CN110062559B - Efficient heat dissipation intelligent controller utilizing physical transmission to match flow velocity - Google Patents

Abstract

The invention discloses a high-efficiency heat-dissipation intelligent controller utilizing physical transmission to match with flow velocity, which structurally comprises a controller inner core device, a display, a key and a connecting seat, wherein a thinner straight rod structure is arranged in the middle of a supporting rod, so that a larger gap is formed between every two middle ends of the supporting rod, the heat dissipation effect is further increased, the heat energy consumption in the transmission process is realized, the internal energy is further reduced, the two ends of a transmission inner rod are connected with a transmission rod to realize the heat transmission, a transmission medium is increased, the heat energy is further consumed in the transmission process, the top of an air pipe is attached to a water tank, the fan blades realize indirect cooling by increasing the wind speed, the surface temperature of the transmission rod is reduced under the flowing wind force, the flow velocity is increased by pushing water flow through a pump, the heat energy is continuously taken away by utilizing the flowing water, the final cooling treatment is realized, and the cooling effect, the controller is prevented from being heated and expanded due to the excessively low cooling effect, and the integral temperature rise of the controller is avoided.

Description

Efficient heat dissipation intelligent controller utilizing physical transmission to match flow velocity

Technical Field

The invention relates to an efficient heat dissipation intelligent controller using physical transmission to match with flow velocity, belonging to the field of intelligent controllers.

Background

Because the popularization of electrical apparatus, there are the mechanical product of many different grade types to integrate into the life now, generally can use intelligent control ware to carry out unified control to the electrical apparatus of difference this moment, but because the multiple electrical apparatus of intelligent control ware simultaneous control, the power consumption is great, so the sensor operation burden is great, produces the heat easily, because the long-term operation of some electrical apparatus, the controller is along with the work operation, can continuously heat up, needs certain heat sink, just can guarantee the long-term steady operation of intelligent control ware.

However, the existing intelligent controller has the following disadvantages:

in the aspect of cooling treatment, a simple physical transmission mode is generally adopted for cooling treatment, the treatment mode is that the cooling treatment is carried out by utilizing the transmission of the metal sheet and the radiating fin and the transfer heat, firstly, the energy transmission of the metal sheet and the radiating fin is too simple, the energy transmission medium is too little, and the heat energy consumption effect is lower; secondly, only utilize the transmission of physical medium, unable rapid cooling, sheetmetal and fin volume are great simultaneously, and the internal energy is not good to be consumed, and easy thermal-arrest intensifies, causes the whole intensification of intelligent control ware.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide an efficient heat dissipation intelligent controller utilizing physical transmission to match with flow velocity, so as to solve the problem that in the aspect of temperature reduction treatment, the temperature reduction treatment is generally carried out by adopting a simple physical transmission mode, the treatment mode is to carry out the temperature reduction treatment by utilizing the heat transferred by the metal sheet and the heat radiating fin, firstly, the energy transmission of the metal sheet and the heat radiating fin is too simple, the energy transmission medium is too little, and the heat energy consumption effect is lower; secondly, only utilize the transmission of physical medium, unable rapid cooling, sheetmetal and fin volume are great simultaneously, and the internal energy is not good to be consumed, and easy thermal-arrest intensifies, causes the whole problem that heaies up of intelligent control ware.

In order to achieve the purpose, the invention is realized by the following technical scheme: an efficient heat dissipation intelligent controller utilizing physical transmission to match flow velocity structurally comprises a controller kernel device, a display, a key and a connecting seat, wherein the front end of the controller kernel device is connected with the rear end of the display through a clamping groove, the interior of the display is electrically connected with the interior of the controller kernel device, the interior of the controller kernel device is connected with the bottom of the connecting seat in an embedded mode, the middle end of the connecting seat is fixedly connected with the top of the controller kernel device through a screw, the rear end of the key is movably connected with the front end of the controller kernel device, the interior of the key is electrically connected with the interior of the controller kernel device, a sensor in the controller kernel device can control the display, and therefore the sensor is a main heating source;

the controller kernel device comprises sensor, heat energy transfer piece, connection pad, heat sink, transfer bar, the sensor bottom is the integral structure with the connection pad top, the connection pad bottom is laminated with heat energy transfer piece top mutually, heat energy transfer piece side link up with the transfer bar side end, the transfer bar upper end is connected with the heat sink upper end, both ends pass through dead lever fixed connection about the sensor, and the connection pad top is with the sensor parcel, so and can collect the heat energy that the sensor produced as far as possible and concentrate, realize the transmission of heat energy through heat energy transfer piece simultaneously.

