CN111969534A - Automatic deicing equipment for electric energy transmission high-voltage line - Google Patents

Abstract

The invention relates to the field related to electric energy, in particular to automatic deicing equipment for an electric energy transmission high-voltage wire, which comprises an equipment body and a travelling device arranged at the top of the equipment body, wherein the travelling device can drive the equipment to travel along a line to ensure the normal operation of the equipment, the top of the equipment body is provided with a deicing device positioned at the right side of the travelling device, the deicing device comprises a first connecting shaft fixedly arranged on the top wall of the equipment body, and the top of the first connecting shaft is provided with a first connecting rod in a spring connection manner. Has high safety.

Description

Automatic deicing equipment for electric energy transmission high-voltage line

Technical Field

The invention relates to the field of electric energy correlation, in particular to automatic deicing equipment for an electric energy transmission high-voltage line.

Background

In the prior art, a thick layer of ice is easily generated on the surface of a line in winter by a long-distance high-voltage transmission line, which not only affects transmission but also has certain potential safety hazard, and can damage a line tower when the weight of the ice is too large, however, in the common deicing operation, people use a long-distance rod to knock the ice by a worker, and the worker needs to climb onto the line to perform deicing operation when encountering ice blocks which are difficult to remove, which is very dangerous, so that the automatic deicing equipment for the electric energy transmission high-voltage line is needed to be designed, and the existing problems are solved.

Disclosure of Invention

The invention aims to provide automatic deicing equipment for an electric energy transmission high-voltage line, which can overcome the defects in the prior art, so that the practicability of the equipment is improved.

The technical scheme adopted by the invention for solving the technical problems is as follows: the invention relates to automatic deicing equipment for an electric energy transmission high-voltage wire, which comprises an equipment body and a travelling device arranged on the top of the equipment body, wherein the travelling device can drive the equipment to travel along a line to ensure the normal operation of the equipment, the top of the equipment body is provided with a deicing device positioned on the right side of the travelling device, the deicing device comprises a first connecting shaft fixedly arranged on the top wall of the equipment body, the top of the first connecting shaft is provided with a first connecting rod in a spring connection manner, the top of the first connecting rod is fixedly provided with a first sleeve, the top = wall of the equipment body is fixedly provided with a first support, the top = wall of the equipment body is provided with a second connecting shaft positioned on the right side of the first connecting shaft in a spring connection manner, the top of the second connecting shaft is provided with a second connecting rod in a spring connection manner, the top of the second connecting rod is fixedly provided, the spring rod is arranged at the top of the third connecting rod in a spring connection mode, the pull rod is fixedly arranged at the top of the spring rod, the pull rod and the first support are jointly matched and connected with a pressure rod, the pressure rod is hinged with the pull rod and can rotate around the first support, the ice breaking knife is hinged at the left end of the pressure rod, a rotary drum which sleeves a cable is rotatably arranged in the first sleeve and the second connecting rod, a first bevel gear is fixedly arranged at the right end of the rotary drum, an ice removing ring is fixedly arranged at the front end of the rotary drum, a centrifugal wheel which is positioned between the first sleeve and the second sleeve is fixedly arranged on the outer surface of the rotary drum, a slide block which is connected with the centrifugal wheel through a spring is arranged in a circumferential surface array, a push plate is hinged to the end face of the slide block, and the centrifugal wheel is driven to rotate when the rotary, the sliding block pushes the push plate outwards under the action of centrifugal force, so that the push plate contacts the pressure rod and then pushes the right end of the pressure rod upwards, the left end of the pressure rod moves downwards to enable the ice breaking blade to cling to a cable for ice breaking, and meanwhile, the rotary drum drives the ice removing ring to rotate to wring out the ice broken by the ice breaking blade when rotating; the ice removing device is characterized in that a processing device located on the lower side of the ice removing device is arranged in the machine body, the processing device collects and melts ice broken by the ice removing device, a transmission device located on the rear side of the processing device is arranged in the machine body, and the transmission device transmits power to the advancing device, the ice removing device and the processing device.

