CN113783359A

CN113783359A - Mechanical temperature control type motor

Info

Publication number: CN113783359A
Application number: CN202111015765.9A
Authority: CN
Inventors: 尹洁; 李晓宇; 尹东升; 罗永林; 林金源
Original assignee: Zhejiang Jiang Yu Motor Co ltd
Current assignee: Shenzhen Shunchang Automation Control Technology Co ltd
Priority date: 2021-08-31
Filing date: 2021-08-31
Publication date: 2021-12-10
Anticipated expiration: 2041-08-31
Also published as: CN113783359B

Abstract

The invention discloses a mechanical temperature control type motor, which relates to the technical field of motor design and comprises a shell, wherein a rotating shaft is arranged in the shell, a positioning cylinder is arranged at the edge part of the shell, a moving plate is slidably arranged in the positioning cylinder, a sealing sleeve is arranged at the edge part of the moving plate, a plurality of uniformly arranged heat dissipation holes are formed in one edge of the moving plate by taking the sealing sleeve as the center, a first gas expansion assembly is arranged in the shell, and a plurality of uniformly arranged second gas expansion assemblies are arranged on the inner wall of the positioning cylinder. According to the invention, the first gas expansion assembly, the second gas expansion assembly, the moving plate, the sealing sleeve and the heat dissipation assembly are arranged, and the heat dissipation assembly works within a temperature difference range formed between the first gas expansion assembly and the second gas expansion assembly by utilizing the difference between the expansion temperature of the first gas expansion assembly and the expansion temperature of the second gas expansion assembly, so that the motor always keeps an ideal working temperature.

Description

Mechanical temperature control type motor

Technical Field

The invention relates to the technical field of motor design, in particular to a mechanical temperature control type motor.

Background

The motor is commonly called as "motor" and refers to an electromagnetic device for realizing electric energy conversion or transmission according to the law of electromagnetic induction, the motor is represented by a letter M (old standard is represented by D) in a circuit, the motor mainly functions to generate driving torque and is used as a power source of electrical appliances or various machines, the generator is represented by a letter G in the circuit, and the generator mainly functions to convert mechanical energy into electric energy.

In the prior art, when the motor rose the ideal temperature, the motor had an ideal operating temperature, the high temperature of motor not only can influence the work efficiency of motor, also probably arouses the overload phenomenon simultaneously, thereby make the motor scrap, because the work of motor inside can produce stronger magnetic field and electric field, temperature sensor and temperature controller can receive the magnetic field influence at the during operation, temperature sensor and temperature controller are difficult to continue to use in the motor, realize temperature control, the motor also is difficult to keep an ideal operating temperature, consequently, we disclose a mechanical accuse temperature formula motor and satisfy the demand at people.

Disclosure of Invention

The present invention is directed to a mechanical temperature-controlled motor, which solves the above problems of the prior art, and is capable of operating while maintaining the motor in an ideal temperature range.

In order to achieve the above purpose, the present application provides the following technical solutions: the utility model provides a machinery accuse temperature formula motor, includes the shell, be equipped with the axis of rotation in the shell, a location section of thick bamboo is installed to the limit portion of shell, slidable mounting has the movable plate in the location section of thick bamboo, the seal cover is installed to the limit portion of movable plate, the installation is provided with first gas expansion subassembly in the shell, install the gaseous expansion subassembly of a plurality of second that evenly set up on the inner wall of a location section of thick bamboo, it is a plurality of second gas expansion subassembly, first gas expansion subassembly all with the movable plate contacts, the limit portion of movable plate through reset block with the location section of thick bamboo is connected, the expansion temperature of first gas expansion subassembly is less than the expansion temperature of second gas expansion subassembly, the lateral part of seal cover install with the corresponding radiator unit in axis of rotation position.