The best, the heat energy transfer piece is by pole, accept board, bracing piece and constitute in the transmission, pole inside and bracing piece bottom integrated structure in the transmission, the bracing piece middle-end with accept the board top and link up mutually, accept pole outer wall fixed connection in inboard and the transmission, pole is the cuboid structure in the transmission, the bracing piece with accept board mutually perpendicular, top and connection pad contact simultaneously, bracing piece quantity is sixteen moreover, enlarges the contact range through increasing quantity, the bracing piece top is little disc simultaneously, the centre is thinner straight pole structure, in the increase of as far as possible and connection pad area of contact, makes great clearance appear in the bracing piece middle-end between two liang, and then increases the radiating effect, realizes the heat energy consumption in the transmission, and then reduces internal energy.

The best, the heat sink comprises water tank, rivers heat sink, ventilation ring structure, tuber pipe, fan leaf, the water tank bottom is connected with rivers heat sink side, rivers heat sink bottom and ventilation ring structure top fixed connection, ventilation ring structure middle-end outer wall link up with tuber pipe top middle-end mutually, tuber pipe bottom and fan leaf outer wall are clearance fit, fan leaf rear end is connected through the bearing with the tuber pipe is inside, laminating mutually in transmission pole upper end left side and the ventilation ring structure middle-end, water tank internally mounted has the pump machine, drives rivers at the inside flow of rivers heat sink through the pump machine, and fan leaf rear end is connected with the micromotor simultaneously, realizes indirect cooling through increasing the wind speed.

The best, rivers heat sink comprises point-end probe, cyclic annular connecting pipe, point-end probe top is the circular cone structure, point-end probe outer wall laminates with cyclic annular connecting pipe inner wall mutually, cyclic annular connecting pipe encircles point-end probe, and there is certain arc at point-end probe top, connects the arc circle of face through the cooperation water tank, increases area of contact, improves the cooling effect, and the pump machine is being connected at cyclic annular connecting pipe both ends simultaneously, promotes rivers through the pump machine and increases the velocity of flow, takes away the heat energy of point-end probe upper end.

The best, the ventilation ring structure comprises montant, wind-driven ring, four corner stabilizer bar, annular tight piece of subsides, montant bottom and wind-driven ring top structure as an organic whole, the inside and four corner stabilizer bar side end welding of wind-driven ring, the inboard side end fixed connection of annular tight piece of subsides of four corner stabilizer bar, montant top and the contact of most advanced probe bottom, the transmission pole is with heat energy transmission to annular tight piece of subsides simultaneously, increases heat energy transmission rate, there is the gap wind-driven ring with the transmission pole outer wall simultaneously, the gap diameter is equal to the length of annular tight piece of subsides and four corner stabilizer bar, and the tuber pipe link up between wind-driven ring and transmission pole simultaneously, and for endless confined space, top laminating water tank, increases the indirect cooling of wind speed realization through the fan leaf.

Optimally, the water accessible outside of water tank temple is observed, prevents excessively, and the water tank top is the funnel structure simultaneously, makes things convenient for the water injection.

Advantageous effects

When the controller is used, the display can be controlled by the sensor in the controller core device, so that the sensor is a main heating source, the heat generated by the sensor is collected by the connecting disc, then is transmitted to the heat energy transmission block, and finally is transmitted to the cooling device by the transmission rod, the heat generated by the sensor is collected by the connecting disc, the sensor is wrapped at the top of the connecting disc, so that the heat energy generated by the sensor can be collected and concentrated as much as possible, the supporting rod is vertical to the receiving plate, the top of the supporting rod is in contact with the connecting disc, the supporting rod is sixteen in number, the contact range is enlarged by increasing the number, meanwhile, the top of the supporting rod is a small disc, the middle of the supporting rod is a thin straight rod structure, the contact area between the middle ends of the supporting rod and the connecting disc is increased as much as possible, the heat dissipation effect is further increased, the heat energy consumption inner rod in, the heat transfer is realized, a transfer medium is increased, heat energy is further consumed in the transfer process, the transfer rod transfers the heat energy to the annular attaching block, the heat energy transmission speed is increased, meanwhile, a gap exists between the pneumatic ring and the outer wall of the transfer rod, the diameter of the gap is equal to the length of the annular attaching block and the four-corner stabilizing rod, the air pipe penetrates between the pneumatic ring and the transfer rod and is a circulating closed space, the top of the air pipe is attached to a water tank (the air can be relatively cooled through the vicinity of the water tank), the rear end of a fan blade is connected with a small motor, indirect cooling is realized by increasing the air speed, the surface temperature of the transfer rod is reduced under the flowing wind power, the heat energy is further reduced, the internal energy of the transfer rod sequentially passes through the annular attaching block and the four-corner stabilizing rod to enter the pneumatic ring and then enters the water flow cooling device through the vertical rod, a certain arc, increase area of contact, improve the cooling effect, water tank internally mounted has the pump machine, drives rivers through the pump machine and at the inside flow of rivers heat sink, and the pump machine is connected with cyclic annular connecting pipe both ends, promotes rivers through the pump machine and increases the velocity of flow, takes away the heat energy of most advanced probe upper end, utilizes the water that flows, continuously takes away heat energy, realizes final cooling and handles.

