JP2021097580A - Motor that can dissipate heat efficiently - Google Patents

Abstract

To provide a motor that can dissipate heat efficiently.SOLUTION: A motor includes a housing, an operating space is provided in the housing, a control space is provided in the housing, a lid plate that closes the operating space is provided at the left end of the operating space, and six exhaust grooves are provided in the lid plate, then exhaust groove can exhaust hot air in the operating space, a motor shell is provided in the operating space, a rotating space is provided in the motor shell, a rotor is provided in the rotating space, two stators are fixedly connected to the upper and lower end walls of the rotating space, and the two stators are provided vertically symmetrically with respect to the rotor.SELECTED DRAWING: Figure 1

Description

The present invention takes up the field of motor technology, and specifically, is a motor capable of efficiently dissipating heat.

In recent years, as the development of motors progresses, motor manufacturers continue to demand compact, high-output density motors. In motor design, materials with high electromagnetic load and heat load are often used. The increased energy consumption when the motor operates leads to an excessive temperature rise of the entire motor or a local excessive temperature rise. This not only shortens the service life of the motor and affects economic and technical indicators such as motor efficiency and torque, but also causes severe deformation of motor components and affects the operational safety of the motor. .. Air cooling is often used to dissipate heat from existing motors, and the heat dissipation effect is low. On the other hand, water cooling is effective, but it is a waste of energy because it cannot be turned off when the motor generates less heat.

Chinese Patent Application Publication No. 1025404023

An object of the present invention is to provide a motor capable of efficiently dissipating heat, which can solve the problems in the present technology described above.

In order to solve the above problems, the present invention employs the following technical plan: The motor capable of efficiently dissipating heat according to the present invention includes a housing, a working space is provided in the housing, and the inside of the housing is provided. Is provided with a control space, a lid plate for closing the operating space is provided at the left end of the operating space, six exhaust grooves are formed in the lid plate, and the exhaust grooves form a lid plate in the operating space. Hot air can be discharged, a motor shell is provided in the working space, a rotating space is provided in the motor shell, a rotor is provided in the rotating space, and the upper and lower parts of the rotating space are provided. Two stators are fixedly connected to the end wall, the two stators are provided vertically symmetrically with respect to the rotor, and the other end is located outside at the right end of the rotor. A motor shaft is provided, heat radiating plates are provided on the four end faces of the motor shell, the amount of heat in the motor shell can be conducted by the heat radiating plate, and heat is generated on the end faces of the heat radiating plate away from the motor shell. A conduction tube is provided, a conduit is provided in the heat conduction tube, and the amount of heat in the heat radiating plate can be removed by the coolant flowing in the conduit, and the above-mentioned working space is provided. A fan fixedly connected to the motor shaft is provided, and when the motor shaft rotates, wind is blown by the operation of the fan to cool the motor shaft, and a storage space is provided on the lower end wall of the working space. Coolant is stored in the storage space, and a water cooling mechanism is provided on the right end wall of the storage space. The water cooling mechanism includes a push plate, and the coolant can be sent by moving the push plate left and right. A control mechanism is provided on the right end wall of the operating space, and the control mechanism includes a drive friction wheel fixedly connected to the motor shaft, and the drive friction wheel is located in the control space to drive the drive. A moving friction wheel that can mesh with the driving friction wheel is provided under the friction wheel, and the water cooling mechanism is activated or stopped by the water cooling mechanism gaining or losing power due to the horizontal movement of the moving friction wheel. Is controlled.

A further technical plan, the water cooling mechanism, includes a liquid return space provided on the upper end wall of the storage space, the liquid return space communicating the pipeline and the storage space, and being in the liquid return space. A first check valve is provided at an end close to the storage space, a liquid push space communicating with the storage space is provided on the right end wall of the storage space, and a communication port between the storage space and the liquid push space. Is provided with a second check valve, and the upper end wall of the liquid pushing space is provided with a liquid-filling space that communicates the liquid pushing space and the pipeline, and is close to the liquid pushing space in the liquid-filling space. A third check valve is provided at the end, the push plate is located in the liquid push space, a moving space is provided on the right end wall of the liquid push space, and a moving plate is provided in the moving space. Are connected so that they can slide, a horizontal spring for connecting the moving space and the moving plate is provided in the moving space, and a moving rack is fixedly connected to the left end surface below the moving plate. , The other end of the moving rack is fixedly connected to the left end surface of the push plate, is connected to the front end wall of the moving space so that the driven shaft can rotate, and the front end of the driven shaft is connected to the moving rack. The incomplete gears that are in mesh are fixedly connected.

