CN115142375A

CN115142375A - Heat supply type snow removing device of energy supply equipment

Info

Publication number: CN115142375A
Application number: CN202211075945.0A
Authority: CN
Inventors: 段豪胜
Original assignee: Sheyang Jingang Energy Development Co ltd
Current assignee: Sheyang Jingang Energy Development Co ltd
Priority date: 2022-09-05
Filing date: 2022-09-05
Publication date: 2022-10-04
Anticipated expiration: 2042-09-05
Also published as: CN115142375B

Abstract

The invention provides a thermal power supply type snow removing device of energy supply equipment, which relates to the field of snow removal and comprises an energy supply plate, wherein driving screw rods are arranged on the left side and the right side of the energy supply plate; the left end of the rear side of the top of the energy supply plate is provided with a motor, and an output shaft of the motor is connected with the rear end of a left driving screw rod; a rack A is arranged in the middle of the top of the guide rail; a snow removing slide block is slidably arranged on the guide rail; and a gear A is arranged on the driving shaft. According to the invention, the ice layer is crushed by the ice crushing head, the ice layer is crushed into small blocks, and further, because the contact surface of the crushed ice and the environment with the temperature higher than that of the crushed ice is large, the crushed ice is more fully absorbed, so that the crushed ice is quickly melted by the influence of the heat supply pipe, and the problem that the existing snow removing device is short of a crushing structure for the ice layer, the ice layer is mostly integrated, the contact surface of the ice layer and the environment with the temperature higher than that of the ice layer is small, the heat is insufficiently absorbed, and the melting efficiency is low is solved.

Description

Heat supply type snow removing device of energy supply equipment

Technical Field

The invention relates to the technical field of snow removal, in particular to a thermal power supply type snow removing device of energy supply equipment.

Background

The energy supply equipment refers to equipment for converting heat energy, mechanical energy, chemical energy, light energy and the like into electric energy, and the energy plate (photovoltaic plate) belongs to the energy supply equipment, but the energy plate is mostly used outdoors, and when snowing, snowflakes are easy to accumulate on the energy plate to cover the energy plate, so that the energy conversion is influenced, and therefore, a snow removing device is needed to clean the snow accumulated on the energy plate.

When the existing snow removing device is used, most of snow accumulated is only cleaned from the energy source plate, but before the snow is accumulated into a pile, part of the snow is easy to melt into water and then is condensed and frozen into an ice layer to be attached to the energy source plate, the existing snow removing device is not convenient to clear the ice layer, the ice layer cannot be synchronously removed when removing the snow, and even if the existing snow removing device has a heating structure to melt the snow and the ice layer, but because the existing snow removing device lacks a crushing structure for the ice layer, the ice layer is mostly integrated, the contact surface of the ice layer and the environment with the temperature higher than that of the ice layer is less, the heat is not absorbed enough, and the melting efficiency is lower.

Disclosure of Invention

In view of the above, the present invention provides a heat supply type snow removing device of an energy supply apparatus, which has an ice breaking structure, and the ice layer can be broken by the ice breaking structure, so that the ice layer is broken into small pieces, and the broken small ice pieces are rapidly melted by matching with heat provided by a heat supply pipe.

The invention provides the purpose and the efficacy of a heat supply type snow removing device of energy supply equipment, which specifically comprises the following steps: the energy supply plate is provided with driving screw rods at the left side and the right side; a synchronous wheel A is arranged on the circumferential outer wall of the driving screw rod and connected through a synchronous belt; a motor is arranged at the left end of the rear side of the top of the energy supply plate, and an output shaft of the motor is connected with the rear end of a left driving screw rod; guide rails are arranged on the left side and the right side of the top of the energy supply plate; a rack A is arranged in the middle of the top of the guide rail; a snow removing slide block is slidably mounted on the guide rail and is connected with the driving screw rod through a nut pair; a heat supply pipe is arranged at the central position of the inner side of the snow removing slide block; driving shafts are arranged on the front side and the rear side inside the snow removing slide block; the driving shaft is provided with a gear A.