Compared with the prior art, the invention has the following advantages:

1. bracing piece and accepting board mutually perpendicular, top and connection pad contact simultaneously, and bracing piece quantity is sixteen, enlarge the contact range through increasing quantity, the bracing piece top is little disc simultaneously, the centre is thin straight pole structure, in the increase of as far as possible and connection pad area of contact, make great clearance appear between two liang of the bracing piece middle-end, and then increase the radiating effect, realize the heat energy consumption in the transmission course, and then reduce the internal energy, pole both ends are connected with the transmission pole in the transmission, realize thermal transmission, increase the transmission medium, and then consume heat energy in the transmission course.

2. The tuber pipe link up between pnematic ring and transmission pole, and be the airtight space of circulation, and tuber pipe top laminating water tank (wind passes through near the water tank and can lower the temperature relatively), the fan leaf realizes the indirectness cooling through increasing the wind speed, make the transmission pole under the wind-force of flow, reduce surface temperature, further reduce heat energy, there is certain arc at most advanced probe top, the arc circle of connecting the face through the cooperation water tank, increase area of contact, improve the cooling effect, promote rivers through the pump machine simultaneously and increase the velocity of flow, take away the heat energy of most advanced probe upper end, utilize the water that flows, heat energy is continuously taken away, realize final cooling treatment, improve the cooling effect through the mode that utilizes physics transmission and air current cooling, prevent that the controller from crossing low owing to the cooling effect, cause the expansion of being heated, avoid the whole intensifi.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic structural diagram of an intelligent controller for efficient heat dissipation using physical transmission in cooperation with flow rate according to the present invention;

FIG. 2 is a bottom sectional view of the controller core apparatus of the present invention;

FIG. 3 is an enlarged view of the heat transfer block of FIG. 2 in accordance with the present invention;

FIG. 4 is a schematic structural view of a thermal energy transfer block of the present invention;

FIG. 5 is an enlarged view of the cooling device of FIG. 2 according to the present invention;

FIG. 6 is an enlarged view of the water flow cooling device of FIG. 5 in accordance with the present invention;

fig. 7 is a right side sectional view of the vent ring structure of the present invention.

In the figure: the device comprises a controller kernel device-1, a display-2, a key-3, a connecting seat-4, a sensor-11, a heat energy transfer block-12, a connecting disc-13, a cooling device-14, a transfer rod-15, a transfer inner rod-121, a bearing plate-122, a support rod-123, a water tank-141, a water flow cooling device-142, a ventilation ring structure-143, an air pipe-144, a fan blade-145, a tip probe-1421, an annular connecting pipe-1422, a vertical rod-1431, a pneumatic ring-1432, a four-corner stabilizer bar-1433 and an annular attaching block-1434.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Referring to fig. 1, the present invention provides a technical solution of an intelligent controller for efficient heat dissipation using physical transmission in cooperation with flow rate: the structure of the controller core device comprises a controller core device 1, a display 2, a key 3 and a connecting seat 4, wherein the front end of the controller core device 1 is connected with the rear end of the display 2 through a clamping groove, the inside of the display 2 is electrically connected with the inside of the controller core device 1, the inside of the controller core device 1 is connected with the bottom of the connecting seat 4 in an embedded manner, the middle end of the connecting seat 4 is fixedly connected with the top of the controller core device 1 through a screw, the rear end of the key 3 is movably connected with the front end of the controller core device 1, the inside of the key 3 is electrically connected with the inside of the controller core device 1, a sensor 11 in the controller core device 1 can control the display 2, and therefore, the sensor 11 is a main heating source;