Further technical plan, the control mechanism includes a rotating shaft rotatably connected to the right end wall of the control space, the moving friction wheel is connected to the rotating shaft so as to be slidable, and the moving friction wheel is slidable. An annular space is provided in the annular space, and a bow-shaped block is connected so as to be slidable in the annular space, and a fixed block is fixedly connected to the right end wall of the control space. Is provided with a translational space, an electromagnet is fixedly connected to the right end wall of the translational space, and a translational plate is connected to the translational space so that the parallel movement plate can slide. Is connected to a return spring that connects the translation plate and the electromagnet, a connection rod is fixedly connected to the left end surface of the translation plate, and the other end of the connection rod is connected to the right end surface of the bow-shaped block. A rotating shaft that is fixedly connected and connected to the right end wall of the control space so as to be rotatable is provided on the rear side of the rotating shaft, and a transmission friction wheel that can mesh with the bow-shaped block is fixed to the rotating shaft. The direction changing umbrella gear is fixedly connected to the left end of the rotating shaft, connected to the lower end wall of the moving space so that the transmission shaft can rotate, and the upper end of the transmission shaft is the control space. A rotary cap gear that is located inside and meshes with the direction-changing cap gear is fixedly connected to the upper end of the transmission shaft, and a transmission cap gear is fixedly connected to the lower end of the transmission shaft. A driven umbrella gear that meshes with the transmission umbrella gear is fixedly connected to the rear end of the shaft.

Further technical plan, the incomplete gear is a gear with only half teeth, the second check valve allows the coolant to only enter the liquid push space from the storage space and the third check valve. The coolant can only enter the liquid entry space from the liquid push space, and the first check valve allows the coolant to enter the storage space from the liquid return space.

Further technical plan, the magnetic force of the electromagnet is stronger than the elasticity of the return spring.

In the present invention, a fan and an exhaust groove are provided, and by rotating the fan by the rotation of the motor shaft itself at the time of use, the heat radiating part is cooled by air, and hot air is discharged to the outside by the exhaust groove, and the cooling effect is good. Further, a water cooling mechanism is installed in the present invention, and the coolant flows around the heat radiating plate by the movement of the push plate to remove the amount of heat in the heat radiating plate and further dissipate heat. An electromagnet that controls the mechanism is installed, and when the amount of heat is low, the water cooling mechanism can be turned off by remotely controlling the electromagnet, thus saving energy.

In order to explain the invention of the present application in detail with reference to FIGS. 1 to 4 below and to explain the present invention in a convenient manner, the following directions are defined as follows: FIG. The left-right front-back direction and the up-down, left-right front-back direction of the self-projection relationship in FIG. 1 coincide with each other.

FIG. 1 is a schematic configuration of the present invention. FIG. 2 is an enlarged schematic diagram of AA of FIG. FIG. 3 is an enlarged schematic diagram of BB of FIG. FIG. 4 is an enlarged schematic diagram of C in FIG.

With reference to FIGS. 1 to 4, the motor capable of efficiently dissipating heat according to the present invention includes a housing 10, an operating space 16 is provided in the housing 10, and a control space 24 is provided in the housing 10. A lid plate 13 for closing the operating space 16 is provided at the left end of the operating space 16, and six exhaust grooves 14 are formed in the lid plate 13, and the exhaust grooves 14 form the inside of the operating space 16. A motor shell 55 is provided in the working space 16, a rotating space 21 is provided in the motor shell 55, and a rotor 19 is provided in the rotating space 21. Two stators 20 are fixedly connected to the upper and lower end walls of the rotating space 21, and the two stators 20 are provided vertically symmetrically with respect to the rotor 19. A motor shaft 25 whose other end is located outside is provided at the right end of 19, and heat radiating plates 18 are provided at the four end faces of the motor shell 55, and the heat radiating plate 18 dissipates the amount of heat in the motor shell 55. A heat conduction tube 17 is provided on the end surface of the heat radiation plate 18 away from the motor shell 55, and a conduit 15 is provided in the heat conduction tube 17 and flows in the conduit 15. The amount of heat in the heat radiating plate 18 can be removed by the coolant, and when the fan 22 fixedly connected to the motor shaft 25 is provided in the operating space 16 and the motor shaft 25 rotates, Wind is blown by the operation of the fan 22 to cool it, a storage space 11 is provided on the lower end wall of the operating space 16, a coolant is stored in the storage space 11, and the right end of the storage space 11 is stored. A water cooling mechanism 57 is provided on the wall, the water cooling mechanism 57 includes a push plate 35, and a cooling liquid can be sent by moving the push plate 35 left and right, and a control mechanism 56 is provided on the right end wall of the working space 16. The control mechanism 56 is provided and includes a drive friction wheel 23 fixedly connected to the motor shaft 25, the drive friction wheel 23 is located in the control space 24, and is below the drive friction wheel 23. Is provided with a moving friction ring 43 that can mesh with the drive friction wheel 23, and the water cooling mechanism 57 operates and stops when the water cooling mechanism 57 gains or loses power due to the horizontal movement of the moving friction wheel 43. Is controlled.