Furthermore, a gear B is arranged on the circumferential outer wall of the transmission shaft and is an elliptic gear.

Furthermore, a wiping shaft is arranged in the middle of the top of the snow removing slide block; and a synchronous wheel D is arranged on the middle section of the wiping shaft.

Further, a first bevel gear is arranged at the inner end of the wiping shaft; the snow removing frame is internally provided with a sliding chute.

Furthermore, the inboard of snow removing slider is provided with the snow removing frame, and the bottom of snow removing frame is the slope column structure.

Further, a sliding block is slidably mounted inside the sliding groove; and ice breaking shafts are arranged on the left side and the right side of the sliding block.

Furthermore, the bottom of slider imbeds and installs the one end of spring A, and the other end embedding of spring A installs in the bottom of spout.

Further, a main bevel gear is arranged at the top end of the ice breaking shaft; and a driven shaft is arranged at the top of the sliding block.

Furthermore, an ice breaking head is arranged at the bottom end of the ice breaking shaft, and an ice breaking contact is arranged at the bottom end of the ice breaking head.

Furthermore, the left end and the right end of the driven shaft are provided with auxiliary bevel gears, and the auxiliary bevel gears are meshed and connected with the main bevel gear.

Further, a sliding plate is slidably mounted at the top of the snow removing sliding block; and a rack B is arranged at the top of the sliding plate.

Further, a connecting plate is arranged at the bottom end of the sliding plate; and a wiping plate is arranged at the bottom end of the connecting plate.

Furthermore, the outside of connecting plate embedding is installed the one end of spring B, and the other end embedding of spring B installs the inboard at snow removing slider.

Furthermore, a synchronizing wheel B is arranged at the outer end of the driving shaft; and transmission shafts are arranged on the front side and the rear side of the top of the snow removing slide block.

Furthermore, the left end and the right end of the transmission shaft are provided with synchronous wheels C; and the synchronizing wheel C is connected with the synchronizing wheel B through a synchronous belt.

Further, a wiping cotton sliver is arranged at the bottom of the wiping plate; and a driving shaft is arranged on the inner side of the snow removing frame.

Furthermore, a second bevel gear is arranged at the inner end of the driving shaft and is in meshed connection with the first bevel gear.

Furthermore, a synchronizing wheel E is arranged on the transmission shaft and is connected with a synchronizing wheel D through a synchronizing belt.

Furthermore, a gear D is arranged on the middle section of the driven shaft and is meshed and connected with the gear B.

Further, a gear C is arranged on the circumferential outer wall of the driving shaft and is an incomplete gear; the gear C is intermittently meshed with the rack B.

Advantageous effects

1. The motor drives the driving screw rod to rotate, so that the driving screw rod drives the snow removing slide block to move along the guide rail under the action of the nut pair, the snow removing slide block drives the snow removing frame to move forwards, the snow removing frame cleans accumulated snow accumulated on the energy supply plate by utilizing the inclined structure at the bottom end of the snow removing frame, and the influence on the normal photoelectric energy conversion work of the energy supply plate due to the existence of the accumulated snow is avoided.

2. When the snow removing slide block moves forwards, the gear A can drive the driving shaft and the synchronous wheel B to rotate under the action of meshing with the rack A, so that the driving shaft and the gear B are driven to rotate under the action of connecting the synchronous belt with the synchronous wheel C, the gear B is matched with the gear D by utilizing the characteristic of the elliptic gear to enable the slide block to be stressed to descend along the sliding chute, the slide block drives the ice breaking shaft and the ice breaking head to descend in a reciprocating mode under the matching of the spring A, the ice breaking head is impacted with an ice layer, the ice breaking head breaks the ice layer by utilizing an ice breaking contact point at the bottom end of the ice breaking head, the ice layer is broken into small blocks, and further, the broken ice is rapidly melted by being influenced by the heat supply pipe because the contact surface of the broken ice and the environment with the temperature higher than that of the broken ice is large.

