CN223649537U - A cooling device for magnetic components - Google Patents

Abstract

The utility model discloses cooling equipment for a magnetic assembly, which comprises a cooling platform, wherein a plurality of cooling stations and a refrigerating module are arranged on the cooling platform, the cooling stations are used for placing a jig carrying the magnetic assembly to be cooled, and the refrigerating module is arranged at a position corresponding to the cooling stations and is used for cooling the magnetic assembly on the jig. According to the utility model, the plurality of cooling stations for placing the jig provided with the magnetic component to be cooled are arranged on the cooling platform, and the refrigerating modules are arranged at the corresponding positions of the cooling stations, so that the jig and the magnetic component on the cooling stations can be cooled down rapidly, the cooling efficiency of the jig and the magnetic component is improved, the stability of the performance of the magnetic component is ensured, the magnetic component can enter the next production process in time, and the production efficiency of the subsequent magnetic component is improved. Meanwhile, certain occupational hazards can be eliminated.

Description

Cooling equipment of magnetic assembly

Technical Field

The utility model relates to the technical field of magnetic assembly cooling, in particular to cooling equipment of a magnetic assembly.

Background

In the current magnetic assembly production process flow, the bonded magnetic assembly is usually placed in a tunnel furnace together with a jig, and the adhesive is heated to reach a curing temperature. After solidification, the magnet assembly is removed from the tunnel oven and cooled to ensure its stable performance.

However, the current commonly adopted fan cooling mode has poor effect in the face of a high-temperature jig, so that the cooling efficiency of the magnetic assembly is low, the magnetic assembly on the production line is backlogged, the follow-up procedure is delayed, and the production efficiency is reduced. In addition, the existing cooling operation mainly depends on manual work, and when the jig cannot be cooled in time, operators can possibly cause body injury by contacting the high-temperature jig for a long time.

Disclosure of utility model

The utility model aims to provide cooling equipment for a magnetic assembly, which can effectively improve the cooling efficiency of the magnetic assembly.

In order to achieve the purpose, the cooling equipment of the magnetic assembly comprises a cooling platform, wherein a plurality of cooling stations and a refrigerating module are arranged on the cooling platform, the cooling stations are used for placing jigs bearing the magnetic assembly to be cooled, and the refrigerating module is arranged at a position corresponding to the cooling stations and is used for cooling the magnetic assembly on the jigs.

The cooling platform is characterized by further comprising a detection module and an alarm module, wherein the detection module and the alarm module are arranged on the cooling platform, and the detection module is arranged at a position corresponding to the cooling station.

Preferably, the detection module is a detection optical fiber, and the alarm module is a buzzer.

Preferably, the cooling stations are uniformly distributed.

Preferably, the cooling platform is a heat conducting plate, and the cooling station is arranged at the top of the heat conducting plate.

Preferably, the heat conducting plate is made of a metal copper material.

Preferably, the cooling platform further comprises a supporting cabinet, and the supporting cabinet is arranged below the cooling platform.

Preferably, the refrigerating module is a refrigerating sheet, and a plurality of refrigerating sheets are arranged at the bottom of the heat conducting plate and correspond to the positions of the cooling stations.

The preferred scheme still includes the water-cooling module, and the water-cooling module sets up on the supporting cabinet, and the cold water pipeline of water-cooling module sets up on the refrigeration piece.

Preferably, universal wheels are arranged at the bottom of the supporting cabinet.

By adopting the scheme, the jig and the magnetic assembly on the cooling station can be cooled rapidly by arranging the plurality of cooling stations for placing the jig carrying the magnetic assembly to be cooled on the cooling platform and arranging the refrigerating module at the corresponding position of the cooling station, so that the cooling efficiency of the jig and the magnetic assembly is improved, the stability of the performance of the magnetic assembly is ensured, the magnetic assembly can enter the next production process in time, and the production efficiency of the subsequent magnetic assembly is improved. Meanwhile, certain occupational hazards can be eliminated.

Drawings

FIG. 1 is a schematic view showing the overall structure of a cooling apparatus according to an embodiment of the present utility model;

FIG. 2 is a bottom view of the overall structure of a cooling apparatus in an embodiment of the present utility model;

Fig. 3 is a top view of a cooling apparatus in an embodiment of the utility model.

Description of the reference numerals:

1. The device comprises a cooling platform, a cooling station, a cooling plate, a cooling module, a cooling sheet, a detecting module, a detecting optical fiber, an alarm module, a buzzer, a supporting cabinet, a universal wheel, a jig, a water cooling module and a water cooling module.