The water cooling mechanism 57 includes a liquid return space 54 provided on the upper end wall of the storage space 11, and the liquid return space 54 communicates the conduit 15 with the storage space 11, and the liquid return space 54 A first check valve 12 is provided at an end close to the storage space 11, and a liquid pushing space 36 communicating with the storage space 11 is provided on the right end wall of the storage space 11. A second check valve 38 is provided at the communication port of the liquid push space 36, and a liquid entry space 53 that communicates the liquid push space 36 and the pipeline 15 is provided on the upper end wall of the liquid push space 36. A third check valve 37 is provided at an end close to the liquid push space 36 in the liquid entry space 53, the push plate 35 is located in the liquid push space 36, and the liquid push space 36 is provided. A moving space 30 is provided on the right end wall of the moving space 30, and the moving plate 31 is connected to the moving space 30 so as to be slidable, and the moving space 30 and the moving plate 31 are connected to the moving space 30. A horizontal spring 29 is provided, and the moving rack 33 is fixedly connected to the lower left end surface of the moving plate 31, and the other end of the moving rack 33 is fixedly connected to the left end surface of the push plate 35. The driven shaft 34 is rotatably connected to the front end wall of the moving space 30, and the incomplete gear 32 meshed with the moving rack 33 is fixedly connected to the front end of the driven shaft 34.

The control mechanism 56 includes a rotating shaft 52 connected to the right end wall of the control space 24 so as to be rotatable, and the moving friction wheel 43 is connected to the rotating shaft 52 so as to be slidable. An annular space 45 is provided in the annular space 43, and the bow-shaped block 44 is connected to the annular space 45 so as to be slidable, and the fixed block 51 is fixedly connected to the right end wall of the control space 24. A translation space 49 is provided in the fixed block 51, an electric magnet 50 is fixedly connected to the right end wall of the translation space 49, and a translation plate 47 slides in the translation space 49. A return spring 48 that connects the translation plate 47 and the electromagnet 50 is connected in the translation space 49 so that the translation rod 46 is fixed to the left end surface of the translation plate 47. The other end of the connecting rod 46 was fixedly connected to the right end surface of the bow-shaped block 44, and was connected to the rear side of the turning shaft 52 so as to be rotatable to the right end wall of the control space 24. A rotating shaft 40 is provided, and a transmission friction ring 39 that can mesh with the bow-shaped block 44 is fixedly connected to the rotating shaft 40, and a direction changing bevel gear 26 is fixedly connected to the left end of the rotating shaft 40. The transmission shaft 28 is connected to the lower end wall of the moving space 30 so as to be rotatable, the upper end of the transmission shaft 28 is located in the control space 24, and the direction changing umbrella is attached to the upper end of the transmission shaft 28. The rotary cap gear 27 that meshes with the gear 26 is fixedly connected, the transmission cap gear 42 is fixedly connected to the lower end of the transmission shaft 28, and the transmission cap gear 42 is fixedly connected to the rear end of the driven shaft 34. The meshed driven cap gears 41 are fixedly connected.

The incomplete gear 32 is a gear having only half a tooth, and the cooling liquid can only enter the liquid pushing space 36 from the storage space 11 by the second check valve 38, and the third check valve 37. The coolant can only enter the liquid entry space 53 from the liquid push space 36, and the coolant can only enter the storage space 11 from the liquid return space 54 by the first check valve 12.

The magnetic force of the electromagnet 50 is stronger than the elasticity of the return spring 48.