By means of the structure: the first piston cylinder in the first gas expansion assembly and the second piston cylinder in the second gas expansion assembly are filled with gas with different thermal expansion temperatures, the expansion temperature of the gas in the first piston cylinder is higher than that of the gas in the second piston cylinder, after the interior of the shell reaches an ideal temperature, the gas in the first piston cylinder is continuously raised, so that the gas in the first piston cylinder is expanded, the first piston rod pushes the moving plate, the moving plate drives the sealing sleeve to move, the sealing sleeve is separated from the vent hole, the sealing sleeve moves to enable the heat dissipation assembly to work, the fan blades in the heat dissipation assembly rotate to generate wind absorption force to perform heat extraction, at the moment, hot air passes through the second heat conduction block in the second gas expansion assembly, the second heat conduction block is heated to enable the gas in the second piston cylinder to expand, the second piston rod contacts the moving plate, after the temperature is reduced, when the interior of the shell reaches the ideal temperature, the first piston rod can be retracted into the first piston cylinder, but the second piston rod can not retract into the second piston cylinder until the internal temperature of the shell is reduced to be lower than the expansion temperature of the gas in the second piston cylinder, and the reset assembly enables the moving plate to return to the original position, namely the sealing sleeve seals the vent hole.

Preferably, the bottom of shell is provided with joint locating component, joint locating component includes brace table and joint subassembly, the joint subassembly sets up the top at the brace table, brace table movable mounting be in the bottom of shell, the standing groove has been seted up at the top of brace table, the bottom of standing groove inner wall is installed and is prevented the rotor plate, the rotating-proof groove has been seted up to the bottom of shell, prevent the rotor plate with prevent the rotor plate looks adaptation, four corners in the bottom of brace table all are provided with damper.

Furthermore, prevent that the rotating groove and prevent changeing looks adaptation, when the shell was placed on the brace table this moment, the shell can not take place to rotate, improves the stability of this motor work.

Preferably, the joint subassembly is including solid placing the ring, place the ring and install prop up supporting bench's top, place a articulated joint ring of installing in a lateral part of ring, the joint ring with place the same lateral part of ring and all seted up the rectangular channel, be located place the ring the both sides of rectangular channel inner wall are rotated and are installed and rotate the piece, the threaded rod is installed at the top of rotating the piece, a joint section of thick bamboo is installed to the outside portion spiro union of threaded rod, one side that a joint section of thick bamboo is located the top position and has seted up the locating hole, the inner wall slidable mounting of locating hole has the locating pin.

Further, rotate the joint section of thick bamboo in the joint subassembly, make the bottom and the joint ring contactless of a joint section of thick bamboo, remove the threaded rod, make the threaded rod break away from the rectangular channel on the joint ring, the joint ring can rotate round the top one side of placing the ring this moment, the joint ring promptly with place the ring can not reciprocal anchorage, the motor can be followed a supporting bench and taken out this moment, set up the locating pin, make for convenience the application of force on a joint section of thick bamboo, make a joint section of thick bamboo rotate.

Preferably, damping component includes a fixed cylinder, the inner wall slidable mounting of a fixed cylinder has the carriage release lever, the top table of carriage release lever is in the bottom of brace table, the bottom plate is installed to the bottom of a fixed cylinder, the lateral wall of a fixed cylinder cup joints and installs damping spring, damping spring's both ends respectively with brace table with the bottom plate contacts.

Further, when this motor work, can produce and rock, rock the potential energy that produces this moment and can turn into damping spring's elastic potential energy, damping spring has constantly gone on telescopically, turns into other ability with elastic potential energy, for example, internal energy, scatters and disappears to reduce the production of rocking, a fixed section of thick bamboo and carriage release lever mutually support, can guarantee rocking of motor can only rock from top to bottom.

Preferably, the reset assembly is including fixed a section of thick bamboo that leads to, fixed a section of thick bamboo that leads to is installed a location section of thick bamboo is kept away from shell lateral wall on one side, the fixed dead lever that leads to one side of a section of thick bamboo and install a plurality of equidistance and distribute, the sliding hole that a plurality of equidistance distribute is seted up on one side of movable plate, dead lever slidable mounting be in on the inner wall of sliding hole, the limiting plate is installed on one side of dead lever, the lateral wall of dead lever cup joints and installs reset spring, reset spring's both ends respectively with the movable plate with fixed a section of thick bamboo that leads to contacts.

Furthermore, the fixed rod is in sliding fit with the sliding hole, the moving plate can only move linearly along the fixed rod at the moment, when the first gas expansion assembly and the second gas expansion assembly exert acting force on one side of the moving plate, the moving plate can move towards the outside, the return spring is compressed to generate counter force, and when the first gas expansion assembly and the second gas expansion assembly do not exert acting force or the acting force on one side of the moving plate is reduced, the return spring exerts acting force on the moving plate, so that the moving plate returns to the original position.

