CN111156722A

CN111156722A - Efficient liquid stirring type wind power heating equipment

Info

Publication number: CN111156722A
Application number: CN202010009916.9A
Authority: CN
Inventors: 刘晓思
Original assignee: Guangdong Jirun Enterprise Management Co Ltd
Current assignee: Nantong Kaitaike Energy Technology Co ltd
Priority date: 2020-01-06
Filing date: 2020-01-06
Publication date: 2020-05-15
Anticipated expiration: 2040-01-06
Also published as: CN111156722B

Abstract

The invention relates to high-efficiency liquid stirring type wind power heating equipment, which comprises a main body, a first fan blade, a transmission shaft, a first bearing and two water pipes, wherein the main body is in a cuboid shape, the two water pipes are respectively arranged at two sides of the main body and are communicated with each other through the main body, a mounting hole is formed in the top of the main body, the transmission shaft vertically penetrates through the mounting hole, the transmission shaft is in sliding and sealing connection with the inner wall of the mounting hole, the first fan blade is arranged at the top end of the transmission shaft, the first fan blade is positioned on the vertical fan blade, the first bearing is positioned between the first fan blade and the main body, the inner ring of the first bearing is arranged on the transmission shaft, a stirring mechanism and an auxiliary mechanism are arranged in the main body, and the high-efficiency liquid stirring type wind power heating equipment realizes the function of improving the heating efficiency through the stirring mechanism, moreover, the heating efficiency is further improved through the auxiliary mechanism.

Description

Efficient liquid stirring type wind power heating equipment

Technical Field

The invention relates to the field of heating equipment, in particular to high-efficiency liquid stirring type wind power heating equipment.

Background

The stirring liquid heater is one kind of heating equipment, and has driving stirrer rotor with several blades to rotate; on the inner wall of the heating tub, there are also a plurality of blades (stators) between the blades corresponding to the rotor. Cold water (oil can also be used as a medium) is injected into the heating barrel, and the hot water tank is connected with the heating barrel through a pipeline. When the rotor rotates, water is stirred to form a vortex, and the flowing water generates friction and impact with the blades, the inner wall of the barrel and water flow particles to generate heat, so that the temperature of the water is gradually increased.

Stirring liquid heating ware is in the use, and the mode of heating is comparatively single, leads to the speed of producing heat to be slower, has reduced practicality and heating efficiency.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: in order to overcome the defects of the prior art, the high-efficiency liquid stirring type wind power heating equipment is provided.

The technical scheme adopted by the invention for solving the technical problems is as follows: a high-efficiency liquid stirring type wind power heating device comprises a main body, a first fan blade, a transmission shaft, a first bearing and two water pipes, wherein the main body is cuboid in shape, the two water pipes are respectively arranged on two sides of the main body and are communicated with each other through the main body, a mounting hole is formed in the top of the main body, the transmission shaft vertically penetrates through the mounting hole, the transmission shaft is connected with the inner wall of the mounting hole in a sliding and sealing mode, the first fan blade is installed at the top end of the transmission shaft and located on a vertical fan blade, the first bearing is located between the first fan blade and the main body, the inner ring of the first bearing is installed on the transmission shaft, the outer ring of the first bearing is fixedly connected with the top of the main body, and a stirring mechanism and an auxiliary mechanism are arranged in;

the stirring mechanism comprises a driving gear, two stirring rods and two stirring components, the axes of the stirring rods are perpendicular to and intersected with the axis of the transmission shaft, the stirring rods are circumferentially and uniformly fixed on the transmission shaft by taking the axis of the transmission shaft as a center, the driving gear is arranged on the transmission shaft and is positioned on one side of the stirring rods close to the first fan blade, and the stirring components are in one-to-one correspondence with the stirring rods and are arranged on one side of the stirring rods close to the first fan blade;

the stirring assembly comprises a driven gear, a second bearing, a connecting shaft, a fixed pipe and a screw rod, the fixed pipe is parallel to the transmission shaft, the fixed pipe is fixedly connected with the inner wall of the main body, the screw rod is arranged in the fixed pipe and coaxially arranged with the fixed pipe, the screw rod is matched with the fixed pipe, the screw rod is in sliding and sealing connection with the inner wall of the fixed pipe, the connecting shaft is coaxially arranged with the screw rod, the bottom end of the connecting shaft is fixed at the top end of the screw rod, the inner ring of the second bearing is installed at the top end of the connecting shaft, the outer ring of the second bearing is fixedly connected with the inner wall of the main body, and the driven gear is installed;