3. According to the invention, when the gear B is matched with the gear D by utilizing the characteristic of the elliptic gear to enable the slider to be stressed to descend along the sliding chute, the gear B is also meshed with the gear D, so that the gear B can provide rotating force for the gear D to rotate, the gear D drives the driven shaft and the auxiliary bevel gear to rotate, the auxiliary bevel gear drives the ice breaking shaft and the ice breaking head to rotate under the action of meshing with the main bevel gear, the ice breaking head improves the effect of breaking an ice layer through rotation, the ice layer is broken more finely, the volume of ice blocks generated by breaking is smaller, and the melting of the ice blocks is accelerated.

4. When the snow removing frame moves forwards, the cleaning plate and the cleaning cotton strip are driven to move forwards, so that the cleaning cotton strip cleans water stains remained on the energy supply plate and generated by snow removing and ice melting, and secondary icing of the water stains caused by improper water stain treatment is avoided, and inconvenience is brought to subsequent work.

5. When the transmission shaft rotates, the transmission shaft can drive the synchronizing wheel E to rotate, so that the synchronizing wheel E drives the wiping shaft and the first bevel gear to rotate under the action of connecting the synchronizing wheel E with the synchronizing wheel D through the synchronizing belt, the first bevel gear drives the driving shaft and the gear C to rotate under the action of meshing with the second bevel gear, the gear C drives the sliding plate, the wiping plate and the wiping cotton sliver to move left and right in a reciprocating mode under the action of intermittent meshing of the gear C and the rack B in cooperation with the spring B, and the wiping cotton sliver can improve the wiping effect on water tracks through the left and right reciprocating movement.

6. The invention can synchronously realize the crushing work and the melting work of the ice layer when the snow removal work is realized, and can synchronously realize the wiping and cleaning work of the water mark, combines a plurality of items, so that a plurality of structural modules can share the same electric power assembly, reduces the arrangement quantity of the electric power assembly, and is beneficial to reducing the production cost of the device.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings of the embodiments will be briefly described below.

The drawings in the following description relate to some embodiments of the invention only and are not intended to limit the invention.

In the drawings:

fig. 1 is a schematic view of the overall structure of a heat-supplied snow removing apparatus of an energy supply device of an embodiment of the invention;

fig. 2 is an enlarged partial structural schematic view of a portion a in fig. 1 of the heat-supplying snow removing device of the energy supply apparatus of the embodiment of the invention;

fig. 3 is a schematic half-section view of a snow-removing frame of a heat-supplying snow removing apparatus of the energy supply device of the embodiment of the invention;

fig. 4 is a schematic view of the structure of a slide plate and a wiper plate of the heat-supply snow removing device of the energy supply apparatus of the embodiment of the invention;

fig. 5 is a schematic structural view of a snow-removing slider and an ice-breaking shaft of the heat-supplying snow-removing apparatus of the energy supply device of the embodiment of the present invention;

fig. 6 is a schematic structural view of a snow removal slider and a heat supply pipe of the heat-supply snow removing apparatus of the energy supply device of the embodiment of the present invention;

fig. 7 is a schematic structural view of a wiping shaft and a drive shaft of the heat-supplying snow removing device of the energy supply apparatus of the embodiment of the invention;

fig. 8 is a schematic structural view of an ice breaking head and a slider of a heat-supplying snow removing device of the energy supply apparatus of the embodiment of the present invention;

fig. 9 is an enlarged partial structural schematic view of B in fig. 3 of the heat-supplied snow removing device of the energy supply apparatus of the embodiment of the present invention;

fig. 10 is a structural schematic view of an enlarged portion C in fig. 3 of the heat-supply snow removing device of the energy supply apparatus of the embodiment of the invention.

