CN218846636U - Cooling device for sintered material - Google Patents

Abstract

The utility model discloses a sintered material's cooling device, including the cooler bin, put the thing platform, the both sides of cooler bin are provided with respectively and put the thing platform, are provided with the air supply subassembly on the cooler bin, are provided with in the cooler bin and put the thing basket, and the cooler bin both sides are provided with chamber door A, chamber door B respectively, put and be provided with cylinder A on the thing platform, the bottom surface of putting the thing platform is provided with the support frame. The utility model discloses can be when the rare earth material after the cooling sintering, the inside humidity of monitoring cooling box prevents to influence rare earth material's performance because of humidity is too high. Through the arrangement of the cooling box, wind power can be concentrated more, and the air cooling efficiency is improved. Through the arrangement of the roller A and the roller B, the article placing basket is convenient to move. The utility model discloses simple to use can reduce the cooling time of rare earth material after the sintering, also can avoid the moisture in the air to influence rare earth material's performance, has great advantage for traditional cooling method that stews.

Description

Cooling device for sintered material

Technical Field

The utility model belongs to the technical field of cooling arrangement, especially, relate to a sintered material's cooling device.

Background

Rare earth sintered magnets are a class of functional materials that are critical for energy conservation and functionality improvement, and the range of applications and yield thereof is expanding year by year. Rare earth sintered magnets are widely used for drive motors of hybrid cars and electric vehicles, motors in electric power steering systems, motors in air-conditioning compressors, and voice coil motors in hard disk drives, and thus are in great demand. The rare earth sintered magnet lowers its coercive force at high temperature and undergoes irreversible thermal demagnetization. Therefore, high-temperature sintering is an essential step in the preparation process of the rare earth materials.

After high-temperature sintering, the rare earth material needs to be cooled to a certain temperature to carry out the next process due to the high temperature. It is common practice to cool the rare earth material by standing, but this cooling method is slow, and if the air is humid, the moisture in the air may affect the performance of the rare earth material. Therefore, a device capable of drying and cooling with high efficiency is required.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a sintered material's cooling device can solve the rare earth material cooling after the high temperature sintering slow, receives the problem that the humidity influences.

The utility model discloses a following technical scheme can realize.

The utility model provides a pair of sintered material's cooling device, including the cooler bin, put the thing platform, the both sides of cooler bin are provided with respectively and put the thing platform, are provided with the air supply subassembly on the cooler bin, are provided with in the cooler bin and put the thing basket, and the cooler bin both sides are provided with chamber door A, chamber door B respectively, it is provided with cylinder B on the thing platform to put, and the bottom surface of putting the thing platform is provided with the support frame.

Preferably, put thing basket one end and be provided with chucking subassembly A, put the thing basket other end and be provided with chucking subassembly B, chucking subassembly A, including fixed block A, slide bar A, the dead lever, the pulley, be provided with spout A on the fixed block A, the fluting, fluting and spout A intercommunication, slide bar A arranges in spout A and forms sliding connection, and spout A is connected with the one end of dead lever, outside the dead lever stretches out fixed block A through the fluting, the other end of dead lever passes through connecting rod A and is connected with the pulley.

Preferably, the box door B is provided with a vent, a baffle plate and a partition plate are arranged on the vent, two ends of the baffle plate are rotatably connected with the box door B through rotating shafts, and stop blocks are arranged on the inner walls of two sides of the vent.

Preferably, chamber door B inner wall bilateral symmetry is provided with buffering subassembly, spout B, buffering subassembly, including slide bar B, buffering strip, slide bar B symmetry sets up in buffering strip both sides, and slide bar B stretches into the inside sliding connection that forms of spout B, be provided with elastic component B in the spout B.

Preferably, the fixed block A is provided with sliding chutes C, the sliding chutes A are symmetrically arranged on two sides of the sliding chutes C, and elastic pieces A are arranged in the sliding chutes A.

Preferably, chucking subassembly B, including fixed block B, the dop, fixed block B passes through connecting rod B and dop formation is connected, the dop shape corresponds the setting with spout C.