Preferably, a mounting hole is formed in one side of the fixing frame, the first gas expansion assembly comprises a first telescopic cylinder, the first telescopic cylinder is mounted on the inner wall of the mounting hole, a first piston rod is slidably mounted on the inner wall of the first telescopic cylinder, a first heat conduction block is mounted on one side of the first telescopic cylinder in an inserted manner, the second gas expansion assembly comprises a second telescopic cylinder, the second telescopic cylinder is mounted on the inner wall of the mounting hole, a second piston rod is slidably mounted on the inner wall of the second telescopic cylinder, a second heat conduction block is mounted on one side of the second telescopic cylinder in an inserted manner, and the first piston rod and the second piston rod are all in contact with the movable plate.

Furthermore, the first heat conduction block and the second heat conduction block are made of materials with good heat conductivity, such as metal blocks, and the first heat conduction block and the second heat conduction block are made of materials with good heat conductivity, so that absorbed heat can be transmitted to gas in the first piston cylinder and gas in the second piston cylinder, and the gas in the first piston cylinder and the gas in the second piston cylinder can be expanded.

Preferably, the guide block is installed on the shell, the heat dissipation assembly comprises a heat dissipation assembly, a support piece and a connecting rod, the support piece is installed on the inner wall of the shell, the heat dissipation assembly is arranged on one side of the support piece, one end of the connecting rod is installed on the sealing sleeve, a fixing ring is installed on one side of the connecting rod, a friction plate is installed on one side of the fixing ring in a rotating mode, a moving barrel is installed in the middle of one side of the friction plate, a guide groove is formed in one side of the inner wall of the moving barrel, and the guide block is installed on the inner wall of the guide groove in a sliding mode.

Furthermore, the guide groove and the guide block are matched with each other, so that when the movable cylinder moves along the rotating shaft, the movable cylinder can synchronously rotate along with the rotating shaft, when the sealing sleeve moves, namely, the friction plate synchronously rotates along with the rotating shaft, when the sealing sleeve moves outwards, the sealing sleeve moves through the connecting rod, the connecting rod drives the fixing ring, the fixing ring drives the friction plate to contact with the rotating plate, and the sealing sleeve moves outwards or inwards to control the work of the radiating assembly.

Preferably, the heat dissipation assembly comprises a rotating plate, the rotating plate is rotatably mounted in the middle of one side of the support member, and a fan blade is mounted in the middle of one side of the rotating plate.

Furthermore, the friction plate is in contact with the rotating plate, the rotating plate is rotated through friction force, the rotating plate drives the fan blades to rotate at the moment, the fan blades cut air to generate wind suction force, and heat inside the shell is discharged outwards through the wind suction force.

Preferably, a plurality of first limiting rods distributed at equal intervals are arranged at the edge of one side of the friction plate, a plurality of second limiting rods distributed at equal intervals are rotatably arranged on the outer side wall of the rotating plate, and the number of the first limiting rods is equal to that of the second limiting rods.

Furthermore, if the friction plate and the rotating plate slip, the first limiting rod exerts an acting force on the outer side wall of the second limiting rod, the second limiting rod drives the rotating plate to rotate, the rotating plate enables the fan blades to cut air to generate wind suction force, and heat inside the shell is discharged outwards through the wind suction force.

In conclusion, the technical effects and advantages of the invention are as follows:

1. according to the invention, the first gas expansion assembly, the second gas expansion assembly, the moving plate, the sealing sleeve and the heat dissipation assembly are arranged, and the heat dissipation assembly works within a temperature difference range formed between the first gas expansion assembly and the second gas expansion assembly by utilizing the difference between the expansion temperature of the first gas expansion assembly and the expansion temperature of the second gas expansion assembly, so that the motor always keeps an ideal working temperature.

2. According to the invention, the guide grooves and the guide blocks are matched with each other, so that when the movable cylinder moves along the rotating shaft, the movable cylinder can synchronously rotate along with the rotating shaft, when the sealing sleeve moves, namely, the friction plate synchronously rotates along with the rotating shaft, when the sealing sleeve moves outwards, the sealing sleeve moves through the connecting rod, the connecting rod drives the fixing ring, the fixing ring drives the friction plate to be in contact with the rotating plate, the sealing sleeve moves outwards or inwards, the work of the radiating assembly can be controlled, the rotating plate rotates through friction force of the friction plate, the rotating plate drives the fan blades to rotate at the moment, so that the air cut by the fan blades generates wind absorption force, the heat in the shell is outwards discharged through the wind absorption force, and the work of the radiating assembly can be controlled at any time through a clutch control mode.