List of reference numerals

1. An energy supply plate; 101. driving the screw rod; 102. a synchronizing wheel A; 103. a motor; 104. a guide rail; 105. a rack A; 2. a snow removal slide block; 201. a drive shaft; 202. a gear A; 203. a synchronizing wheel B; 204. a drive shaft; 205. a synchronizing wheel C; 206. a gear B; 207. wiping the shaft; 208. a synchronizing wheel D; 209. a first bevel gear; 2010. a snow removal frame; 2011. a chute; 2012. a slider; 2013. a spring A; 2014. an ice breaking shaft; 2015. a primary bevel gear; 2016. an ice breaking head; 2017. a driven shaft; 2018. a secondary bevel gear; 2019. a sliding plate; 2020. a rack B; 2021. a connecting plate; 2022. a spring B; 2023. wiping the board; 2024. wiping cotton slivers; 2025. a drive shaft; 2026. a second bevel gear; 2027. a gear C; 2028. a synchronizing wheel E; 2029. a gear D; 3. a heat supply pipe.

Detailed Description

In order to make the objects, aspects and advantages of the embodiments of the present invention more apparent, the embodiments of the present invention will be described in detail with reference to the accompanying drawings. Unless otherwise indicated, terms used herein have the ordinary meaning in the art. Like reference symbols in the various drawings indicate like elements.

The embodiment is as follows: please refer to fig. 1 to 10:

the invention provides a heat supply type snow removing device of energy supply equipment, which comprises: the energy supply device comprises an energy supply plate 1, wherein driving screw rods 101 are arranged on the left side and the right side of the energy supply plate 1; a synchronous wheel A102 is arranged on the circumferential outer wall of the driving screw rod 101, and the synchronous wheels A102 are connected through a synchronous belt; the left end of the rear side of the top of the energy supply plate 1 is provided with a motor 103, and the output shaft of the motor 103 is connected with the rear end of a left driving screw rod 101; guide rails 104 are arranged on the left side and the right side of the top of the energy supply plate 1; a rack A105 is arranged at the central position of the top of the guide rail 104; a snow removal sliding block 2 is slidably mounted on the guide rail 104, and the snow removal sliding block 2 is connected with the driving screw rod 101 through a nut pair; a heat supply pipe 3 is arranged at the middle position of the inner side of the snow removing slide block 2; the front side and the rear side inside the snow removing slide block 2 are provided with driving shafts 201; the drive shaft 201 is provided with a gear a202.

In another embodiment: the surface of the snow removing slider 2 in contact with the guide rail 104 can be provided with an upper roller, and the friction force between the snow removing slider 2 and the guide rail 104 can be reduced by the roller, so that the snow removing slider 2 can move more smoothly.

Wherein, the outer end of the driving shaft 201 is provided with a synchronous wheel B203; the front side and the rear side of the top of the snow removing slide block 2 are provided with transmission shafts 204; the left end and the right end of the transmission shaft 204 are provided with synchronous wheels C205; the synchronous wheel C205 is connected with the synchronous wheel B203 through a synchronous belt; a gear B206 is arranged on the circumferential outer wall of the transmission shaft 204, and the gear B206 is an elliptic gear; a wiping shaft 207 is arranged at the top center position of the snow removing slide block 2; a synchronous wheel D208 is arranged on the middle section of the wiping shaft 207; the inner end of the wiping shaft 207 is provided with a first bevel gear 209; a snow removing frame 2010 is arranged on the inner side of the snow removing slider 2, and the bottom end of the snow removing frame 2010 is in an inclined structure; a chute 2011 is formed inside the snow removing frame 2010;

through starter motor 103, make motor 103 drive and be located left drive lead screw 101 rotatory, make and be located left drive lead screw 101 and drive the drive lead screw 101 that is located the right side under the effect of synchronizing wheel A102 and hold-in range and rotate, make two drive lead screws 101 drive snow removing slider 2 and remove along guide rail 104 under the vice effect of nut, make snow removing slider 2 drive snow removing frame 2010 move forward, make snow removing frame 2010 clear away snow.