Preferably, the air supply assembly is connected with the box door A through a vent pipe, and the box door A is provided with a vent pipe and a clamping ring.

Preferably, a groove and a humidity detector are arranged in the cooling box, and a plurality of rollers B are arranged on the groove.

Preferably, an infrared temperature detector is arranged at the top of one side, close to the box door B, in the cooling box, and a control assembly is arranged outside the cooling box.

The beneficial effects of the utility model reside in that:

the utility model discloses can be when the rare earth material after the cooling sintering, the inside humidity of monitoring cooler bin prevents to influence rare earth material's performance because of humidity is too high. Through the arrangement of the cooling box, wind power can be concentrated more, and the air cooling efficiency is improved. Through the setting of chucking subassembly A and chucking subassembly B for a plurality of puts the thing basket and can link into an organic whole, is convenient for put taking out of thing basket. Through the arrangement of the roller A and the roller B, the article placing basket is convenient to move. The utility model discloses simple to use can reduce the cooling time of rare earth material after the sintering, also can avoid the moisture in the air to influence rare earth material's performance, has great advantage for traditional cooling method that stews.

Drawings

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

FIG. 2 is a schematic structural diagram of the region A of the present invention;

fig. 3 is a schematic structural view of the clamping assembly a and the clamping assembly B of the present invention;

fig. 4 is a schematic structural view of the sliding chute a of the present invention;

fig. 5 is a schematic structural view of the box door B of the present invention;

fig. 6 is a schematic structural view of a stop of the box door B of the present invention;

in the figure: 1-cooling box, 11-groove, 12-humidity detector, 13-roller B, 14-infrared temperature detector, 15-control component, 2-object placing table, 21-roller a, 22-supporting frame, 3-air supply component, 31-air pipe, 4-object placing basket, 5-door a, 51-air pipe, 52-clamping ring, 6-door B, 61-air vent, 62-baffle, 63-clapboard, 64-rotating shaft, 65-baffle, 66-sliding chute B, 67-elastic component B, 7-clamping component a, 71-fixing block a, 72-sliding rod a, 73-fixing rod, 74-pulley, 75-sliding chute a, 76-groove, 77-connecting rod a, 78-sliding chute C, 79-elastic component a, 8-clamping component B, 81-fixing block B, 82-clamping head, 83-connecting rod B, 9-buffer component, 91-sliding rod B, 92-buffer strip.

Detailed Description

The technical solutions of the present invention are further described below, but the scope of protection claimed is not limited to the described ones.

Example 1:

as shown in fig. 1 to 6, a cooling device for sintered materials, includes a cooling box 1 and a storage table 2, the storage table 2 is respectively arranged on two sides of the cooling box 1, an air supply assembly 3 is arranged on the cooling box 1 and used for supplying dry air into the cooling box 1, the air supply temperature of the air supply assembly 3 is controllable, a storage basket 4 is arranged in the cooling box 1, a box door A5 and a box door B6 are respectively arranged on two sides of the cooling box 1, the box door A5 and the box door B6 are hinged on the cooling box 1 and are both side-opening doors, a roller B21 is arranged on the storage table 2, the storage basket 4 can be conveniently moved, and a support frame 22 is arranged on the bottom surface of the storage table 2. The storage table 2 can be used for conveniently storing the basket 4 in and out of the cooling box 1, and the storage basket 4 is of a hollow frame structure so as to be ventilated and used for storing sintered rare earth materials.

Put thing basket 4 one end and be provided with chucking subassembly A7, put the thing basket 4 other end and be provided with chucking subassembly B8, chucking subassembly A7, including fixed block A71, slide bar A72, dead lever 73, pulley 74, be provided with spout A75 on the fixed block A71, fluting 76 and spout A75 intercommunication, slide bar A72 are arranged in spout A75 and are formed sliding connection, and spout A75 is connected with the one end of dead lever 73, outside dead lever 73 stretches out fixed block A71 through fluting 76, the other end of dead lever 73 passes through connecting rod A77 and is connected with pulley 74, and the setting up of fluting 76 makes slide bar A72 when sliding, and dead lever 73 also can follow the slip. The pulley 74 facilitates the chuck 82 to push the slide bars A72 away from each other and the elastic member A79 is compressed when the chuck 82 extends into the slide groove C78. After the chuck 82 extends into the sliding chute C78, the pulleys 74 on the two sides approach again under the condition that the elastic piece A79 recovers to extend because the diameter of the connecting rod B83 is smaller than that of the chuck 82, and then the chuck 82 is limited.