the auxiliary mechanism comprises an auxiliary pipe, a driving bevel gear, two wind power assemblies, two air pipes and two sealing assemblies, wherein the auxiliary pipe is perpendicular to and intersected with the axis of the transmission shaft, two ends of the auxiliary pipe are respectively sealed and fixedly connected with the inner walls of two sides of the main body, the auxiliary pipe is positioned on one side of the stirring rod, which is far away from the first fan blade, a through hole is formed in the top end of the auxiliary pipe, the transmission shaft penetrates through the through hole, the transmission shaft is in sliding and sealing connection with the inner walls of the through hole, the air pipes are parallel to the transmission shaft and are in one-to-one correspondence with the fixed pipes, two connecting holes are formed in the top of the main body and are in one-to-one correspondence with the air pipes, the top ends of the air pipes are inserted into the connecting holes, the air pipes are in sealing and fixed connection with the inner walls of the connecting holes, the, the wind power assembly is arranged in the auxiliary pipe and is in one-to-one correspondence with the fixed pipe, the wind power assembly is located between the axes of the two air pipes, and the sealing assembly is in one-to-one correspondence with the air pipes and is arranged at the top of the main body.

Preferably, in order to realize the directional flow of air in the auxiliary pipe, the wind power assembly comprises a driven bevel gear, a third bearing, a power shaft and a second fan blade, the power shaft is parallel to the auxiliary pipe, the driven bevel gear is mounted at one end of the power shaft and meshed with the driving bevel gear, the second fan blade is mounted at the other end of the power shaft, an inner ring of the third bearing is mounted on the power shaft, and an outer ring of the third bearing is fixedly connected with the inner wall of the auxiliary pipe.

Preferably, the number of teeth of the driving bevel gear is greater than the number of teeth of the driven bevel gear in order to increase the flow rate of air in the subsidiary pipe.

As preferred, in order to realize the function of sealing the trachea, the seal assembly includes pilot hole, sealed dish, carriage release lever, connecting rod, pipe, two springs and two inflation pieces, the pilot hole sets up the top at the main part, the pipe is parallel with the transmission shaft, the pipe passes the pilot hole, the sealed and fixed connection of inner wall of pipe and pilot hole, the carriage release lever sets up the middle-end in the pipe and coaxial setting with the pipe, the inner wall slip and the sealing connection of carriage release lever and pipe, spring and inflation piece all are located the pipe, two inflation pieces are fixed respectively on the inner wall at pipe both ends, the spring just is located between carriage release lever and the inflation piece with inflation piece one-to-one, the carriage release lever passes through the spring and is connected with the inflation piece, one side of pipe that is close to the transmission shaft is equipped with the sliding tray, the sliding tray is located between two springs, the axis of connecting rod is perpendicular and crossing with the axis of carriage release lever, the connecting rod pass the sliding tray and with the inner wall sliding connection of sliding tray, sealed dish and the coaxial setting of trachea, the diameter of sealed dish is greater than tracheal external diameter and equals, the top laminating and the sealing connection of sealed dish and main part, sealed dish is located between connecting rod and the main part, the one end of connecting rod is fixed on the carriage release lever, the other end and the sealed dish fixed connection of connecting rod.

Preferably, the sealing disc is made of rubber for achieving buffering and vibration reduction.

Preferably, in order to reduce a gap between the transmission shaft and an inner wall of the mounting hole, the inside of the mounting hole is coated with a sealing grease.

Preferably, in order to improve the heating efficiency, two heat conducting rods are arranged on one sides of the two air pipes close to the axis of the transmission shaft, the heat conducting rods are parallel to the stirring rod, two through holes are formed in the air pipes, the through holes correspond to the heat conducting rods one to one, the heat conducting rods penetrate through the through holes, the heat conducting pipes are sealed and fixedly connected with the inner walls of the through holes, and the stirring rod is located between the two heat conducting rods and is abutted against the heat conducting rods.