Furthermore, the moving device comprises a connecting table which is arranged at the top of the machine body and connected through a spring and is positioned on the right side of the deicing device, a first connecting arm is fixedly arranged at the top of the connecting table, the first connecting arm is divided into an upper part and a lower part, the bottom surface of the upper part of the first connecting arm is fixedly provided with a clamping groove extending to the lower part, a spring block which can clamp the clamping block is arranged on the rear end wall in the clamping groove through the spring connection, the rear end surface of the spring block is fixedly provided with a sliding rod extending out of the first connecting arm, a user can separate the upper part and the lower part of the first connecting arm by pulling the sliding rod, a second connecting arm positioned on the front side of the first connecting arm is hinged at the top of the connecting table, the second connecting arm and the top of the first connecting arm are fixedly provided with the same third sleeve, and a driving wheel shaft is arranged in the third, the front end of the driving wheel shaft is fixedly provided with a second bevel gear, the outer surface of the driving wheel shaft is fixedly provided with a driving wheel positioned between the two third sleeves, the top of the connecting table is provided with a supporting wheel shaft and a supporting wheel which are the same as the driving wheel shaft and the driving wheel and positioned on the right side of the driving wheel, and the driving wheel and the supporting wheel are jointly matched and hung on a cable and drive equipment to move when the driving wheel rotates.

Furthermore, the processing device comprises a melting cavity which is arranged at the top of the machine body and is upwards opened and is positioned at the lower side of the ice breaking blade, a first transmission cavity which is positioned at the lower side of the melting cavity is arranged in the machine body, the top of the first transmission cavity is rotatably provided with a crushing shaft which extends into the melting cavity, the bottom end of the crushing shaft is fixedly provided with a first belt wheel which is positioned in the first transmission cavity, the top end of the crushing shaft is fixedly provided with a crushing barrel which is positioned in the melting cavity, the machine body is internally provided with a heater which is attached to the bottom wall of the melting cavity, the heater is used for heating and melting crushed ice, the processing device also comprises an atomizing cavity which is arranged at the bottom wall of the machine body and is downwards opened, the atomizing cavity is communicated with the melting cavity through a pipeline, and the machine body is internally provided with a second, second transmission chamber roof rotates to be provided with and extends to fan shaft in the atomizing chamber, fan shaft external surface is fixed to be provided with and is located the fan wheel of atomizing intracavity, fan shaft bottom end is fixed to be provided with and is located the turning block of fan wheel downside, the inside array of turning block is provided with the through-hole, will when the fan wheel rotates melt the ice water that the intracavity melts and take out extremely in the atomizing chamber and pass through the turning block atomization processing arranges extremely the organism is external.

Further, the transmission device comprises a motor arranged on the lower side of the second transmission cavity, an output shaft of the motor penetrates through the second transmission cavity and extends to the top of the machine body, a second belt wheel positioned in the second transmission cavity is fixedly arranged on the outer surface of the output shaft, a first spline shaft connected through a spring is arranged on the top end of the output shaft in a spline fit manner, a third bevel gear always engaged with the second bevel gear is fixedly arranged on the top end of the first spline shaft, a fourth sleeve is rotatably arranged on the outer surface of the first spline shaft, the fourth sleeve and the second connecting arm are fixedly connected with each other through a second bracket, the transmission device further comprises a third belt wheel fixedly arranged on the outer surface of the fan shaft and connected with the second belt wheel through a first belt, and a fourth belt wheel positioned on the lower side of the third belt wheel is fixedly arranged on the outer surface of the fan shaft, the bottom wall of the first transmission cavity is rotatably provided with a rotating shaft which penetrates through the second transmission cavity and extends to the top of the machine body, a fifth belt wheel which is located in the first transmission cavity and is connected with the first belt wheel in a matched mode through a second belt is fixedly arranged on the outer surface of the rotating shaft, a sixth belt wheel which is located in the second transmission cavity and is connected with the fourth belt wheel in a matched mode through a third belt is fixedly arranged on the outer surface of the rotating shaft, a second spline shaft connected through a spring is arranged in a spline matched mode on the top of the rotating shaft, a fourth bevel gear which is always meshed with the first bevel gear is fixedly arranged at the top end of the second spline shaft, a fifth sleeve is rotatably arranged on the outer surface of the second spline shaft, and the fifth sleeve and the second connecting rod are fixedly connected with each other through a third support.