Through the setting of chucking subassembly A7, chucking subassembly B8 for a plurality of thing baskets 4 of putting can form after putting into the cooler bin 1 and connect, only need stimulate one of them thing basket 4 of putting, and remaining thing basket 4 homoenergetic synchronous motion is convenient for take out the thing basket 4 of putting at 1 middle part of cooler bin.

The box door B6 is provided with a vent 61 for discharging gas in the cooling box 1, so that the gas in the cooling box 1 can flow, the vent 61 is provided with a baffle sheet 62 and a partition plate 63, two ends of the baffle sheet 62 are rotationally connected with the box door B6 through a rotating shaft 64, when the air supply assembly 3 operates, the generated air flow enables the baffle sheet 62 to rotate towards the outer side of the cooling box 1, so that the gas flows out of the vent 61, the inner walls on two sides of the vent 61 are provided with a stop block 65, and the stop block 65 can prevent the baffle sheet 62 from rotating towards the inner side direction of the cooling box 1, so that the external air is prevented from entering the cooling box 1 in a natural state.

Chamber door B6 inner wall bilateral symmetry is provided with buffering subassembly 9, spout B66, and buffering subassembly 9 can prevent to put thing basket 4 direct striking chamber door B6, buffering subassembly 9, including slide bar B91, buffering strip 92, slide bar B91 symmetry sets up in buffering strip 92 both sides, and slide bar B91 stretches into the formation sliding connection of spout B66, be provided with elastic component B67 in the spout B66. When the basket 4 impacts the buffer assembly 9, the sliding rod B91 moves towards the sliding groove B66, the elastic piece B67 is compressed, partial kinetic energy is absorbed, and the buffer effect is achieved.

Be provided with spout C78 on the fixed block A71, the deepest of spout C78 is arc, spout A75 symmetry sets up the both sides at spout C78, is equipped with elastic component A79 in the spout A75. The distance between the pulleys 74 on the two sides is smaller than the width of the sliding groove C78 in a natural state, so that after the clamping head 82 completely extends into the sliding groove C78, the pulleys 74 on the two sides can limit the clamping head 82, the clamping head 82 is prevented from being separated from the sliding groove C78, and the two storage baskets 4 are connected.

The clamping assembly B8 comprises a fixing block B81 and a clamping head 82, the fixing block B81 is connected with the clamping head 82 through a connecting rod B83, the clamping head 82 is arranged in a shape corresponding to the sliding groove C78, and the front end of the clamping head 82 is arc-shaped, so that the pulley 74 can be pushed open towards two sides conveniently.

The air supply assembly 3 is connected with the box door A5 through a vent pipe 31, the vent pipe 31 is a flexible pipe and can stretch or bend so as to adapt to the opening and closing actions of the box door A5, the box door A5 is provided with a vent pipe 51 and a clamping ring 52, the vent pipe 31 is fixed in the vent pipe 51 through the clamping ring 52, and the vent pipe 51 penetrates through the box door A5.

A groove 11 and a humidity detector 12 are arranged in the cooling box 1, a plurality of rollers B13 are arranged on the groove 11, and the rollers B13 are in a suspended state due to the arrangement and are convenient to rotate. The humidity detector 12 is used for detecting the humidity in the cooling box 1 so as to avoid that the humidity is too high to influence the performance of the sintered rare earth material.