Preferably, in order to prolong the service life of the auxiliary pipe, the auxiliary pipe is provided with an anti-corrosion zinc coating.

Preferably, in order to facilitate the installation of the transmission shaft, chamfers are arranged at both ends of the transmission shaft.

Preferably, the drive gear is coated with grease in order to reduce friction between the drive gear and the driven gear.

The efficient liquid stirring type wind power heating equipment has the advantages that the efficient liquid stirring type wind power heating equipment achieves the function of improving the heating efficiency through the stirring mechanism, compared with the existing stirring mechanism, the stirring mechanism is ingenious in structure and high in practicability, the heating efficiency is further improved through the auxiliary mechanism, compared with the existing auxiliary mechanism, the auxiliary mechanism achieves the function of mechanically and automatically detecting the air temperature outside the main body and the water temperature inside the main body, and the anti-interference capability is high.

Drawings

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

FIG. 1 is a schematic structural view of a high efficiency type liquid stirring type wind power heating apparatus of the present invention;

FIG. 2 is a schematic structural diagram of a stirring mechanism of the high-efficiency liquid stirring type wind power heating equipment;

FIG. 3 is a schematic structural diagram of an auxiliary mechanism of the high-efficiency liquid stirring type wind power heating equipment of the invention;

FIG. 4 is an enlarged view of portion A of FIG. 1;

FIG. 5 is a schematic view of the installation structure of the heat conduction rod of the high-efficiency liquid stirring type wind power heating apparatus of the present invention;

in the figure: 1. the fan comprises a main body, 2, a first fan blade, 3, a transmission shaft, 4, a first bearing, 5, a water pipe, 6, a driving gear, 7, a stirring rod, 8, a driven gear, 9, a second bearing, 10, a connecting shaft, 11, a fixed pipe, 12, a screw rod, 13, an auxiliary pipe, 14, a driving bevel gear, 15, an air pipe, 16, a driven bevel gear, 17, a third bearing, 18, a power shaft, 19, a second fan blade, 20, a sealing disc, 21, a moving rod, 22, a connecting rod, 23, a guide pipe, 24, a spring, 25, an expansion block and 26, and a heat conducting rod.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

As shown in fig. 1-2, a high-efficiency liquid stirring type wind power heating device comprises a main body 1, a first fan blade 2, a transmission shaft 3, a first bearing 4 and two water pipes 5, the main body 1 is cuboid, two water pipes 5 are respectively arranged at two sides of the main body 1, the two water pipes 5 are communicated through the main body 1, the top of the main body 1 is provided with a mounting hole, the transmission shaft 3 vertically penetrates through the mounting hole, the transmission shaft 3 is connected with the inner wall of the mounting hole in a sliding and sealing way, the first fan blade 2 is arranged at the top end of the transmission shaft 3, the first fan blade 2 is positioned on the vertical fan blade, the first bearing 4 is positioned between the first fan blade 2 and the main body 1, the inner ring of the first bearing 4 is arranged on the transmission shaft 3, the outer ring of the first bearing 4 is fixedly connected with the top of the main body 1, and a stirring mechanism and an auxiliary mechanism are arranged in the main body 1;

the stirring mechanism comprises a driving gear 6, two stirring rods 7 and two stirring components, the axes of the stirring rods 7 are perpendicular to and intersected with the axis of the transmission shaft 3, the stirring rods 7 are circumferentially and uniformly fixed on the transmission shaft 3 by taking the axis of the transmission shaft 3 as a center, the driving gear 6 is arranged on the transmission shaft 3 and is positioned on one side of the stirring rods 7 close to the first fan blade 2, and the stirring components are in one-to-one correspondence with the stirring rods 7 and are arranged on one side of the stirring rods 7 close to the first fan blade 2;