The invention has the beneficial effects that: the automatic deicing equipment for the electric energy transmission high-voltage wire can realize full-automatic deicing operation on the electric energy transmission high-voltage wire, does not influence a line, carries out melting treatment on the removed electric energy transmission high-voltage wire, avoids falling and smashing personnel, is high in automation degree, simple in operation and high in efficiency, avoids dangerous operation of the personnel, and has high safety.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a schematic view of the overall structure of an automatic deicing apparatus for electric power transmission high voltage lines according to the present invention;

FIG. 2 is a schematic view of the structure A-A of FIG. 1;

FIG. 3 is a schematic view of a portion of B in FIG. 1;

fig. 4 is a partially enlarged structural diagram of C in fig. 2.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The automatic deicing equipment for the electric energy transmission high-voltage line described in conjunction with fig. 1-4 comprises an equipment body 10 and a traveling device 81 arranged on the top of the equipment body 10, wherein the traveling device 81 can drive the equipment to travel along a line to ensure the normal operation of the equipment, a deicing device 82 arranged on the right side of the traveling device 81 is arranged on the top of the equipment body 10, the deicing device 82 comprises a first connecting shaft 49 fixedly arranged on the top wall of the equipment body 10, a first connecting rod 66 is arranged on the top of the first connecting shaft 49 in a spring connection manner, a first sleeve 63 is fixedly arranged on the top of the first connecting rod 66, a first support 62 is fixedly arranged on the top of the first sleeve 63, a second connecting shaft 50 arranged on the right side of the first connecting shaft 49 is fixedly arranged on the top = wall of the equipment body 10, a second connecting rod 67 is arranged on the top of the second connecting, a second sleeve 57 is fixedly arranged on the top of the second connecting rod 67, a third connecting rod 58 is fixedly arranged on the top of the second sleeve 57, a spring rod 59 is arranged on the top of the third connecting rod 58 in a spring connection manner, a pull rod 60 is fixedly arranged on the top of the spring rod 59, a pressure rod 61 is arranged between the pull rod 60 and the first bracket 62 in a matching connection manner, the pressure rod 61 is hinged with the pull rod 60 and can rotate around the first bracket 62, the left end of the pressure rod 61 is hinged with an ice breaking knife 65, a drum 56 which is used for sleeving cables is rotatably arranged inside the first sleeve 63 and the second connecting rod 67, a first bevel gear 55 is fixedly arranged at the right end of the drum 56, an ice removing ring 64 is fixedly arranged at the front end of the drum 56, a centrifugal wheel 68 which is positioned between the first sleeve 63 and the second sleeve 57 is fixedly arranged on the outer surface of the drum 56, the peripheral surface array of the centrifugal wheel 68 is provided with a slide block 69 connected through a spring, the end surface of the slide block 69 is hinged with a push plate 70, when the first bevel gear 55 drives the rotary drum 56 to rotate, the centrifugal wheel 68 is driven to rotate, so that the slide block 69 pushes the push plate 70 outwards under the action of centrifugal force, the push plate 70 is driven to push the right end of the pressure rod 61 upwards after contacting the pressure rod 61, the left end of the pressure rod 61 moves downwards, the ice breaking knife 65 is attached to a cable for ice breaking, and meanwhile, when the rotary drum 56 rotates, the ice removing ring 64 is driven to rotate to wring out the ice broken by the ice breaking knife 65; the machine body 10 is provided with a processing device 83 at a lower side of the deicing device 82, the processing device 83 collects and melts the ice crushed by the deicing device 82, a transmission device 84 at a rear side of the processing device 83 is provided in the machine body 10, and the transmission device 84 transmits power to the traveling device 81, the deicing device 82 and the processing device 83.

Advantageously, the traveling device 81 includes a connecting table 32 disposed on the top of the machine body 10 and connected by a spring, and located on the right side of the deicing device 82, a first connecting arm 37 is fixedly disposed on the top of the connecting table 32, the first connecting arm 37 is divided into an upper portion and a lower portion, a slot 71 extending to the lower portion is fixedly disposed on the bottom surface of the upper portion of the first connecting arm 37, a spring block 74 capable of latching the latch block 72 is disposed on the rear side end wall inside the slot 71 by a spring connection, a slide rod 73 extending out of the first connecting arm 37 is fixedly disposed on the rear end surface of the spring block 74, a user can separate the upper portion and the lower portion of the first connecting arm 37 by pulling the slide rod 73, a second connecting arm 40 located on the front side of the first connecting arm 37 is hinged on the top of the connecting table 32, and the same third sleeve 39 is fixedly disposed on the top of the second connecting arm 40 and the first connecting arm 37, a driving wheel shaft 35 is arranged in the third sleeves 39 in a co-rotating mode, a second bevel gear 41 is fixedly arranged at the front end of the driving wheel shaft 35, a driving wheel 36 located between the two third sleeves 39 is fixedly arranged on the outer surface of the driving wheel shaft 35, a supporting wheel shaft 33 and a supporting wheel 34 which are the same as the driving wheel shaft 35 and the driving wheel 36 and located on the right side of the driving wheel 36 are arranged at the top of the connecting table 32, and the driving wheel 36 and the supporting wheel 34 are jointly matched and hung on a cable and drive the equipment to move when the driving wheel 36 rotates.

