate 547 is slidably and hermetically connected with the cylinder housing 545, a first one-way valve 505 is disposed at the end of the cylinder housing 545, a third communicating pipe 504 is connected to the first one-way valve 505, the third communicating pipe 504 is fixedly connected with the rotary connecting block 522, an inner pipe thereof is communicated with the first through hole 529, and a second. Driving motor 501 drives first gear 502 and rotates, thereby when driving gear sleeve 521 pivoted, can also rotate with second gear 542 meshing, it carries out eccentric rotation around the centre of a circle of second gear 542 to drive the connecting rod 543 that rotates, thereby drive and rotate the cylinder push pedal 547 that the connecting rod 543 end rotates and is connected in the cylinder up-and-down motion, intermittent type nature is blowing in third communicating pipe 504, gas blows to the brill ice part of brill ice claw through first through-hole 529, can make the ice sediment in small bits blown up, can be better absorb in the inlet scoop that is formed by sliding door 513 and connection shell 508. The first check valve 505 is communicated with the third communication pipe 504, and is a check valve that discharges air in one direction to the communication pipe, and the second check valve 546 is a check valve that discharges air in one direction to the cylinder case 545.

The middle part of the communicating pipe 4 is spirally and circularly arranged outside the side wall of the driving motor 501. Second communicating pipe 503 connected to each connection housing 508 is connected to the upper portion of communicating pipe 4 located on driving motor 501, and then communicating pipe 508 is designed around driving motor 501, so that heat exchange between communicating pipe 508 and driving motor 501 is increased more, more comprehensive heat dissipation can be provided for driving motor 501, and meanwhile, ice slag in communicating pipe 508 is melted more quickly.

As shown in fig. 3 and 9, the water replenishing device 6 includes a water storage tank 602, the water storage tank 602 is fixedly connected to the lower portions of the three mounting rods 2, a first pump 601 is disposed on the upper portion of the water storage tank, the input end of the first pump 601 is connected to the communicating pipe 4, the output end of the first pump 601 is connected to a fourth communicating pipe 603, the fourth communicating pipe 603 is connected to the inside of the water storage tank 602, a filter element 604 is disposed at the end of the fourth communicating pipe 603, a water outlet 606 is disposed at the lower end of the water storage tank 602, a valve 605 is disposed on the upper portion of the water outlet 606, a water filling port 607 is disposed on the. The water injection port 607 is used for injecting water into the water storage tank 602 before the device is operated. The first pump 601 is a water-air dual-purpose pump, and belongs to the prior art. After the first pump 601 is opened, the input end of the first pump is connected with the communicating pipe 508, the output end of the first pump enters the water storage tank 602 through the fourth communicating pipe 603, the first pump further needs to pass through the filter element 604 at the output end, impurities in water after ice slag is melted are filtered out, then the first pump enters the water storage tank 602, blown wind can blow the water inside the water storage tank 602 to prevent the water from being solidified, and the blown wind is finally discharged from the vent 608. When water is to be supplied to the pit position drilled on the ice surface, water can be supplied by only aligning the water outlet 606 with the position where water is required to be supplied, opening the valve 605, and closing the valve after water supply is finished. Liquid water is subsequently solidified into ice surface, and materials such as liquid nitrogen can be used, so that the water surface can be quickly solidified.

The whole device can be arranged on a vehicle or other moving parts through the outer mounting frame 1, and the ice surface can be repaired.

Claims

1. The ice surface repairing device comprises an outer mounting frame (1), wherein three mounting rods (2) are arranged on the lower portion of the right end of the outer mounting frame (1), a transverse mounting plate (3) is arranged in the middle of the left end of the outer mounting frame (1), and the ice surface repairing device is characterized by further comprising an ice drilling component (5), wherein the ice drilling component (5) comprises a driving motor (501), the driving motor (501) is arranged on the lower portion of the transverse mounting plate, and the ice drilling component drills an ice surface after being started;

the water replenishing device (6) is arranged at the lower parts of the three mounting rods (2), and is used for replenishing water after a pit is dug on an ice surface;

and the communicating pipe (4) is connected with the ice drilling component (5) and the water replenishing device 6 through the communicating pipe (4).

2. The ice surface repairing device according to claim 1, wherein the ice drilling component (5) further comprises a first gear (502), the first gear (502) is arranged at an output end of the driving motor (501), an ice drilling outer cover (509) is arranged at the lower portion of the first gear (502), the ice drilling outer cover (509) is fixedly connected with the mounting frame (1), the top of the ice drilling outer cover (509) is closed, the lower portion of the ice drilling outer cover is open, the ice drilling outer cover is inclined inwards from top to bottom, a shaft sleeve (527) is arranged in the middle of a top plate of the ice drilling outer cover (509), a rotating shell (520) is arranged in the shaft sleeve (527), a gear sleeve (521) is arranged on the outer ring of the rotating shell (520), and the gear sleeve (521) is in meshing transmission with the first gear (502).