referring to fig. 2, the controller core device 1 is composed of a sensor 11, a thermal energy transfer block 12, a connection disc 13, a cooling device 14 and a transfer rod 15, the bottom of the sensor 11 and the top of the connection disc 13 are of an integrated structure, the bottom of the connection disc 13 is attached to the top of the thermal energy transfer block 12, the side end of the thermal energy transfer block 12 is communicated with the side end of the transfer rod 15, the upper end of the transfer rod 15 is connected with the upper end of the cooling device 14, the left end and the right end of the sensor 11 are fixedly connected through fixing rods, and the sensor 11 is wrapped by the top of the connection disc 13, so that the thermal energy generated by the sensor 11 can be collected and concentrated as much as possible, meanwhile, the heat energy transfer is realized through the thermal energy transfer block 12, the heat generated by the sensor 11 is collected by the connection disc 13, then transferred to.

Referring to fig. 3 to 4, the heat energy transfer block 12 is composed of a transfer inner rod 121, a receiving plate 122, and a support rod 123, the interior of the transfer inner rod 121 and the bottom of the support rod 123 are integrated, the middle end of the support rod 123 is communicated with the top of the receiving plate 122, the interior of the receiving plate 122 is fixedly connected with the outer wall of the transfer inner rod 121, the transfer inner rod 121 is of a rectangular structure, the support rod 123 and the receiving plate 122 are perpendicular to each other, the top of the support rod 123 is in contact with the connecting disc 13, the number of the support rods 123 is sixteen, the contact range is enlarged by increasing the number, meanwhile, the top of the support rod 123 is a small circular disc, the middle of the support rod 123 is a thin straight rod structure, while the contact area with the connecting disc 13 is increased as much as possible, a large gap is formed between the middle ends of the support rod 123, the heat dissipation effect is increased, the heat transfer is realized, the transfer medium is increased, and then the heat energy is consumed in the transfer process.

Referring to fig. 5, the cooling device 14 includes a water tank 141, a water flow cooling device 142, a ventilation ring structure 143, an air pipe 144, and fan blades 145, the bottom of the water tank 141 is connected to the side end of the water flow cooling device 142, the bottom of the water flow cooling device 142 is fixedly connected to the top of the ventilation ring structure 143, the outer wall of the middle end of the ventilation ring structure 143 is communicated with the middle end of the top of the air pipe 144, the bottom of the air pipe 144 is in clearance fit with the outer wall of the fan blades 145, the rear end of the fan blades 145 is connected to the inside of the air pipe 144 through a bearing, the left side of the upper end of the transmission rod 15 is attached to the middle end of the ventilation ring structure 143, a pump is installed inside the water tank 141, the pump drives water flow inside the water flow cooling device 142, and the rear end of the fan blades 145 is connected to a small motor, so that indirect, the surface temperature is reduced further reducing the thermal energy, while the internal energy is transferred to the vent ring structure 143.

Referring to fig. 6, the water flow cooling device 142 includes a tip probe 1421 and an annular connecting pipe 1422, the top of the tip probe 1421 is a conical structure, the outer wall of the tip probe 1421 is attached to the inner wall of the annular connecting pipe 1422, the tip probe 1421 is surrounded by the annular connecting pipe 1422, a certain arc shape exists at the top of the tip probe 1421, the contact area is increased by matching with an arc ring of the connecting surface of the water tank 141, the cooling effect is improved, meanwhile, the two ends of the annular connecting pipe 1422 are connected to a pump, the flow rate is increased by pushing water flow through the pump, heat energy at the upper end of the tip probe 1421 is taken away, flowing water is used to continuously take away heat energy, and the final cooling treatment is.