Beneficially, the processing device 83 includes a melting chamber 12 disposed at the top of the machine body 10 and opened upward and located at the lower side of the ice breaking blade 65, a first transmission chamber 15 located at the lower side of the melting chamber 12 is disposed inside the machine body 10, a crushing shaft 14 extending into the melting chamber 12 is rotatably disposed at the top of the first transmission chamber 15, a first pulley 16 located in the first transmission chamber 15 is fixedly disposed at the bottom end of the crushing shaft 14, a crushing cylinder 13 located in the melting chamber 12 is fixedly disposed at the top end of the crushing shaft 14, a heater 17 attached to the bottom wall of the melting chamber 12 is disposed inside the machine body 10, the heater 17 is used for heating and melting the crushed ice, the processing device 83 further includes an atomizing chamber 26 disposed at the bottom wall of the machine body 10 and opened downward, and the atomizing chamber 26 is communicated with the melting chamber 12 through a pipeline 20, the inside second transmission chamber 22 that is located of being provided with of organism 10 atomizing chamber 26 upside, second transmission chamber 22 roof rotates to be provided with and extends to fan shaft 30 in the atomizing chamber 26, fan shaft 30 external fixed surface is provided with and is located fan 27 in the atomizing chamber 26, fan shaft 30 bottom mounting is provided with and is located the turning block 28 of fan 27 downside, the inside array of turning block 28 is provided with through-hole 29, will when fan 27 rotates melt the interior frozen water that melts of chamber 12 take out extremely in the atomizing chamber 26 and pass through turning block 28 atomization treatment arrange extremely outside the organism 10.

Advantageously, the transmission device 84 includes an electric motor 11 disposed at the lower side of the second transmission cavity 22, an output shaft 45 of the electric motor 11 extends through the second transmission cavity 22 to the top of the machine body 10, a second pulley 47 disposed in the second transmission cavity 22 is fixedly disposed on the outer surface of the output shaft 45, a first spline shaft 43 connected through a spring is disposed at the top end of the output shaft 45 in a spline fit manner, a third bevel gear 42 always engaged with the second bevel gear 41 is fixedly disposed at the top end of the first spline shaft 43, a fourth sleeve 44 is rotatably disposed on the outer surface of the first spline shaft 43, the fourth sleeve 44 and the second connecting arm 40 are fixedly connected to each other through a second bracket 46, the transmission device 84 further includes a third pulley 31 fixedly disposed on the outer surface of the fan shaft 30 in a fit manner connected with the second pulley 47 through a first belt 48, the outer surface of the fan wheel shaft 30 is fixedly provided with a fourth belt wheel 25 positioned on the lower side of the third belt wheel 31, the bottom wall of the first transmission cavity 15 is rotatably provided with a rotating shaft 21 which penetrates through the second transmission cavity 22 and extends to the top of the machine body 10, the outer surface of the rotating shaft 21 is fixedly provided with a fifth belt wheel 19 which is positioned in the first transmission cavity 15 and is in fit connection with the first belt wheel 16 through a second belt 18, the outer surface of the rotating shaft 21 is fixedly provided with a sixth belt wheel 23 which is positioned in the second transmission cavity 22 and is in fit connection with the fourth belt wheel 25 through a third belt 24, the top of the rotating shaft 21 is in spline fit connection with a second spline shaft 52 connected through a spring, the top end of the second spline shaft 52 is fixedly provided with a fourth bevel gear 54 which is always engaged with the first bevel gear 55, and the outer surface of the second spline shaft 52 is rotatably provided with a fifth sleeve 53, the fifth sleeve 53 and the second connecting rod 67 are fixedly connected to each other by a third bracket 51.

The fixing and connecting method in this embodiment includes, but is not limited to, bolting, welding, and the like.