A slider 2012 is slidably mounted inside the chute 2011; the bottom of the slider 2012 is embedded with one end of a spring A2013, and the other end of the spring A2013 is embedded with the bottom of the chute 2011; the ice breaking shafts 2014 are arranged on the left side and the right side of the sliding block 2012; a main bevel gear 2015 is arranged at the top end of the ice breaking shaft 2014; an ice breaking head 2016 is arranged at the bottom end of the ice breaking shaft 2014, and an ice breaking contact is arranged at the bottom end of the ice breaking head 2016; a driven shaft 2017 is arranged at the top of the sliding block 2012;

when the snow removing slider 2 moves forward, the gear a202 drives the driving shaft 201 and the synchronizing wheel B203 to rotate under the action of meshing with the rack a105, the synchronizing wheel B203 drives the driving shaft 204 and the gear B206 to rotate under the action of connecting with the synchronizing wheel C205 through a synchronous belt, the gear B206 is matched with the gear D2029 by utilizing the characteristics of an elliptic gear to enable the slider 2012 to descend along the chute 2011 under stress, the slider 2012 drives the ice breaking shaft 2014 and the ice breaking head 2016 to descend in a reciprocating mode under the matching of the spring a2013, the ice breaking head 2016 is collided with an ice layer, the ice breaking head 2016 breaks the ice layer into small pieces, meanwhile, the gear B206 is also meshed with the gear D2029, the gear B206 can provide rotating force for the gear D2029 to rotate, the driven shaft 2017 and the secondary bevel gear 2018 are driven by the secondary bevel gear 2018 to drive the ice breaking shaft 2014 and the ice breaking head 2016 to rotate under the meshing with the main gear, and the ice breaking head 2016 is broken into smaller pieces.

Wherein, the left end and the right end of the driven shaft 2017 are provided with auxiliary bevel gears 2018, and the auxiliary bevel gears 2018 are meshed with the main bevel gear 2015; a sliding plate 2019 is slidably mounted at the top of the snow removing slider 2; the top of the sliding plate 2019 is provided with a rack B2020; the bottom end of the sliding plate 2019 is provided with a connecting plate 2021; one end of a spring B2022 is embedded and mounted on the outer side of the connecting plate 2021, and the other end of the spring B2022 is embedded and mounted on the inner side of the snow removal slider 2; the bottom end of the connecting plate 2021 is provided with a wiping plate 2023; the bottom of the wiping plate 2023 is provided with a wiping cotton sliver 2024; a driving shaft 2025 is arranged inside the snow removing frame 2010; the inner end of the driving shaft 2025 is provided with a second bevel gear 2026, and the second bevel gear 2026 is engaged with the first bevel gear 209; a gear C2027 is arranged on the circumferential outer wall of the driving shaft 2025, and the gear C2027 is an incomplete gear; the gear C2027 is intermittently meshed with the rack B2020; a synchronizing wheel E2028 is arranged on the transmission shaft 204, and the synchronizing wheel E2028 is connected with a synchronizing wheel D208 through a synchronizing belt; a gear D2029 is arranged on the intermediate section of the driven shaft 2017, and the gear D2029 is meshed and connected with the gear B206;

when the snow removing frame 2010 drives the wiping plate 2023 and the wiping cotton sliver 2024 to move forwards, the wiping cotton sliver 2024 can wipe and clean water traces left on the energy supply plate 1 and generated by snow removing and ice melting, and when the transmission shaft 204 rotates, the transmission shaft 204 can drive the synchronizing wheel E2028 to rotate, so that the synchronizing wheel E2028 drives the wiping shaft 207 and the first bevel gear 209 to rotate under the action of connecting with the synchronizing wheel D208 through the synchronizing belt, the first bevel gear 209 drives the driving shaft 2025 and the gear C2027 to rotate under the action of meshing with the second bevel gear 2026, the gear C2027 drives the sliding plate 2019, the wiping plate 2023 and the wiping cotton sliver 2024 to reciprocate left and right under the action of intermittent meshing with the rack B2020, and the sliding plate 2019, the wiping plate 2023 and the wiping cotton sliver 2024 are driven to reciprocate left and right, so that the wiping cotton sliver 2024 wipes and cleans the water traces, and the cleaning effect of the water traces is ensured.