3. The ice surface repairing device according to claim 2, wherein a first sliding groove (525) is formed in the middle of the rotating shell (520), the first sliding groove (525) penetrates towards the lower side, a sliding shaft (526) capable of sliding in a reciprocating mode is arranged in the first sliding groove (525), the upper end of the sliding shaft (526) is connected with the rotating shell (520) through a telescopic hose (524), a second shaft (526) is fixedly connected to the lower end of the sliding shaft (526), a rotating connecting block (522) is arranged at the top end of the rotating shell (520), the rotating connecting block (522) and the rotating shell (520) are arranged in a concentric mode, and a first through hole (529) penetrating up and down is formed in the rotating connecting block (522), the rotating shell (520), the sliding shaft (526) and the second shaft (526).

4. The ice surface repairing device according to claim 3, wherein two first hydraulic grooves (533) are symmetrically arranged at the lower end of the second shaft (526) from left to right, each first hydraulic groove (533) is provided with a hydraulic rod (534) capable of sliding back and forth, the outer end of each hydraulic rod (534) is rotatably connected with an ice drilling claw (535), the inner end of each ice drilling claw (535) close to the rotary connection position of the hydraulic rod (534) and the ice drilling claw (535) is rotatably connected with a first connecting rod (536), the other end of each first connecting rod (536) is fixedly connected with the bottom surface of the second shaft (526), an annular groove (556) is arranged on the side wall of the second shaft (526), an annular block (555) is arranged in the annular groove (556), the annular block (555) can rotate relative to the second shaft (526) in the annular groove (556), two rope hooks (531) are symmetrically arranged on the annular block (555), each rope hook (531) is provided with a connecting rope (511).

5. An ice surface repairing device according to claim 4, wherein a sliding door (513) is arranged at the other end of the connecting rope (511), the sliding door (513) is slidably arranged in a third sliding groove (510), the third sliding groove (510) is stacked left and right and arranged on the left and right inclined side surfaces of the ice drilling outer cover (509), a first spring (512) is arranged between the upper end surface of each third sliding groove (510) and the sliding door (513), a connecting shell (508) which is through from front to back is arranged on the outer side of each third sliding groove (510), a second communicating pipe (503) is arranged at the outer opening of each connecting shell (508), and the other end (3) of each second communicating pipe (50) is communicated with the upper end of the communicating pipe (4).

6. The ice repairing device according to claim 2, wherein a second gear (542) is further disposed at a rear side of a top plate of the ice drilling housing (509), the second gear (542) is in meshing transmission with the first gear (502), a rotating connecting rod (543) is disposed at a position of the second gear (542) away from an axis by a certain distance, the other end of the rotating connecting rod (543) is rotatably connected with a cylinder push plate (547), a cylinder housing (545) is fixedly disposed at a right side of the top plate of the ice drilling housing (509), the cylinder push plate (547) is slidably and hermetically connected with the cylinder housing (545), a first one-way valve (505) is disposed at an end of the cylinder housing (545), a third communicating pipe (504) is connected to the first one-way valve (505), the third communicating pipe (504) is fixedly connected with a rotating connecting block (522), and an inner pipe thereof is communicated with the first through hole (529), the tail end of the cylinder shell (545) is also provided with a second one-way valve (546).

7. The ice surface repairing device according to claim 1, wherein the middle part of the communicating pipe (4) is spirally and circularly arranged outside the side wall of the driving motor (501).

8. An ice repair device according to claim 1, wherein said water replenishing device (6) comprises a water storage tank (602), the water storage tank body (602) is fixedly connected with the lower parts of the three mounting rods (2), the upper part of the water storage tank body is provided with a first pump (601), the input end of the first pump (601) is connected with a communicating pipe (4), the output end of the first pump (601) is connected with a fourth communicating pipe (603), the fourth communicating pipe (603) is connected with the inside of the water storage tank body (602), the end of the fourth communicating pipe (603) is provided with a filter element (604), the lower end of the water storage tank body (602) is provided with a water outlet (606), the water outlet (606) is provided with a valve (605) at the upper part, the side wall of the water storage tank body (602) is provided with a water filling port (607), and the upper part of the water storage tank body (602) is provided with two air vents (608).