Sequence of mechanical actions of the whole device: when the device of the present invention is operated, the motor 11 is started to rotate the output shaft 45, so as to rotate the third bevel gear 42, so as to rotate the second bevel gear 41, so as to rotate the driving wheel shaft 35, so as to rotate the driving wheel 36, so as to move the device to the left, and when the output shaft 45 rotates, the second belt wheel 47 is rotated, so as to rotate the third belt wheel 31, so as to rotate the fan wheel shaft 30, so as to rotate the fourth belt wheel 25, so as to rotate the sixth belt wheel 23, so as to rotate the rotating shaft 21, so as to rotate the fourth bevel gear 54, so as to rotate the first bevel gear 55, so as to rotate the rotating drum 56, so as to rotate the centrifugal wheel 68, so as to cause the slide block 69 to push the push plate 70 outwards under the action of centrifugal force, so that the push plate 70 contacts the pressure rod 61 and pushes the right end of the pressure rod 61 upwards, so that the left end of the pressure rod 61 moves downwards to make the ice breaking blade 65 cling to the cable to break ice, meanwhile, the rotary drum 56 rotates to drive the ice removing ring 64 to rotate to wring the ice broken by the ice breaking blade 65 into the melting chamber 12, the rotary shaft 21 rotates to drive the fifth belt wheel 19 to rotate to drive the first belt wheel 16 to rotate to drive the breaking shaft 14 to rotate to drive the breaking cylinder 13 to rotate, so that the broken ice in the melting chamber 12 is broken and melted by the heater 17, the fan wheel shaft 30 rotates to drive the fan wheel 27 to rotate, and the fan wheel 27 rotates to pump the ice water melted in the melting chamber 12 into the atomizing chamber 26 and discharge the ice water out of the machine body 10 through the rotary block 28, all links of the equipment are matched and run continuously.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims (4)

1. The utility model provides an automatic deicing equipment of electric energy transmission high-voltage line, includes the organism and sets up the advancing device at organism top which characterized in that: the travelling device can drive equipment to travel along a line, normal operation of the equipment is guaranteed, the deicing device is arranged on the top of the machine body and positioned on the right side of the travelling device, the deicing device comprises a first connecting shaft fixedly arranged on the top wall of the machine body, a first connecting rod is arranged on the top of the first connecting shaft in a spring connection mode, a first sleeve is fixedly arranged on the top of the first connecting rod, a first support is fixedly arranged on the top of the first sleeve, a second connecting shaft positioned on the right side of the first connecting shaft is fixedly arranged on the top = wall of the machine body, a second connecting rod is arranged on the top of the second connecting shaft in a spring connection mode, a second sleeve is fixedly arranged on the top of the second connecting rod, a third connecting rod is fixedly arranged on the top of the second sleeve, a spring rod is arranged on the top of the third connecting rod in a spring, the pull rod and the first support are jointly matched and connected with a pressure rod, the pressure rod is hinged with the pull rod and can rotate around the first support, the left end of the pressure rod is hinged with an ice breaking cutter, the first sleeve and the second connecting rod are internally and rotatably provided with a rotary drum sleeved with a cable, the right end of the rotary drum is fixedly provided with a first bevel gear, the front end of the rotary drum is fixedly provided with an ice removing ring, the outer surface of the rotary drum is fixedly provided with a centrifugal wheel positioned between the first sleeve and the second sleeve, the circumferential surface array of the centrifugal wheel is provided with a slide block connected through a spring, the end surface of the slide block is hinged with a push plate, and when the rotary drum is driven by the first bevel gear to rotate, the centrifugal wheel is driven to rotate, so that the slide block pushes the push plate outwards under the action of centrifugal force, and the right end of the pressure rod is pushed upwards after the push plate contacts the pressure rod, so that the left end of the pressure rod moves downwards to enable the ice breaking blade to cling to the cable for ice breaking, and meanwhile, the rotary drum drives the ice removing ring to rotate to wring out the ice broken by the ice breaking blade; the ice removing device is characterized in that a processing device located on the lower side of the ice removing device is arranged in the machine body, the processing device collects and melts ice broken by the ice removing device, a transmission device located on the rear side of the processing device is arranged in the machine body, and the transmission device transmits power to the advancing device, the ice removing device and the processing device.