Referring to fig. 7, the ventilation ring structure 143 includes a vertical rod 1431, a pneumatic ring 1432, a four-corner stabilizer 1433, and an annular attachment block 1434, the bottom of the vertical rod 1431 and the top of the pneumatic ring 1432 are integrated, the interior of the pneumatic ring 1432 is welded to the side end of the four-corner stabilizer 1433, the inner side of the four-corner stabilizer 1433 is fixedly connected to the side end of the annular attachment block 1434, the top of the vertical rod 1431 contacts with the bottom of the tip probe 1421, the transmission rod 15 transmits heat energy to the annular attachment block 1434 to increase the heat energy transmission rate, the pneumatic ring 1432 has a gap with the outer wall of the transmission rod 15, the diameter of the gap is equal to the length of the annular attachment block 1434 and the four-corner stabilizer 1433, the air duct 144 runs through between the pneumatic ring 1432 and the transmission rod 15 and is a circulating closed space, the top is attached to the water tank 141, the wind speed is increased by the fan blade 145 to realize indirect cooling, the, The four corner stabilizer bar 1433 enters the pneumatic ring 1432 and then enters the water flow cooling device 142 through the vertical bar 1431.

The water accessible outside observation of water tank 141 temple prevents excessively, and water tank 141 top is the funnel structure simultaneously, makes things convenient for the water injection.

When the controller is used, the sensor 11 in the controller core device 1 can control the display 2, so the sensor 11 is a main heating source, the sensor 11 heats, the heat is collected by the connecting disc 13, then transmitted to the heat energy transmission block 12, and finally transmitted to the cooling device 14 by the transmission rod 15, the heat is collected by the connecting disc 13 by the sensor 11, the sensor 11 is wrapped by the top of the connecting disc 13, so the heat energy generated by the sensor 11 can be collected and concentrated as much as possible, the supporting rod 123 is vertical to the bearing plate 122, the top of the supporting rod is contacted with the connecting disc 13, the number of the supporting rod 123 is sixteen, the contact range is enlarged by increasing the number, the top of the supporting rod 123 is a small disc, the middle of the supporting rod is a thin straight rod structure, the contact area with the connecting disc 13 is increased as much as possible, a large gap is formed between the middle ends of the supporting rod 123, the heat dissipation effect is increased, further reducing the internal energy, the two ends of the inner transmission rod 121 are connected with the transmission rod 15 to realize heat transmission, increasing transmission media and further consuming heat energy in the transmission process, because the transmission rod 15 transmits the heat energy to the annular attaching block 1434 to increase the heat energy transmission rate, and at the same time, a gap exists between the pneumatic ring 1432 and the outer wall of the transmission rod 15, the diameter of the gap is equal to the length of the annular attaching block 1434 and the four corners 1433, and at the same time, the air pipe 144 runs through between the pneumatic ring 1432 and the transmission rod 15 and is a circulating closed space, and the top of the air pipe 144 is attached to the water tank 141 (the air can be relatively cooled through the vicinity of the water tank 141), the rear end of the fan blade 145 is connected with a small motor to realize indirect cooling by increasing the air speed, so that the surface temperature of the transmission rod 15 is reduced under the flowing wind force, further reducing the heat energy, and the internal energy of the transmission rod 15 enters the pneumatic, get into rivers heat sink 142 through montant 1431 again, there is certain arc at tip probe 1421 top, connect the arc circle of face through cooperation water tank 141, increase area of contact, improve the cooling effect, water tank 141 internally mounted has the pump machine, drive rivers at the inside flow of rivers heat sink 142 through the pump machine, and the pump machine is connected with cyclic annular connecting pipe 1422 both ends, promote rivers through the pump machine and increase the velocity of flow, take away the heat energy of tip probe 1421 upper end, utilize the water that flows, heat energy is continuously taken away, realize final cooling and handle.

The invention solves the problem that in the aspect of cooling treatment, the cooling treatment is generally carried out by adopting a simple physical transmission mode, the treatment mode is to carry out the cooling treatment by utilizing the heat transferred by the metal sheet and the radiating fin, firstly, the energy transmission of the metal sheet and the radiating fin is too simple, the energy transmission medium is too little, and the heat energy consumption effect is lower; secondly, the temperature can not be quickly reduced only by utilizing the transmission of physical media, meanwhile, the metal sheet and the radiating fins have larger volumes and are not easy to consume, the heat collection and the temperature rise are easy, and the integral temperature rise of the intelligent controller is caused, the invention has the advantages that through the mutual combination of the components, the supporting rod and the bearing plate are mutually vertical, meanwhile, the top part is contacted with the connecting disc, the number of the supporting rod is sixteen, the contact range is enlarged by increasing the number, meanwhile, the top part of the supporting rod is a small disc, the middle part is a thin straight rod structure, the contact area with the connecting disc is increased as much as possible, meanwhile, a larger gap is formed between the middle ends of the supporting rods, the heat dissipation effect is further increased, the heat energy consumption in the transmission process is realized, the internal energy is further reduced, the two ends of the transmission inner rod are connected with the transmission rod, the heat transmission is, and be the airtight space of circulation, and the laminating water tank in tuber pipe top (wind can relatively cool down near through the water tank), the fan leaf realizes the indirectness cooling through increasing the wind speed, make the transmission pole under the wind-force that flows, reduce surface temperature, further reduce heat energy, there is certain arc at most advanced probe top, through the arc circle of cooperation water tank connection face, increase area of contact, improve the cooling effect, promote rivers through the pump simultaneously and increase the velocity of flow, take away the heat energy of most advanced probe upper end, utilize the water that flows, heat energy is continuously taken away, realize ultimate cooling and handle, improve the cooling effect through the mode that utilizes physics transmission and air current cooling, prevent that the controller from because the cooling effect is low excessively, cause the expansion of being heated, avoid the controller whole intensification.