3. According to the invention, the first limiting rod and the second limiting rod are arranged, so that if the friction plate and the rotating plate slip, the first limiting rod can apply acting force to the outer side wall of the second limiting rod, the second limiting rod drives the rotating plate to rotate, the rotating plate enables the fan blades to cut air to generate wind absorption force, and heat in the shell is discharged outwards through the wind absorption force.

Drawings

In order to more clearly illustrate the embodiments of the present application 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, it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings can be obtained by those skilled in the art without creative efforts.

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

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

FIG. 3 is an enlarged view of the structure at A in FIG. 2;

FIG. 4 is a schematic front view of the present invention

FIG. 5 is a schematic view of the sectional structure A-A of FIG. 4;

FIG. 6 is a schematic view of a portion of a first gas expansion assembly according to the present invention;

FIG. 7 is a schematic view of the sectional structure B-B of FIG. 4;

fig. 8 is a front view sectional structure diagram of the present invention.

In the figure: 1. a housing; 2. a positioning cylinder; 3. fixing the through cylinder; 4. moving the plate; 5. a shock absorbing assembly; 6. a base plate; 7. a support table; 8. placing a ring; 9. a rotating member; 10. a threaded rod; 11. a snap ring; 12. a clamping cylinder; 13. positioning pins; 14. a limiting plate; 15. fixing the rod; 16. a return spring; 17. a rotating shaft; 18. a guide block; 19. moving the drum; 20. a support member; 21. a friction plate; 22. a fixing ring; 23. a connecting rod; 24. a first limit rod; 25. a second limiting rod; 26. a rotating plate; 27. a fixed mount; 28. an anti-rotation plate; 29. a first gas expansion assembly; 30. sealing sleeves; 31. a fan blade; 32. a first heat-conducting block; 33. a second gas expansion assembly; 34. a second heat conduction block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example (b): referring to fig. 1-6, a mechanical temperature control motor comprises a housing 1, a rotating shaft 17 is arranged in the housing 1, a positioning cylinder 2 is arranged at the edge of the housing 1, a moving plate 4 is slidably arranged in the positioning cylinder 2, a sealing sleeve 30 is arranged at the edge of the moving plate 4, a plurality of heat dissipation holes are uniformly arranged on one side of the moving plate 4 by taking the sealing sleeve 30 as a center, a first gas expansion assembly 29 is arranged in the housing 1, a plurality of second gas expansion assemblies 33 and a plurality of second gas expansion assemblies 33 are uniformly arranged on the inner wall of the positioning cylinder 2, the first gas expansion components 29 are all contacted with the moving plate 4, the edge part of the moving plate 4 is connected with the positioning cylinder 2 through the resetting component, the expansion temperature of the first gas expansion components 29 is lower than that of the second gas expansion components 33, and the side part of the sealing sleeve 30 is provided with a heat radiation component corresponding to the position of the rotating shaft 17.

By means of the structure, when the motor works, the temperature in the shell 1 is gradually increased, and when the ideal temperature is reached, such as ninety-five degrees, the working efficiency of the motor is maximum, the motor continues to work, the temperature in the shell 1 continues to rise, at the moment, the first gas expansion assembly 29 senses that the temperature exceeds the ideal temperature and starts to work, the first gas expansion assembly 29 pushes the moving plate 4 outwards, at the moment, the sealing sleeve 30 gradually keeps away from the shell 1 until the sealing sleeve 30 is completely separated from the shell 1, at the same time, the sealing sleeve 30 enables the heat dissipation assembly to work, the heat of the shell 1 is discharged outwards by means of wind power, hot air is discharged from a gap formed by the sealing sleeve 30 and the shell 1 and contacts with the second gas expansion assembly 33, at the moment, the second gas expansion assembly 33 senses the temperature and starts to work, the moving plate 4 is jacked, when the temperature in the shell 1 is reduced to the ideal temperature, the first gas expansion assembly 29 stops working and returns to the original state, because the expansion temperature of the first gas expansion assembly 29 is lower than the expansion temperature of the second gas expansion assembly 33, the second gas expansion assembly 33 then works until the temperature in the shell 1 is lower than the expansion temperature of the second gas expansion assembly 33, the second gas expansion assembly 33 stops working and returns to the original state, at this time, the movable plate 4 returns to the original position under the action of the reset assembly, the sealing sleeve 30 returns to the original position, meanwhile, the heat dissipation assembly stops working, and if the temperature rises to exceed the ideal temperature, the working is repeated, so that the motor always works in an ideal working temperature range.