The top of one side of the box door B6 in the cooling box 1 is provided with an infrared temperature detector 14 so as to monitor whether the rare earth materials in the storage basket 4 far away from the air inlet position are reduced to proper temperature or not and avoid the condition of incomplete cooling, and a control assembly 15 is arranged outside the cooling box 1 and is used for controlling the operation of the air supply assembly 3, the temperature of air supplied by the air supply assembly 3 and displaying the monitoring data of the humidity detector 12 and the infrared temperature detector 14.

The using method comprises the following steps: detect the humidity in the cooler bin 1, if humidity that weather reason or cooler bin were originally in 1 is not conform to the requirement, can start earlier and close after air supply subassembly 3 reduces humidity, then chamber door A5 opens again, put into thing basket 4 with the rare earth material after the sintering, put into thing basket 4 from chamber door A5 one side, place and close chamber door A5 after accomplishing, adjust air supply subassembly 3's air supply temperature, and start air supply subassembly 3, reach the requirement after the rare earth material temperature of 14 monitoring of infrared thermoscope reaches, it can to take out thing basket 4 to open chamber door B6.

Claims (9)

1. A cooling device for a sintered material, characterized in that: including cooler bin (1), put thing platform (2), the both sides of cooler bin (1) are provided with respectively and put thing platform (2), are provided with air supply subassembly (3) on cooler bin (1), are provided with in cooler bin (1) and put thing basket (4), and cooler bin (1) both sides are provided with chamber door A (5) respectively, chamber door B (6), be provided with cylinder A (21) on putting thing platform (2), the bottom surface of putting thing platform (2) is provided with support frame (22).

2. A cooling device for a sintered material as claimed in claim 1, wherein: put thing basket (4) one end and be provided with chucking subassembly A (7), put thing basket (4) other end and be provided with chucking subassembly B (8), chucking subassembly A (7), including fixed block A (71), slide bar A (72), dead lever (73), pulley (74), be provided with spout A (75) on fixed block A (71), fluting (76) and spout A (75) intercommunication, slide bar A (72) are arranged in spout A (75) and are formed sliding connection, and spout A (75) are connected with the one end of dead lever (73), outside fixed block A (71) is stretched out through fluting (76) dead lever (73), the other end of dead lever (73) passes through connecting rod A (77) and is connected with pulley (74).

3. A cooling device for a sintered material as claimed in claim 1, wherein: the refrigerator door B (6) is provided with a vent (61), a baffle (62) and a partition plate (63) are arranged on the vent (61), two ends of the baffle (62) are rotatably connected with the refrigerator door B (6) through rotating shafts (64), and stop blocks (65) are arranged on inner walls of two sides of the vent (61).

4. A cooling apparatus for a sintered material as claimed in claim 1, wherein: chamber door B (6) inner wall bilateral symmetry is provided with buffering subassembly (9), spout B (66), buffering subassembly (9), including slide bar B (91), buffering strip (92), slide bar B (91) symmetry sets up in buffering strip (92) both sides, and slide bar B (91) stretch into spout B (66) and form sliding connection, be provided with elastic component B (67) in spout B (66).

5. A cooling device for a sintered material as claimed in claim 2, wherein: be provided with spout C (78) on fixed block A (71), spout A (75) symmetry sets up in the both sides of spout C (78), is provided with elastic component A (79) in spout A (75).

6. A cooling apparatus for a sintered material as claimed in claim 2, wherein: chucking subassembly B (8), including fixed block B (81), dop (82), fixed block B (81) form with dop (82) through connecting rod B (83) and are connected, dop (82) shape corresponds the setting with spout C (78).

7. A cooling apparatus for a sintered material as claimed in claim 1, wherein: the air supply assembly (3) is connected with the box door A (5) through a vent pipe (31), and the box door A (5) is provided with a vent pipe (51) and a clamping ring (52).

8. A cooling apparatus for a sintered material as claimed in claim 1, wherein: a groove (11) and a humidity detector (12) are arranged in the cooling box (1), and a plurality of rollers B (13) are arranged on the groove (11).

9. A cooling apparatus for a sintered material as claimed in claim 1, wherein: the top of one side, close to the box door B (6), of the cooling box (1) is provided with an infrared temperature detector (14), and a control assembly (15) is arranged outside the cooling box (1).

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