the stirring assembly comprises a driven gear 8, a second bearing 9, a connecting shaft 10, a fixed pipe 11 and a screw 12, the fixed pipe 11 is parallel to the transmission shaft 3, the fixed pipe 11 is fixedly connected with the inner wall of the main body 1, the screw 12 is arranged in the fixed pipe 11 and coaxially arranged with the fixed pipe 11, the screw 12 is matched with the fixed pipe 11, the screw 12 is connected with the inner wall of the fixed pipe 11 in a sliding and sealing manner, the connecting shaft 10 is coaxially arranged with the screw 12, the bottom end of the connecting shaft 10 is fixed at the top end of the screw 12, the inner ring of the second bearing 9 is arranged at the top end of the connecting shaft 10, the outer ring of the second bearing 9 is fixedly connected with the inner wall of the main body 1, and the driven gear 8 is arranged on the connecting shaft 10 and meshed;

water is conveyed into the main body 1 through one of the water pipes 5, then the first fan blades 2 are rotated through environmental wind power, so that the transmission shaft 3 drives the stirring rod 7 to rotate under the supporting action of the first bearing 4, water in the main body 1 generates friction and realizes heating through the rotation of the stirring rod 7, water after heating is discharged from the other water pipe 5, during the heating, the rotation of the transmission shaft 3 drives the driving gear 6 to rotate, the rotation of the driving gear 6 drives the driven gear 8 to rotate, so that the connecting shaft 10 rotates under the supporting action of the second bearing 9, the rotation of the connecting shaft 10 drives the screw rod 12 to rotate in the fixed pipe 11, clear water in the fixed pipe 11 flows towards the direction close to the stirring rod 7, the friction mode and the friction strength of the water can be increased, and the water heating efficiency can be improved.

As shown in fig. 3, the auxiliary mechanism includes an auxiliary tube 13, a driving bevel gear 14, two wind power assemblies, two air tubes 15 and two sealing assemblies, the auxiliary tube 13 is perpendicular to and intersects with the axis of the transmission shaft 3, two ends of the auxiliary tube 13 are respectively and fixedly connected with the inner walls of two sides of the main body 1, the auxiliary tube 13 is located on one side of the stirring rod 7 away from the first fan blade 2, a through hole is formed in the top end of the auxiliary tube 13, the transmission shaft 3 passes through the through hole, the transmission shaft 3 is in sliding and sealing connection with the inner walls of the through hole, the air tubes 15 are parallel to the transmission shaft 3 and in one-to-one correspondence with the fixed tubes 11, two connecting holes are formed in the top of the main body 1, the connecting holes are in one-to-one correspondence with the air tubes 15, the top ends of the air tubes 15 are inserted into the connecting holes, the air tubes 15 are in, the air pipes 15 are communicated with the auxiliary pipe 13, the driving bevel gear 14 is located in the auxiliary pipe 13 and is installed at the bottom end of the transmission shaft 3, the wind power assemblies are arranged in the auxiliary pipe 13 and correspond to the fixed pipes 11 one by one, the wind power assemblies are located between the axes of the two air pipes 15, and the sealing assemblies correspond to the air pipes 15 one by one and are arranged at the top of the main body 1.

The air temperature outside the main body 1 and the water temperature inside the main body 1 can be detected through the sealing assembly, when the air temperature outside the main body 1 is higher than the water temperature inside the main body 1, the air pipes 15 are in a dredging state, the rotation of the transmission shaft 3 drives the bevel gear 14 to rotate, the rotation of the bevel gear 14 enables the air inside the auxiliary pipe 13 to realize directional flow through the wind power assembly, so that the air outside the main body 1 is conveyed into the auxiliary pipe 13 through one of the air pipes 15, the air inside the auxiliary pipe 13 is discharged from the other air pipe 15, here, the temperature of the air inside the auxiliary pipe 13 is transmitted into the water inside the main body 1 through the auxiliary pipe 13, the temperature of the water inside the main body 1 is further improved, the heating efficiency is further improved, when the air temperature outside the main body 1 is lower than the water temperature inside the main body 1, the two air pipes 15 are in a sealing state through the sealing assembly, so that the, the water temperature in the main body 1 is prevented from losing, and heat preservation is realized.

Preferably, in order to realize the directional flow of air in the auxiliary pipe 13, the wind power assembly comprises a driven bevel gear 16, a third bearing 17, a power shaft 18 and a second fan blade 19, wherein the power shaft 18 is parallel to the auxiliary pipe 13, the driven bevel gear 16 is installed at one end of the power shaft 18 and is meshed with the driving bevel gear 14, the second fan blade 19 is installed at the other end of the power shaft 18, the inner ring of the third bearing 17 is installed on the power shaft 18, and the outer ring of the third bearing 17 is fixedly connected with the inner wall of the auxiliary pipe 13.