The foregoing merely illustrates the principles and preferred embodiments of the invention and many variations and modifications may be made by those skilled in the art in light of the foregoing disclosure, which are intended to be within the scope of the invention.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (1)

1. The utility model provides an utilize high-efficient heat dissipation intelligent control ware of physics transmission cooperation velocity of flow, its structure includes controller kernel device (1), display (2), button (3), connecting seat (4), its characterized in that:

the front end of the controller kernel device (1) is connected with the rear end of the display (2) through a clamping groove, the inside of the display (2) is electrically connected with the inside of the controller kernel device (1), the inside of the controller kernel device (1) is connected with the bottom of the connecting seat (4) in an embedded mode, the middle end of the connecting seat (4) is fixedly connected with the top of the controller kernel device (1) through a screw, the rear end of the key (3) is movably connected with the front end of the controller kernel device (1), and the inside of the key (3) is electrically connected with the inside of the controller kernel device (1);

the controller core device (1) is composed of a sensor (11), a heat energy transfer block (12), a connecting disc (13), a cooling device (14) and a transfer rod (15), the bottom of the sensor (11) and the top of the connecting disc (13) are of an integrated structure, the bottom of the connecting disc (13) is attached to the top of the heat energy transfer block (12), the side end of the heat energy transfer block (12) is communicated with the side end of the transfer rod (15), the upper end of the transfer rod (15) is connected with the upper end of the cooling device (14), and the left end and the right end of the sensor (11) are fixedly connected through fixing rods;

the heat energy transfer block (12) is composed of a transfer inner rod (121), a bearing plate (122) and a support rod (123), the interior of the transfer inner rod (121) and the bottom of the support rod (123) are of an integrated structure, the middle end of the support rod (123) is communicated with the top of the bearing plate (122), the interior of the bearing plate (122) is fixedly connected with the outer wall of the transfer inner rod (121), and the transfer inner rod (121) is of a cuboid structure;

the cooling device (14) consists of a water tank (141), a water flow cooling device (142), a ventilation ring structure (143), an air pipe (144) and fan blades (145), the bottom of the water tank (141) is connected with the side end of the water flow cooling device (142), the bottom of the water flow cooling device (142) is fixedly connected with the top of the ventilation ring structure (143), the outer wall of the middle end of the ventilation ring structure (143) is communicated with the middle end of the top of the air pipe (144), the bottom of the air pipe (144) is in clearance fit with the outer wall of the fan blades (145), the rear end of the fan blades (145) is connected with the inside of the air pipe (144) through bearings, and the left side of the upper end of the transmission rod (15) is attached to the middle end of the ventilation ring;

the water flow cooling device (142) comprises a tip probe (1421) and an annular connecting pipe (1422), the top of the tip probe (1421) is of a conical structure, the outer wall of the tip probe (1421) is attached to the inner wall of the annular connecting pipe (1422), and the annular connecting pipe (1422) surrounds the tip probe (1421);

the ventilation ring structure (143) comprises a vertical rod (1431), a pneumatic ring (1432), a four-corner stabilizing rod (1433) and an annular attaching block (1434), the bottom of the vertical rod (1431) and the top of the pneumatic ring (1432) are of an integrated structure, the interior of the pneumatic ring (1432) is welded with the side end of the four-corner stabilizing rod (1433), and the inner side of the four-corner stabilizing rod (1433) is fixedly connected with the side end of the annular attaching block (1434).

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