In the initial state, the incomplete gear 32 is just meshed with the moving rack 33, the push plate 35 is located on the far right side, the horizontal spring 29 is in a loosened state, and the moving friction wheel 43 is located on the leftmost side. The return spring 48 is in a loosened state, the moving friction wheel 43 meshes with the drive friction wheel 23, the moving friction wheel 43 meshes with the transmission friction wheel 39, and the inside of the storage space 11 and the liquid pushing space 36. Is where the coolant is stored.

When the motor operates, the two stators 20 are energized to generate a magnetic field, and the rotor 19 rotates by the magnetic force of the magnetic field to rotate the motor shaft 25 to output power, and the rotor 19 and the motor shaft 25 are output. The amount of heat is generated by the rotation of and is transmitted to the heat radiating plate 18 via the motor shell 55, the fan 22 is rotated by the rotation of the motor shaft 25, and the fan 22 produces wind and is on the upper surface of the heat radiating plate 18. The amount of heat is removed, and the hot air is separated from the working space 16 by the exhaust groove 14, whereby the amount of heat in the working space 16 is dissipated to the outside, and heat is dissipated to the motor.
At the same time that heat is dissipated to the motor, the motor shaft 25 rotates to rotate the drive friction wheel 23 to rotate the moving friction wheel 43, and the transmission friction wheel 39 interlocks to rotate to rotate the rotation shaft 40. The direction-changing cap gear 26 is interlocked to rotate to rotate the rotary cap gear 27, the transmission shaft 28 is interlocked to rotate to rotate the transmission cap gear 42, and the driven cap gear 41 is interlocked to rotate to rotate the driven shaft 34. Since the incomplete gear 32 rotates in conjunction with the incomplete gear 32 and the incomplete gear 32 just meshes with the moving rack 33 in the initial state, the moving rack 33 is driven by the rotation of the incomplete gear 32 to move to the left, and the moving plate 31 Move to the left and extend the horizontal spring 29, the moving rack 33 moves to the left and the push plate 35 moves to the left, and the push plate 35 is moved by the second check valve 38 and the third check valve 37. Moves to the left, the coolant in the liquid pushing space 36 is pushed into the conduit 15 via the liquid-filled space 53, and the original coolant in the conduit 15 is returned to the liquid return space 54. And the first check valve 12 enters the storage space 11.
When the push plate 35 moves to the leftmost end, the incomplete gear 32 rotates half a turn and does not mesh with the moving rack 33, and the moving plate 31 moves the push plate 35 to the left via the moving rack 33 due to the elasticity of the horizontal spring 29. It is moved to return to the initial state, the coolant enters the liquid push space 36 from the storage space 11 and returns by the second check valve 38 and the third check valve 37, and the incomplete gear 32 continues to rotate, and the above The mechanical operation of the above is repeated, and the amount of heat in the heat radiating plate 18 is removed by the flow of the cooling liquid, whereby further cooling processing for the motor is realized.
When the work rate of the motor is small and the cooling process by the water cooling mechanism 57 is not required, the electric magnet 50 is activated, the electric magnet 50 attracts the parallel moving plate 47, the parallel moving plate 47 moves to the left, and the return spring 48 is moved. Compressed, the translation plate 47 moves to the left, the connecting rod 46 moves to the left, and the bow block 44 interlocks to move to the left, and finally the moving friction wheel 43 is driven to the left. It moves and does not mesh with the direction changing bevel gear 26 and the transmission friction wheel 39. At this time, the rotation of the motor shaft 25 does not rotate the incomplete gear 32, and the water cooling mechanism 57 stops.

The above is merely a specific embodiment of the invention of the present application, and the scope of protection of the invention of the present application is not limited to this. Changes and replacements that come to mind through all creative labor are covered by the scope of the invention of the present application. Therefore, the scope of protection of the present invention is based on the scope of protection in which the request for rights is limited.