As a preferred implementation manner of this embodiment, as shown in fig. 1, the bottom of the housing 1 is provided with a clamping positioning component, the clamping positioning component includes a supporting table 7 and a clamping component, the clamping component is disposed on the top of the supporting table 7, the supporting table 7 is movably mounted on the bottom of the housing 1, a placing groove is disposed on the top of the supporting table 7, an anti-rotation plate 28 is mounted on the bottom of an inner wall of the placing groove, an anti-rotation groove is disposed on the bottom of the housing 1, the anti-rotation groove is adapted to the anti-rotation plate 28, and four corners of the bottom of the supporting table 7 are provided with shock absorbing components 5.

Through preventing that the rotating groove and preventing the adaptation of rotating plate 28, when shell 1 placed on brace table 7 this moment, shell 1 can not take place to rotate, improves the stability of this motor work.

The joint subassembly is including solid ring 8 of placing, place ring 8 and install the top at brace table 7, a lateral part of placing ring 8 articulates installs joint ring 11, joint ring 11 and the same lateral part of placing ring 8 have all been seted up the rectangular channel, it installs rotation piece 9 to be located the both sides rotation of the rectangular channel inner wall of placing ring 8, threaded rod 10 is installed at the top of rotation piece 9, a joint section of thick bamboo 12 is installed to the outside portion spiro union of threaded rod 10, one side of a joint section of thick bamboo 12 is located the top position and has been seted up the locating hole, the inner wall slidable mounting of locating hole has locating pin 13.

Prevent rotating groove and rotation-proof plate 28 looks adaptation, when shell 1 placed brace table 7 this moment, shell 1 can not take place to rotate, improve the stability of this motor work, rotate joint section of thick bamboo 12 in the joint subassembly, make the bottom and the joint ring 11 contactless of joint section of thick bamboo 12, remove threaded rod 10, make threaded rod 10 break away from the rectangular channel on the joint ring 11, joint ring 11 can rotate round top one side of placing ring 8 this moment, joint ring 11 can not the reciprocal anchorage with placing ring 8 promptly, the motor can be taken out from brace table 7 this moment, set up locating pin 13, make for convenience the application of force on joint section of thick bamboo 12, make joint section of thick bamboo 12 rotate.

As a preferred embodiment of this embodiment, as shown in fig. 7, the damping assembly 5 includes a fixed cylinder, a moving rod is slidably mounted on an inner wall of the fixed cylinder, a top table of the moving rod is at the bottom of the supporting table 7, a bottom plate 6 is mounted at the bottom of the fixed cylinder, a damping spring is sleeved on an outer side wall of the fixed cylinder, and two ends of the damping spring are respectively in contact with the supporting table 7 and the bottom plate 6.

When this motor work, can produce and rock, rock the potential energy that produces this moment and can turn into damping spring's elastic potential energy, damping spring has constantly gone on flexible, turns into other ability with elastic potential energy, for example, internal energy, scatters and disappears to reduce the production of rocking, a fixed section of thick bamboo and carriage release lever mutually support, can guarantee rocking of motor can only rock from top to bottom.

As a preferred embodiment of this embodiment, as shown in fig. 3, the reset assembly includes a fixed through cylinder 3, the fixed through cylinder 3 is installed on an outer side wall of one side of the positioning cylinder 2 away from the housing 1, one side of the fixed through cylinder 3 is installed with a plurality of fixing rods 15 distributed equidistantly, one side of the moving plate 4 is opened with a plurality of sliding holes distributed equidistantly, the fixing rods 15 are slidably installed on an inner wall of the sliding holes, one side of the fixing rods 15 is installed with a limiting plate 14, an outer side wall of the fixing rods 15 is sleeved with a reset spring 16, and two ends of the reset spring 16 are respectively in contact with the moving plate 4 and the fixed through cylinder 3.