Detailed Description

The utility model will now be further described with reference to the drawings and detailed description.

The embodiment provides cooling equipment for a magnetic assembly, as shown in fig. 1 to 3, the cooling equipment comprises a cooling platform 1, a plurality of cooling stations 10 and a cooling module 2 are arranged on the cooling platform 1, the cooling stations 10 are used for placing jigs 6 bearing the magnetic assembly to be cooled, and the cooling module 2 is arranged at a position corresponding to the cooling stations 10 and used for cooling the magnetic assembly on the jigs 6.

Be equipped with a plurality of cooling stations 10 on the cooling platform 1 of this embodiment, every cooling station 10 corresponds to be equipped with refrigerating module 2, only need put tool 6 to cooling station 10 when cooling, refrigerating module 2 can cool off tool 6 and the magnetic assembly on the cooling station 10 through cooling platform 1.

The embodiment further comprises a control module (not shown in the figure), and the control module is arranged to control the refrigeration temperature of the refrigeration module 2, so that the cooling temperature on the cooling platform 1 can be adjusted to the temperature range according to the actual requirement. In addition, the cooling station 10 of the embodiment can adapt to different jigs 6 and magnetic assemblies, is flexible to use, can effectively improve cooling efficiency, and further improves the production efficiency of the subsequent magnetic assemblies.

As shown in fig. 1 and 3, the cooling system further comprises a detection module 3 and an alarm module 4, wherein the detection module 3 and the alarm module 4 are arranged on the cooling platform 1, and the detection module 3 is arranged at a position corresponding to the cooling station 10.

In this embodiment, the detection module 3 is disposed at a position corresponding to each cooling station 10, and the detection module 3 can detect whether the jig 6 and the magnetic assembly are placed on the cooling station 10. After the jig 6 and the magnetic assembly on the cooling station 10 are cooled, the alarm module 4 corresponding to the cooling station 10 can give an alarm to remind an operator to take down the jig 6 and the magnetic assembly which are cooled from the cooling station 10, so that the cooling device is convenient to use. If the detection module 3 detects that the jig 6 and the magnetic assembly are not placed on the cooling station 10, the alarm module 4 corresponding to the cooling station 10 does not give an alarm, and the design is ingenious.

Further, the detection module 3 is a detection optical fiber 30, and the alarm module 4 is a buzzer 40. The detection optical fiber 30 of the embodiment has high sensitivity, is favorable for accurately detecting the jig 6 and the magnetic assembly on the cooling station 10, has high response speed and clear sound of the buzzer 40, and can adapt to complex production and processing environments.

As shown in fig. 3, the cooling stations 10 of the present embodiment are uniformly distributed, so as to ensure that each cooling station 10 can obtain a uniform cooling effect. And the cooling stations 10 are uniformly distributed, so that the space utilization rate of the cooling platform 1 can be improved, and the cooling efficiency can be improved.

As shown in fig. 1, the cooling platform 1 is a heat conducting plate 11, and the cooling station 10 is disposed on top of the heat conducting plate 11. The cooling platform 1 of the embodiment adopts the heat-conducting plate 11, so that the temperature of the heat-conducting plate 11 can be quickly reduced by the refrigeration module 2, and the cooling efficiency is improved. And the heat-conducting plate 11 can provide a uniform temperature distribution so that each cooling station 10 on the heat-conducting plate 11 can obtain a uniform cooling effect.

Further, the heat conducting plate 11 of the embodiment is made of a metal copper material, and the metal copper has excellent heat conducting performance, so that the temperature of the heat conducting plate 11 can be quickly reduced by the refrigeration module 2, and the cooling efficiency is improved. And the metal copper has good corrosion resistance and rigidity, and the service life of the equipment is effectively prolonged. Meanwhile, the production and the processing are more convenient. In addition, when the jig 6 and the magnetic component are placed on the cooling platform 1 made of a metallic copper material, no adsorption is generated between the metallic copper and the magnetic component, so that no influence is exerted on the magnetic component.

As shown in fig. 1 and 2, a supporting cabinet 5 is further included, the supporting cabinet 5 being disposed below the cooling platform 1. The support cabinet 5 of the present embodiment provides stable support for the cooling platform 1, ensuring stability and reliability of the entire cooling apparatus.

As shown in fig. 2, the cooling module 2 is a cooling plate 20, and a plurality of cooling plates 20 are disposed at the bottom of the heat conducting plate 11 and correspond to the positions of the cooling stations 10.