The rotation of the transmission shaft 3 drives the driving bevel gear 14 to rotate, the rotation of the driving bevel gear 14 drives the driven bevel gear 16 to rotate, the rotation of the driven bevel gear 16 enables the power shaft 18 to drive the second fan blades 19 to rotate under the supporting action of the third bearing 17, and the rotation of the second fan blades 19 enables the air in the auxiliary pipe 13 to realize unidirectional flow, so that the air in the auxiliary pipe 13 can directionally flow.

Preferably, the number of teeth of the driving bevel gear 14 is greater than that of the driven bevel gear 16 in order to increase the flow rate of air in the auxiliary duct 13.

In the gear transmission, the number of teeth is inversely proportional to the rotation speed, so that the rotation speed of the driven bevel gear 16, that is, the rotation speed of the second fan blade 19, the flow rate of air in the auxiliary pipe 13, and the heating efficiency are further improved.

As shown in fig. 4, the sealing assembly includes an assembly hole, a sealing disc 20, a moving rod 21, a connecting rod 22, a guide tube 23, two springs 24 and two expansion blocks 25, the assembly hole is disposed at the top of the main body 1, the guide tube 23 is parallel to the transmission shaft 3, the guide tube 23 passes through the assembly hole, the guide tube 23 is hermetically and fixedly connected with the inner wall of the assembly hole, the moving rod 21 is disposed at the middle end of the guide tube 23 and is coaxially disposed with the guide tube 23, the moving rod 21 is slidably and hermetically connected with the inner wall of the guide tube 23, the springs 24 and the expansion blocks 25 are both disposed in the guide tube 23, the two expansion blocks 25 are respectively fixed on the inner walls at both ends of the guide tube 23, the springs 24 are one-to-one corresponding to the expansion blocks 25 and are disposed between the moving rod 21 and the expansion blocks 25, the moving rod 21 is connected with the expansion blocks 25 through the springs 24, one side of the, the draw runner is located between two springs 24, the axis of connecting rod 22 is perpendicular and crossing with the axis of carriage release lever 21, connecting rod 22 pass the draw runner and with the inner wall sliding connection of draw runner, sealed dish 20 and the coaxial setting of trachea 15, the diameter of sealed dish 20 is greater than the external diameter of trachea 15 and equals, sealed dish 20 laminates and sealing connection with the top of main part 1, sealed dish 20 is located between connecting rod 22 and the main part 1, the one end of connecting rod 22 is fixed on carriage release lever 21, the other end and the sealed dish 20 fixed connection of connecting rod 22.

The expansion block 25 realizes the change of volume by the principle of thermal barrier cold contraction, and, when the ambient air temperature is high and the water temperature in the main body 1, the volume increase range of the expansion block 25 at the top end in the guide pipe 23 is larger than the volume increase range of the expansion block 25 at the bottom end in the guide pipe 23, so that the spring 24 can drive the moving rod 21 to move downwards in the guide pipe 23, so that the sealing disc 20 blocks the air pipe 15, when the ambient air temperature is lower than the water temperature in the main body 1, the moving rod 21 moves upwards in the guide pipe 23, the movement of the moving rod 21 drives the sealing disc 20 to move upwards through the connecting rod 22, so that the sealing disc 20 is separated from the main body 1, the air pipe 15 is dredged, and the air in the auxiliary pipe 13 can flow.

Preferably, the sealing disk 20 is made of rubber for achieving cushioning and vibration reduction.

The rubber is soft, so that the impact force generated when the sealing disc 20 abuts against the main body 1 can be reduced, and buffering and vibration reduction can be realized.

Preferably, in order to reduce the gap between the propeller shaft 3 and the inner wall of the mounting hole, the inside of the mounting hole is coated with a sealing grease.

The sealing grease has the function of reducing the gap between the transmission shaft 3 and the inner wall of the mounting hole, and the sealing performance is improved.