The fixed rod 15 is in sliding fit with the sliding hole, the moving plate 4 can only move linearly along the fixed rod 15 at this time, when the first gas expansion assembly 29 and the second gas expansion assembly 33 exert acting force on one side of the moving plate 4, the moving plate 4 can move outwards, the return spring 16 is compressed to generate counter force, and when the first gas expansion assembly 29 and the second gas expansion assembly 33 do not exert acting force or the acting force on one side of the moving plate 4 is reduced, the return spring 16 exerts acting force on the moving plate 4, and the moving plate 4 returns to the original position.

As a preferred implementation manner of this embodiment, as shown in fig. 6, a mounting hole is opened on one side of the fixing frame 27, the first gas expansion assembly 29 includes a first telescopic cylinder, the first telescopic cylinder is installed on an inner wall of the mounting hole, a first piston rod is slidably installed on an inner wall of the first telescopic cylinder, a first heat conduction block 32 is installed on one side of the first telescopic cylinder in an inserted manner, the second gas expansion assembly 33 includes a second telescopic cylinder, the second telescopic cylinder is installed on the inner wall of the mounting hole, a second piston rod is slidably installed on an inner wall of the second telescopic cylinder, a second heat conduction block 34 is installed on one side of the second telescopic cylinder in an inserted manner, and both the first piston rod and the second piston rod are in contact with the moving plate 4.

The first heat conduction block 32 and the second heat conduction block 34 are made of materials with good heat conductivity, such as metal blocks, and the first heat conduction block 32 and the second heat conduction block 34 are made of materials with good heat conductivity, so that absorbed heat can be transmitted to gas in the first piston cylinder and gas in the second piston cylinder, and the gas in the first piston cylinder and the gas in the second piston cylinder can be expanded.

As a preferred embodiment of the present invention, as shown in fig. 3, a guide block 18 is installed on one side portion of the rotating shaft 17, the heat dissipation assembly includes a heat dissipation assembly, a support 20 and a connecting rod 23, the support 20 is installed on the inner wall of the housing 1, the heat dissipation assembly is disposed on one side of the support 20, one end of the connecting rod 23 is installed on the sealing sleeve 30, a fixing ring 22 is installed on one side portion of the connecting rod 23, a friction plate 21 is rotatably installed on one side of the fixing ring 22, a moving cylinder 19 is installed on the middle portion of one side of the friction plate 21, a guide groove is opened on one side portion of the inner wall of the moving cylinder 19, and the guide block 18 is slidably installed on the inner wall of the guide groove.

The heat dissipation assembly comprises a rotating plate 26, the rotating plate 26 is rotatably mounted in the middle of one side of the support member 20, and a fan blade 31 is mounted in the middle of one side of the rotating plate 26.

A plurality of first limiting rods 24 are arranged at the edge of one side of the friction plate 21, a plurality of second limiting rods 25 are arranged on the outer side wall of the rotating plate 26 in a rotating mode, and the number of the first limiting rods 24 is equal to that of the second limiting rods 25.

The guide grooves and the guide blocks 18 are matched with each other, so that when the movable cylinder 19 moves along the rotating shaft 17, the movable cylinder 19 can synchronously rotate along with the rotating shaft 17, when the sealing sleeve 30 moves, namely the friction plate 21 synchronously rotates along with the rotating shaft 17, when the sealing sleeve 30 moves outwards, the sealing sleeve 30 moves through the connecting rod 23, the connecting rod 23 drives the fixing ring 22, and the fixing ring 22 drives the friction plate 21 to be in contact with the rotating plate 26, so that the sealing sleeve 30 moves outwards or inwards, and the work of the heat dissipation assembly can be controlled; the friction plate 21 contacts the rotating plate 26, and the rotating plate 26 rotates by the friction force, and at this time, the rotating plate 26 drives the fan blades 31 to rotate, so that the fan blades 31 cut air to generate wind suction force, and the heat inside the housing 1 is discharged outside by the wind suction force.

If the friction plate 21 and the rotating plate 26 slip, the first limiting rod 24 applies an acting force to the outer side wall of the second limiting rod 25, the second limiting rod 25 drives the rotating plate 26 to rotate, the rotating plate 26 enables the fan blades 31 to cut air to generate an air suction force, and heat inside the housing 1 is discharged outwards through the air suction force.