The cooling fin 20 of the embodiment is directly disposed at the bottom of the heat conducting plate 11 and corresponds to the cooling station 10, so that the temperature at the cooling station 10 can be rapidly reduced, which is beneficial to improving the cooling efficiency. In addition, the cooling fins 20 can be precisely temperature controlled, which helps to ensure that the magnetic assembly maintains a constant temperature during cooling, avoiding performance differences due to temperature fluctuations. The cooling fin 20 of this embodiment is Zave V type, the cooling temperature in the room temperature space can be as low as 3 ℃, and other types of cooling fin 20 can be used in other embodiments.

As shown in fig. 2, the cooling device further comprises a water cooling module 7, wherein the water cooling module 7 is arranged on the supporting cabinet 5, and a cold water pipeline of the water cooling module 7 is arranged on the refrigerating sheet 20. Since the cooling fin 20 generates heat during cooling, the water cooling module 7 is further provided in this embodiment, and the cooling water pipeline of the water cooling module 7 is disposed on the cooling fin 20, so that the heat generated by the cooling fin 20 during cooling can be taken away, thereby improving the cooling efficiency of the cooling fin 20. The water cooling module 7 of this embodiment is SLMZ-S-L24V30W, and other water cooling modules 7 may be used in other embodiments. Meanwhile, the power supply of the embodiment adopts 12V/30A for supplying power to the refrigerating sheet 20 and the water cooling module 7.

As shown in fig. 1 and 2, the universal wheels 50 are arranged at the bottom of the supporting cabinet 5 in this embodiment, so that the whole cooling device can be easily moved, whether the position adjustment is performed in the production line or the device needs to be moved to other areas for operation or maintenance, which is very convenient and fast, and improves the flexibility of use. Of course, the universal wheel 50 is provided with locking means to ensure the stability of the support cabinet 5 during cooling.

The use process of this embodiment is as follows:

After the power supply of the equipment is turned on, the refrigerating sheet 20 and the water cooling module 7 work, and wait for 120 seconds, so that the whole cooling platform 1 can be reduced to the required temperature.

The magnetic assembly is placed on the cooling station 10 of the cooling platform 1 together with the jig 6, and the detecting fiber 30 detects whether the jig 6 is present on the cooling station 10.

After waiting for a plurality of times to reduce the temperature of the jig 6 and the magnetic assembly, the buzzer 40 gives an alarm to prompt that the cooling is finished, and an operator can carry out the next production process by only taking down the jig 6 and the magnetic assembly from the cooling platform 1.

The directional terms mentioned in the present specification are defined with respect to the structures shown in the drawings, which are relative concepts, and thus may be changed accordingly according to different positions and different use states thereof. These and other directional terms should not be construed as limiting terms.

The above embodiments are only preferred embodiments of the present utility model, and are not limited to the present utility model, and all equivalent changes made according to the design key of the present utility model fall within the protection scope of the present utility model.

Claims (10)

1. A cooling device for magnetic components, characterized in that: it includes a cooling platform, the cooling platform is provided with a plurality of cooling stations and a refrigeration module, the cooling stations are used to place fixtures on which magnetic components to be cooled are placed, and the refrigeration module is set at a position corresponding to the cooling station for cooling the magnetic components on the fixture. 2. The cooling device for a magnetic component as described in claim 1, characterized in that: it further includes a detection module and an alarm module, wherein the detection module and the alarm module are disposed on the cooling platform, and the detection module is disposed at a position corresponding to the cooling station. 3. The cooling device for a magnetic component as described in claim 2, characterized in that: the detection module is a detection optical fiber, and the alarm module is a buzzer. 4. The cooling device for a magnetic component as described in claim 1, characterized in that: the cooling stations are evenly distributed. 5. The cooling device for a magnetic component as described in claim 1, wherein the cooling platform is a heat-conducting plate, and the cooling station is located on top of the heat-conducting plate. 6. The cooling device for a magnetic component as described in claim 5, wherein the heat-conducting plate is made of copper. 7. The cooling device for a magnetic component as described in claim 5, characterized in that: it further includes a support cabinet, which is disposed below the cooling platform. 8. A cooling device for a magnetic component as described in claim 7, characterized in that: the cooling module is a cooling chip, and a plurality of the cooling chips are disposed at the bottom of the heat-conducting plate and correspond to the position of the cooling station. 9. The cooling device for a magnetic component as described in claim 8, characterized in that: it further includes a water-cooling module, the water-cooling module is mounted on a support cabinet, and the cold water pipes of the water-cooling module are mounted on the cooling plate. 10. A cooling device for a magnetic component as described in claim 7, characterized in that: the bottom of the support cabinet is provided with casters.