Claims (5)

A housing is included, an operating space is provided in the housing, a control space is provided in the housing, and a lid plate for closing the operating space is provided at the left end of the operating space. Six exhaust grooves are formed in the above, and hot air in the working space can be discharged by the exhaust grooves, a motor shell is provided in the working space, and a rotating space is provided in the motor shell. A rotor is provided in the rotating space, two stators are fixedly connected to the upper and lower end walls of the rotating space, and the two stators are positioned around the rotor. A motor shaft is provided symmetrically at the right end of the rotor and the other end is located outside, heat radiating plates are provided at the four end faces of the motor shell, and the heat radiating plate is provided inside the motor shell. A heat conduction tube is provided on the end face of the heat radiation plate away from the motor shell, a conduit is provided in the heat conduction tube, and the coolant flowing in the conduit provides. The amount of heat in the heat radiating plate can be removed, and a fan fixedly connected to the motor shaft is provided in the operating space, and when the motor shaft rotates, the wind is blown by the operation of the fan. A storage space is provided in the lower end wall of the working space, a coolant is stored in the storage space, and a water cooling mechanism is provided in the right end wall of the storage space. A push plate is included, and the coolant can be sent by moving the push plate left and right. A control mechanism is provided on the right end wall of the working space, and the control mechanism is fixedly connected to the motor shaft. A moving friction wheel including a ring, the driving friction wheel is located in the control space, and a moving friction wheel capable of meshing with the driving friction wheel is provided under the drive friction wheel, and the horizontal movement of the moving friction wheel causes the movement. A motor capable of radiating heat efficiently, characterized in that the operation and stop of the water cooling mechanism are controlled by the water cooling mechanism gaining or losing power. The water cooling mechanism includes a liquid return space provided on the upper end wall of the storage space, the liquid return space communicates with the pipeline and the storage space, and is in the liquid return space and close to the storage space. A first check valve is provided at the end of the storage space, a liquid push space communicating with the storage space is provided on the right end wall of the storage space, and a second reverse is provided at the communication port between the storage space and the liquid push space. A stop valve is provided, a liquid-filling space connecting the liquid pushing space and the pipeline is provided on the upper end wall of the liquid pushing space, and a third is provided at the end of the liquid-filling space close to the liquid pushing space. A check valve is provided so that the push plate is located in the liquid push space, a moving space is provided on the right end wall of the liquid push space, and the moving plate can slide in the moving space. A horizontal spring is provided in the moving space to connect the moving space and the moving plate, and the moving rack is fixedly connected to the lower left end surface of the moving plate, and the moving rack of the moving rack is connected. The other end is fixedly connected to the left end surface of the push plate, is connected to the front end wall of the moving space so that the driven shaft can rotate, and the front end of the driven shaft is an incomplete gear that meshes with the moving rack. The motor capable of efficiently dissipating heat according to claim 1, wherein the motors are fixedly connected to each other. The control mechanism includes a rotating shaft that is rotatably connected to the right end wall of the control space, is connected to the rotating shaft so that the moving friction wheel can slide, and is annular in the moving friction wheel. A space is provided, and a bow-shaped block is connected so as to slide in the annular space, a fixed block is fixedly connected to the right end wall of the control space, and a translation space is contained in the fixed block. An electromagnet is fixedly connected to the right end wall of the parallel movement space, the parallel movement plate is connected so as to slide in the parallel movement space, and the parallel movement is in the parallel movement space. A return spring that connects the plate and the electromagnet is connected, a connecting rod is fixedly connected to the left end surface of the translation plate, and the other end of the connecting rod is fixedly connected to the right end surface of the bow-shaped block. A rotating shaft connected to the right end wall of the control space so as to be rotatable is provided on the rear side of the rotating shaft, and a transmission friction ring capable of engaging with the bow-shaped block is fixedly connected to the rotating shaft. A direction-changing cap gear is fixedly connected to the left end of the rotating shaft, is connected to the lower end wall of the moving space so that the transmission shaft can rotate, and the upper end of the transmission shaft is located in the control space. A rotary cap gear that meshes with the direction-changing cap gear is fixedly connected to the upper end of the transmission shaft, and a transmission cap gear is fixedly connected to the lower end of the transmission shaft to the rear end of the driven shaft. Is a motor capable of efficiently dissipating heat according to claim 2, wherein the driven umbrella gear that meshes with the transmission umbrella gear is fixedly connected. The incomplete gear is a gear with only half teeth, the second check valve allows the coolant to only enter the liquid push space from the storage space, and the third check valve allows the coolant to enter the liquid push space. The efficiency according to claim 2, wherein the liquid pushing space can only enter the liquid entry space, and the first check valve allows the coolant to only enter the storage space from the liquid return space. A motor that can dissipate heat well. The motor capable of efficiently dissipating heat according to claim 3, wherein the magnetic force of the electromagnet is stronger than the elasticity of the return spring.

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