As a preferable embodiment of this embodiment, as shown in fig. 8, a rubber plate is provided at the bottom of the bottom plate 6, and the rubber plate increases the friction of the bottom plate 6 and also protects the bottom plate 6.

The working principle of the invention is as follows:

when the motor works, the temperature in the shell 1 gradually rises, and at the time when the ideal temperature is reached, for example, ninety-five degrees, the working efficiency of the motor is maximum, the motor continues to work, the temperature in the shell 1 continues to rise, at the time, the first gas expansion assembly 29 senses that the temperature exceeds the ideal temperature and starts to work, the first gas expansion assembly 29 pushes the moving plate 4 outwards, at the time, the sealing sleeve 30 gradually moves away from the shell 1 until the sealing sleeve 30 is completely separated from the shell 1, at the same time, the sealing sleeve 30 enables the heat dissipation assembly to start to work, the heat of the shell 1 is discharged outwards by wind power, hot air is discharged from a gap formed by the sealing sleeve 30 and the shell 1 and contacts with the second gas expansion assembly 33, at the time, the second gas expansion assembly 33 senses that the temperature of the moving plate starts to work and props against the moving plate 4, when the temperature in the shell 1 reaches the ideal temperature, the first gas expansion assembly 29 stops working and returns to the original state, because the expansion temperature of the first gas expansion assembly 29 is lower than the expansion temperature of the second gas expansion assembly 33, the second gas expansion assembly 33 then works until the temperature in the shell 1 is lower than the expansion temperature of the second gas expansion assembly 33, the second gas expansion assembly 33 stops working and returns to the original state, at this time, the movable plate 4 returns to the original position under the action of the reset assembly, the sealing sleeve 30 returns to the original position, meanwhile, the heat dissipation assembly stops working, and if the temperature rises to exceed the ideal temperature, the working is repeated, so that the motor always works in an ideal working temperature range.

The guide grooves and the guide blocks 18 are matched with each other, when the movable cylinder 19 moves along the rotating shaft 17, the movable cylinder 19 can synchronously rotate along the rotating shaft 17, when the sealing sleeve 30 moves, namely the friction plate 21 synchronously rotates along the rotating shaft 17, when the sealing sleeve 30 moves outwards, the sealing sleeve 30 moves through the connecting rod 23, the connecting rod 23 drives the fixing ring 22, the fixing ring 22 drives the friction plate 21 to contact with the rotating plate 26, so that the sealing sleeve 30 moves outwards or inwards, the heat dissipation assembly can be controlled to work, the friction plate 21 enables the rotating plate 26 to rotate through friction force, at the moment, the rotating plate 26 drives the fan blades 31 to rotate, the fan blades 31 cut air to generate wind absorption force, heat in the shell 1 is discharged outwards through the wind absorption force, and when the friction plate 21 and the rotating plate 26 generate a slipping phenomenon, at the moment, the first limiting rod 24 applies acting force to the outer side wall of the second limiting rod 25, at this time, the second limiting rod 25 drives the rotating plate 26 to rotate, and the rotating plate 26 enables the fan blades 31 to cut air to generate wind absorption force, so that heat inside the shell 1 is discharged outwards through the wind absorption force.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims

1. The utility model provides a machinery accuse temperature formula motor, includes shell (1), its characterized in that: the utility model discloses a gas turbine generator, including shell (1), locating cylinder (2) are installed to the limit portion of shell (1), slidable mounting has movable plate (4) in locating cylinder (2), seal cover (30) are installed to the limit portion of movable plate (4), the installation is provided with first gas expansion subassembly (29) in shell (1), install a plurality of second gas expansion subassembly (33) that evenly set up on the inner wall of locating cylinder (2), it is a plurality of second gas expansion subassembly (33), first gas expansion subassembly (29) all with movable plate (4) contact, the limit portion of movable plate (4) through the reset assembly with locating cylinder (2) are connected, the expansion temperature of first gas expansion subassembly (29) is less than the expansion temperature of second gas expansion subassembly (33), radiator unit is installed to the lateral part of seal cover (30).

2. A mechanical temperature controlled electric machine according to claim 1, characterized in that: the bottom of shell (1) is provided with joint locating component, joint locating component includes brace table (7) and joint subassembly, the joint subassembly sets up the top at brace table (7), brace table (7) movable mounting be in the bottom of shell (1), the standing groove has been seted up at the top of brace table (7), the bottom of standing groove inner wall is installed and is prevented rotating plate (28), the bottom of shell (1) has been seted up and has been prevented the rotating groove, prevent the rotating groove with prevent rotating plate (28) looks adaptation, four corners in the bottom of brace table (7) all are provided with damper (5).