As shown in fig. 5, two heat conducting rods 26 are respectively disposed on one sides of the two air pipes 15 close to the axis of the transmission shaft 3, the heat conducting rods 26 are parallel to the stirring rod 7, two through holes are disposed on the air pipes 15, the through holes correspond to the heat conducting rods 26 one by one, the heat conducting rods 26 pass through the through holes, the heat conducting tubes are hermetically and fixedly connected to the inner walls of the through holes, and the stirring rod 7 is disposed between the two heat conducting rods 26 and abuts against the heat conducting rods 26.

The heat conduction rod 26 absorbs the heat transfer of the air in the air pipe 15 to the water in the main body 1, the heating efficiency is improved, the impact effect of water can be improved by the heat conduction rod 26, the heating efficiency of water is improved, and the water heating efficiency can be further improved by the friction between the stirring rod 7 and the heat conduction rod 26 according to the principle of heat generation through friction.

Preferably, in order to prolong the service life of the auxiliary pipe 13, the auxiliary pipe 13 is provided with an anti-corrosion zinc coating.

The function of anticorrosive zinc coating is to promote the rust-resistant ability of auxiliary pipe 13, prolongs the life of auxiliary pipe 13.

Preferably, in order to facilitate the installation of the transmission shaft 3, both ends of the transmission shaft 3 are provided with chamfers.

The chamfer has the effect of reducing the caliber of the transmission shaft 3 when the transmission shaft passes through the mounting hole, and facilitating mounting.

Preferably, in order to reduce the frictional force between the driving gear 6 and the driven gear 8, the driving gear 6 is coated with grease.

The lubricating grease has the characteristic of insolubility in water, can reduce the friction force between the driving gear 6 and the driven gear 8, and improves the fluency of the driving gear 6 driving the driven gear 8 to rotate.

Water is conveyed into the main body 1 through one of the water pipes 5, then the first fan blade 2 is rotated by ambient wind power, so that the transmission shaft 3 drives the stirring rod 7 to rotate under the supporting action of the first bearing 4, water in the main body 1 generates friction and realizes heating through the rotation of the stirring rod 7, water after heating is discharged from the other water pipe 5, during the period, the rotation of the transmission shaft 3 drives the driving gear 6 to rotate, the rotation of the driving gear 6 drives the driven gear 8 to rotate, so that the connecting shaft 10 rotates under the supporting action of the second bearing 9, the rotation of the connecting shaft 10 drives the screw rod 12 to rotate in the fixed pipe 11, so that clean water in the fixed pipe 11 flows towards the direction close to the stirring rod 7, and the friction mode and the friction strength of the water can be increased, namely, the water heating efficiency can be improved, when the temperature of air outside the main body 1 is lower than the temperature of the water in the main body 1, the expansion block 25 at the top end in the guide tube 23 has a smaller volume increase than the expansion block 25 at the bottom end in the guide tube 23, the movable rod 21 is pushed by the spring 24 to rise in the guide tube 23, the movable rod 21 moves to drive the sealing disc 20 to move upwards through the connecting rod 22, so that the sealing disc 20 is separated from the main body 1, the drive bevel gear 14 is driven to rotate by the rotation of the drive shaft 3, the drive bevel gear 14 drives the driven bevel gear 16 to rotate, the driven bevel gear 16 rotates to drive the power shaft 18 to drive the second fan 19 to rotate under the supporting action of the third bearing 17, and the rotation of the second fan 19 makes the air in the auxiliary tube 13 realize one-way flow, so that the air outside the main body 1 is conveyed into the auxiliary tube 13 through one of the air tubes 15, the air in the auxiliary tube 13 is discharged from the other air tube 15, wherein the temperature of the air in the auxiliary tube 13 is transferred to the water in the main body 1 through the auxiliary tube 13, further improve the temperature of main part 1 water-logging, further promote the efficiency of heating, when the outside air temperature of main part 1 is less than temperature in the main part 1, the volume increase range of the inflation piece 25 on top is greater than the volume increase range of the inflation piece 25 in the pipe 23, thereby can make spring 24 drive the carriage release lever 21 downstream in the pipe 23, make sealed dish 20 block up trachea 15, thereby can avoid the air escape in the trachea 15, avoid the temperature loss in the main part 1, realize keeping warm.