2. An automatic de-icing apparatus for an electrical energy transmission high voltage line according to claim 1, characterized in that: the travelling device comprises a connecting table which is arranged at the top of the machine body and connected through a spring and is positioned on the right side of the deicing device, a first connecting arm is fixedly arranged at the top of the connecting table, the first connecting arm is divided into an upper part and a lower part, the bottom surface of the upper part of the first connecting arm is fixedly provided with a clamping groove extending to the lower part, a spring block capable of clamping the clamping block is arranged on the rear end wall in the clamping groove through the spring connection, the rear end surface of the spring block is fixedly provided with a sliding rod extending out of the first connecting arm, a user can separate the upper part and the lower part of the first connecting arm by pulling the sliding rod, a second connecting arm positioned on the front side of the first connecting arm is hinged at the top of the connecting table, the second connecting arm and the top of the first connecting arm are fixedly provided with the same third sleeve, and a driving wheel shaft is arranged in, the front end of the driving wheel shaft is fixedly provided with a second bevel gear, the outer surface of the driving wheel shaft is fixedly provided with a driving wheel positioned between the two third sleeves, the top of the connecting table is provided with a supporting wheel shaft and a supporting wheel which are the same as the driving wheel shaft and the driving wheel and positioned on the right side of the driving wheel, and the driving wheel and the supporting wheel are jointly matched and hung on a cable and drive equipment to move when the driving wheel rotates.

3. An automatic de-icing apparatus for an electrical energy transmission high voltage line according to claim 1, characterized in that: the processing device comprises a melting cavity which is arranged at the top of the machine body and is upwards opened and is positioned on the lower side of the ice breaking blade, a first transmission cavity which is positioned on the lower side of the melting cavity is arranged in the machine body, the top of the first transmission cavity is rotatably provided with a crushing shaft which extends into the melting cavity, the bottom of the crushing shaft is fixedly provided with a first belt wheel which is positioned in the first transmission cavity, the top of the crushing shaft is fixedly provided with a crushing cylinder which is positioned in the melting cavity, the machine body is internally provided with a heater which is attached to the bottom wall of the melting cavity, the heater is used for heating and melting crushed ice, the processing device also comprises an atomizing cavity which is arranged at the bottom wall of the machine body and is downwards opened, the atomizing cavity is communicated with the melting cavity through a pipeline, a second transmission cavity which is positioned on the upper side of the atomizing cavity is arranged in the machine body, and the top wall of the, the fan wheel shaft outer surface is fixedly provided with a fan wheel located in the atomizing cavity, the bottom end of the fan wheel shaft is fixedly provided with a rotating block located on the lower side of the fan wheel, through holes are formed in the rotating block in an array mode, and when the fan wheel rotates, ice water melted in the melting cavity is pumped into the atomizing cavity and is discharged outside the machine body through the rotating block in an atomizing mode.

4. An automatic de-icing apparatus for an electrical energy transmission high voltage line according to claim 1, characterized in that: the transmission device comprises a motor arranged on the lower side of the second transmission cavity, an output shaft of the motor penetrates through the second transmission cavity and extends to the top of the machine body, a second belt wheel positioned in the second transmission cavity is fixedly arranged on the outer surface of the output shaft, a first spline shaft connected through a spring is arranged on the top end of the output shaft in a spline fit manner, a third bevel gear always engaged with the second bevel gear is fixedly arranged on the top end of the first spline shaft, a fourth sleeve is rotatably arranged on the outer surface of the first spline shaft, the fourth sleeve and the second connecting arm are fixedly connected with each other through a second support, the transmission device further comprises a third belt wheel fixedly arranged on the outer surface of the fan wheel shaft and connected with the second belt wheel through a first belt in a fit manner, and a fourth belt wheel positioned on the lower side of the fan wheel shaft is fixedly arranged on the outer surface of, the bottom wall of the first transmission cavity is rotatably provided with a rotating shaft which penetrates through the second transmission cavity and extends to the top of the machine body, a fifth belt wheel which is located in the first transmission cavity and is connected with the first belt wheel in a matched mode through a second belt is fixedly arranged on the outer surface of the rotating shaft, a sixth belt wheel which is located in the second transmission cavity and is connected with the fourth belt wheel in a matched mode through a third belt is fixedly arranged on the outer surface of the rotating shaft, a second spline shaft connected through a spring is arranged in a spline matched mode on the top of the rotating shaft, a fourth bevel gear which is always meshed with the first bevel gear is fixedly arranged at the top end of the second spline shaft, a fifth sleeve is rotatably arranged on the outer surface of the second spline shaft, and the fifth sleeve and the second connecting rod are fixedly connected with each other through a third support.

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