The specific use mode and function of the embodiment are as follows: when the snow-removing device is used, firstly, the motor 103 is started, the motor 103 drives the driving screw rod 101 on the left side to rotate, the driving screw rod 101 on the left side drives the driving screw rod 101 on the right side to rotate under the action of the synchronous wheel A102 and the synchronous belt, the two driving screw rods 101 drive the snow-removing slider 2 to move along the guide rail 104 under the action of the nut pair, the snow-removing slider 2 drives the snow-removing frame 2010 to move forward, the snow-removing frame 2010 removes snow, and when the snow-removing slider 2 moves forward, the gear A202 drives the driving shaft 201 and the synchronous wheel B203 to rotate under the action of meshing with the rack A105, the synchronous wheel B203 drives the transmission shaft 204 and the gear B206 to rotate under the action of connecting the synchronous belt with the synchronous wheel C205, the gear B206 is matched with the gear D2029 by utilizing the characteristic of the elliptic gear to enable the slider 2012 to descend along the chute 2011 under the stress, so that the slider 2012 drives the ice breaking shaft 2014 and the ice breaking head 2016 to descend in a reciprocating manner under the coordination of the spring A2013, the ice breaking head 2016 is made to collide with the ice layer, the ice breaking head 2016 is made to break the ice layer into small pieces, meanwhile, the gear B206 is also meshed with the gear D2029, so that the gear B206 can also provide rotating force for the gear D2029 to rotate, the gear D drives the driven shaft 2017 and the auxiliary bevel gear 2018 to rotate, the auxiliary bevel gear 2018 drives the ice breaking shaft 2014 and the ice breaking head 2016 to rotate under the meshing action with the main bevel gear 2015, the ice breaking head 2016 is made to break the ice layer into smaller fragments, accordingly, the crushed ice blocks can be rapidly melted under the influence of the heat supply pipe 3, when the snow removing frame 2010 drives the wiping plate 2023 and the wiping plate 2024 to move forwards, the wiping sliver 2024 can wipe and clean water marks generated by ice melting and melting on the energy supply plate 1, and when the transmission shaft 204 rotates, the transmission shaft 204 can drive the synchronizing wheel E2028 to rotate, the synchronizing wheel E2028 drives the wiping shaft 207 and the first bevel gear 209 to rotate under the action of being connected with the synchronizing wheel D208 through a synchronous belt, the first bevel gear 209 drives the driving shaft 2025 and the gear C2027 to rotate under the action of being meshed with the second bevel gear 2026, the gear C2027 drives the sliding plate 2019, the wiping plate 2023 and the wiping cotton sliver 2024 to reciprocate left and right by utilizing the action of being intermittently meshed with the rack B2020 and the spring B2022, and the wiping cotton sliver 2024 wipes water stains in a reciprocating manner left and right to ensure the cleaning effect on the water stains.

The above description is intended to be illustrative of the present invention and not to limit the scope of the invention, which is defined by the claims appended hereto.

Claims

1. A heat-supply snow removing apparatus of an energy supply facility, characterized by comprising: the energy supply device comprises an energy supply plate (1), wherein driving screw rods (101) are arranged on the left side and the right side of the energy supply plate (1); a synchronous wheel A (102) is arranged on the circumferential outer wall of the driving screw rod (101), and the synchronous wheel A (102) is connected through a synchronous belt; a motor (103) is arranged at the left end of the rear side of the top of the energy supply plate (1), and an output shaft of the motor (103) is connected with the rear end of a left driving screw rod (101); guide rails (104) are arranged on the left side and the right side of the top of the energy supply plate (1); a rack A (105) is arranged in the middle of the top of the guide rail (104); the snow removing slide block (2) is slidably mounted on the guide rail (104), and the snow removing slide block (2) is connected with the driving screw rod (101) through a nut pair; a heat supply pipe (3) is arranged at the central position of the inner side of the snow removing slide block (2); driving shafts (201) are arranged on the front side and the rear side inside the snow removing slide block (2); the driving shaft (201) is provided with a gear A (202).