3. A mechanical temperature controlled electric machine according to claim 2, characterized in that: the joint subassembly is including solid ring (8) of placing, place ring (8) and install the top of brace table (7), a lateral part of placing ring (8) is articulated installs joint ring (11), joint ring (11) with the rectangular channel has all been seted up to the same lateral part of placing ring (8), is located place ring (8) the both sides of rectangular channel inner wall are rotated and are installed and rotate piece (9), threaded rod (10) are installed at the top of rotating piece (9), a joint section of thick bamboo (12) is installed to the outside portion spiro union of threaded rod (10), one side of a joint section of thick bamboo (12) is located the top position and has been seted up the locating hole, the inner wall slidable mounting of locating hole has locating pin (13).

4. A mechanical temperature controlled electric machine according to claim 2, characterized in that: damping component (5) are including solid fixed cylinder, solid fixed cylinder's inner wall slidable mounting has the carriage release lever, the top table of carriage release lever is in the bottom of propping up supporting bench (7), bottom plate (6) are installed to solid fixed cylinder's bottom, gu fixed cylinder's lateral wall cup joints and installs damping spring, damping spring's both ends respectively with prop up supporting bench (7) with bottom plate (6) contact.

5. A mechanical temperature controlled electric machine according to claim 1, characterized in that: reset assembly leads to a section of thick bamboo (3) including fixed, fixed a section of thick bamboo (3) of leading to is installed location section of thick bamboo (2) are kept away from shell (1) lateral wall on one side, fixed dead lever (15) that lead to a plurality of equidistance distributions are installed on one side of a section of thick bamboo (3), the slip hole that a plurality of equidistance distribute is seted up on one side of movable plate (4), dead lever (15) slidable mounting be in on the inner wall in slip hole, limiting plate (14) are installed on one side of dead lever (15), the lateral wall of dead lever (15) cup joints and installs reset spring (16), the both ends of reset spring (16) respectively with movable plate (4) with fixed a section of thick bamboo (3) that leads to contacts.

6. A mechanical temperature controlled electric machine according to claim 1, characterized in that: mount (27) are installed to the inner wall of shell (1), the mounting hole has been seted up on one side of mount (27), first gas expansion subassembly (29) include first telescopic tube, first telescopic tube is installed on the inner wall of mounting hole, the inner wall slidable mounting of first telescopic tube has first piston rod, first heat conduction piece (32) are installed in pegging graft on one side of first telescopic tube, second gas expansion subassembly (33) include the second telescopic tube, the second telescopic tube is installed on the inner wall of mounting hole, the inner wall slidable mounting of the second telescopic tube has the second piston rod, second heat conduction piece (34) are installed in the grafting of a lateral part of the second telescopic tube, first piston rod with the second piston rod all with the movable plate (4) contact.

7. A mechanical temperature controlled electric machine according to claim 1, characterized in that: install guide block (18) on shell (1), radiator unit includes radiator unit, support piece (20) and connecting rod (23), install support piece (20) the inner wall of shell (1), radiator unit sets up one side of support piece (20), the one end of connecting rod (23) is installed seal cover (30), solid fixed ring (22) are installed to one side portion of connecting rod (23), gu fixed ring (22) rotate on one side and install friction plate (21), the mid-mounting on one side of friction plate (21) has a removal section of thick bamboo (19), the guide way has been seted up to one side portion of removal section of thick bamboo (19) inner wall, guide block (18) slidable mounting be in on the inner wall of guide way.

8. A mechanical temperature controlled motor according to claim 7, wherein: the heat dissipation assembly comprises a rotating plate (26), the rotating plate (26) is rotatably installed in the middle of one side of the support piece (20), and fan blades (31) are installed in the middle of one side of the rotating plate (26).

9. A mechanical temperature controlled electric machine according to claim 8, wherein: the edge on one side of the friction plate (21) is provided with a plurality of first limiting rods (24) distributed at equal intervals, the outer side wall of the rotating plate (26) is rotatably provided with a plurality of second limiting rods (25) distributed at equal intervals, and the number of the first limiting rods (24) is equal to that of the second limiting rods (25).