Compared with the prior art, this high-efficient type liquid stirring formula wind-force equipment of heating has realized improving the function that heats efficiency through rabbling mechanism, compares with current rabbling mechanism, and this rabbling mechanism structure is ingenious, and the practicality is stronger, moreover, has still further improved the efficiency of heating through complementary unit, compares with current complementary unit, and this complementary unit has still realized the function of mechanical type automated inspection main part 1 outside air temperature and main part 1 interior temperature, and the interference killing feature is stronger.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims

1. The utility model provides a high-efficient type liquid stirring formula wind-force equipment of heating, includes main part (1), first flabellum (2), transmission shaft (3), first bearing (4) and two water pipes (5), the shape of main part (1) is the cuboid, and two water pipes (5) set up respectively in the both sides of main part (1), and two water pipes (5) communicate through main part (1), the top of main part (1) is equipped with the mounting hole, the vertical mounting hole that passes of transmission shaft (3), the inner wall slip and the sealing connection of transmission shaft (3) and mounting hole, the top at transmission shaft (3) is installed to first flabellum (2), first flabellum (2) are located vertical fan blade, first bearing (4) are located between first flabellum (2) and main part (1), the inner circle of first bearing (4) is installed on transmission shaft (3), the outer lane of first bearing (4) and the top fixed connection of main part (1), the device is characterized in that a stirring mechanism and an auxiliary mechanism are arranged in the main body (1);

the stirring mechanism comprises a driving gear (6), two stirring rods (7) and two stirring components, the axes of the stirring rods (7) are perpendicular to and intersected with the axis of the transmission shaft (3), the stirring rods (7) are circumferentially and uniformly fixed on the transmission shaft (3) by taking the axis of the transmission shaft (3) as a center, the driving gear (6) is installed on the transmission shaft (3) and is positioned on one side, close to the first fan blade (2), of the stirring rods (7), and the stirring components are in one-to-one correspondence with the stirring rods (7) and are arranged on one side, close to the first fan blade (2), of the stirring rods (7);

the stirring component comprises a driven gear (8), a second bearing (9), a connecting shaft (10), a fixed pipe (11) and a screw (12), the fixed pipe (11) is parallel to the transmission shaft (3), the fixed pipe (11) is fixedly connected with the inner wall of the main body (1), the screw rod (12) is arranged in the fixed pipe (11) and is coaxial with the fixed pipe (11), the screw rod (12) is matched with the fixed pipe (11), the screw rod (12) is connected with the inner wall of the fixed pipe (11) in a sliding and sealing way, the connecting shaft (10) and the screw rod (12) are coaxially arranged, the bottom end of the connecting shaft (10) is fixed at the top end of the screw rod (12), the inner ring of the second bearing (9) is arranged at the top end of the connecting shaft (10), the outer ring of the second bearing (9) is fixedly connected with the inner wall of the main body (1), the driven gear (8) is arranged on the connecting shaft (10) and is meshed with the driving gear (6);

the auxiliary mechanism comprises an auxiliary pipe (13), a driving bevel gear (14), two wind power assemblies, two air pipes (15) and two sealing assemblies, wherein the auxiliary pipe (13) is perpendicular to and intersected with the axis of the transmission shaft (3), two ends of the auxiliary pipe (13) are respectively sealed and fixedly connected with the inner walls of two sides of the main body (1), the auxiliary pipe (13) is positioned on one side of the stirring rod (7) far away from the first fan blade (2), a through hole is formed in the top end of the auxiliary pipe (13), the transmission shaft (3) penetrates through the through hole, the transmission shaft (3) slides and is hermetically connected with the inner wall of the through hole, the air pipes (15) are parallel to the transmission shaft (3) and are in one-to-one correspondence with the fixed pipes (11), two connecting holes are formed in the top of the main body (1), the connecting holes are in one-to-one correspondence with the air pipes (15), and, the air pipe (15) is connected with the inner wall of the connecting hole in a sealing and fixed mode, the bottom end of the air pipe (15) is arranged at the top of the auxiliary pipe (13), the air pipe (15) is communicated with the auxiliary pipe (13), the driving bevel gear (14) is located in the auxiliary pipe (13) and is installed at the bottom end of the transmission shaft (3), the wind power assembly is arranged in the auxiliary pipe (13) and corresponds to the fixed pipe (11) one to one, the wind power assembly is located between the axes of the two air pipes (15), and the sealing assembly corresponds to the air pipe (15) one to one and is arranged at the top of the main body (1).