2. A heat-supplied snow removing apparatus of an energy supply facility as defined in claim 1, wherein: the outer end of the driving shaft (201) is provided with a synchronous wheel B (203); transmission shafts (204) are arranged on the front side and the rear side of the top of the snow removing slide block (2); the left end and the right end of the transmission shaft (204) are provided with synchronous wheels C (205); the synchronizing wheel C (205) is connected with the synchronizing wheel B (203) through a synchronous belt.

3. A heat-supplied snow removing apparatus of an energy supply facility as defined in claim 2, wherein: a gear B (206) is arranged on the circumferential outer wall of the transmission shaft (204), and the gear B (206) is an elliptic gear; a wiping shaft (207) is arranged at the center of the top of the snow removing slide block (2); a synchronous wheel D (208) is arranged on the middle section of the wiping shaft (207).

4. A heat-supplied snow removing apparatus of an energy supply device as defined in claim 3, wherein: a first bevel gear (209) is arranged at the inner end of the wiping shaft (207); a snow removing frame (2010) is arranged on the inner side of the snow removing slide block (2), and the bottom end of the snow removing frame (2010) is of an inclined structure; a sliding groove (2011) is formed in the snow removing frame (2010).

5. A heat-supplied snow removing apparatus of an energy supply device as defined in claim 4, wherein: a sliding block (2012) is arranged inside the sliding groove (2011) in a sliding manner; the bottom of the sliding block (2012) is embedded with one end of a spring A (2013), and the other end of the spring A (2013) is embedded with the bottom of the sliding groove (2011); the left side and the right side of the slider (2012) are provided with an ice breaking shaft (2014).

6. A heat-supplied snow removing apparatus of an energy supply facility as defined in claim 5, wherein: a main bevel gear (2015) is arranged at the top end of the ice breaking shaft (2014); an ice breaking head (2016) is arranged at the bottom end of the ice breaking shaft (2014), and an ice breaking contact is arranged at the bottom end of the ice breaking head (2016); and a driven shaft (2017) is arranged at the top of the sliding block (2012).

7. A heat-supplied snow removing apparatus of an energy supply device as defined in claim 6, wherein: auxiliary bevel gears (2018) are arranged at the left end and the right end of the driven shaft (2017), and the auxiliary bevel gears (2018) are meshed and connected with the main bevel gear (2015); a sliding plate (2019) is slidably mounted at the top of the snow removing slide block (2); the top of the sliding plate (2019) is provided with a rack B (2020).

8. A heat-supplied snow removing apparatus of an energy supply facility as defined in claim 7, wherein: a connecting plate (2021) is arranged at the bottom end of the sliding plate (2019); one end of a spring B (2022) is embedded in the outer side of the connecting plate (2021), and the other end of the spring B (2022) is embedded in the inner side of the snow removing slide block (2); the bottom end of the connecting plate (2021) is provided with a wiping plate (2023).

9. A heat-supplied snow removing apparatus of an energy supply device as defined in claim 8, wherein: the bottom of the wiping plate (2023) is provided with a wiping cotton sliver (2024); a driving shaft (2025) is arranged on the inner side of the snow removing frame (2010); the inner end of the driving shaft (2025) is provided with a second bevel gear (2026), and the second bevel gear (2026) is meshed and connected with the first bevel gear (209).

10. A heat-supplied snow removing apparatus of an energy supply facility as defined in claim 9, wherein: a gear C (2027) is arranged on the circumferential outer wall of the driving shaft (2025), and the gear C (2027) is an incomplete gear; the gear C (2027) is intermittently meshed with the rack B (2020); a synchronizing wheel E (2028) is arranged on the transmission shaft (204), and the synchronizing wheel E (2028) is connected with a synchronizing wheel D (208) through a synchronizing belt; the intermediate section of the driven shaft (2017) is provided with a gear D (2029), and the gear D (2029) is meshed and connected with the gear B (206).