2. A high efficiency liquid stirring type wind power equipment as claimed in claim 1, wherein said wind power assembly comprises a driven bevel gear (16), a third bearing (17), a power shaft (18) and a second blade (19), said power shaft (18) is parallel to the auxiliary pipe (13), said driven bevel gear (16) is installed at one end of the power shaft (18) and meshed with the driving bevel gear (14), said second blade (19) is installed at the other end of the power shaft (18), the inner ring of said third bearing (17) is installed on the power shaft (18), the outer ring of said third bearing (17) is fixedly connected with the inner wall of the auxiliary pipe (13).

3. A high efficiency liquid-agitated wind power plant as claimed in claim 2, wherein the number of teeth of the drive bevel gear (14) is greater than the number of teeth of the driven bevel gear (16).

4. The efficient type liquid agitation type wind power heating apparatus according to claim 1, wherein the sealing assembly comprises an assembly hole, a sealing disk (20), a moving rod (21), a connecting rod (22), a guide tube (23), two springs (24) and two expansion blocks (25), the assembly hole is provided at the top of the main body (1), the guide tube (23) is parallel to the driving shaft (3), the guide tube (23) passes through the assembly hole, the guide tube (23) is hermetically and fixedly connected with the inner wall of the assembly hole, the moving rod (21) is provided at the middle end in the guide tube (23) and is coaxially provided with the guide tube (23), the moving rod (21) is slidably and hermetically connected with the inner wall of the guide tube (23), the springs (24) and the expansion blocks (25) are both located in the guide tube (23), and the two expansion blocks (25) are respectively fixed on the inner walls at both ends of the guide tube (23), spring (24) and inflation piece (25) one-to-one and lie in carriage release lever (21) and inflation piece (25) between, carriage release lever (21) is connected with inflation piece (25) through spring (24), the one side that is close to transmission shaft (3) of pipe (23) is equipped with the sliding tray, the sliding tray is located between two spring (24), the axis of connecting rod (22) is perpendicular and crossing with the axis of carriage release lever (21), connecting rod (22) pass the sliding tray and with the inner wall sliding connection of sliding tray, sealed dish (20) and trachea (15) coaxial setting, the diameter of sealed dish (20) is greater than the external diameter of trachea (15) and equals, the laminating of top and sealing connection of sealed dish (20) and main part (1), sealed dish (20) are located between connecting rod (22) and main part (1), the one end of connecting rod (22) is fixed on carriage release lever (21), the other end of the connecting rod (22) is fixedly connected with the sealing disc (20).

5. A highly efficient liquid-stirring wind power generation apparatus as defined in claim 4, wherein said sealing disk (20) is made of rubber.

6. A high efficiency liquid-agitated wind powered heating apparatus as claimed in claim 1 wherein said mounting hole is internally coated with a sealing grease.

7. The efficient liquid stirring wind power heating equipment according to claim 1, wherein two heat conducting rods (26) are arranged on one side of each of the two air pipes (15) close to the axis of the transmission shaft (3), the heat conducting rods (26) are parallel to the stirring rod (7), two through holes are formed in the air pipes (15), the through holes correspond to the heat conducting rods (26) one by one, the heat conducting rods (26) penetrate through the through holes, the heat conducting pipes are hermetically and fixedly connected with the inner walls of the through holes, and the stirring rod (7) is located between the two heat conducting rods (26) and abuts against the heat conducting rods (26).

8. A high efficiency liquid stirring wind power heating apparatus as defined in claim 1, wherein said auxiliary pipe (13) is provided with an anti-corrosion zinc plating layer.

9. A high efficiency liquid agitated wind power plant as claimed in claim 1 wherein both ends of said drive shaft (3) are chamfered.

10. A high efficiency liquid agitated wind powered heating device as claimed in claim 1 wherein said drive gear (6) is grease coated.