CN214294128U - Heating mechanism for machining magnetic rotor in fluid pump - Google Patents

Abstract

The utility model relates to an interior magnetic rotor processing technology field especially relates to a heating mechanism that is used for magnetic rotor processing in the fluid pump. The magnetic rotor type magnetic motor comprises a lifting mechanism for adjusting the position of an inner magnetic rotor, wherein heating components are arranged on two sides of the lifting mechanism respectively, and each heating component comprises a heating device and a transverse driving mechanism for driving the heating device to move left and right. The utility model discloses an elevating system and two sets of heating element cooperation carry out external heating to the internal magnet rotor, can effectively reduce the transfer time.

Description

Heating mechanism for machining magnetic rotor in fluid pump

Technical Field

The utility model relates to an interior magnetic rotor processing technology field especially relates to a heating mechanism that is used for magnetic rotor processing in the fluid pump.

Background

When the inner magnetic rotor of the fluid pump is encapsulated, the initial state inner magnetic rotor needs to be placed in an injection molding machine, and the temperature difference between injection molding glue and the temperature of the inner magnetic rotor is large during injection molding, so that the encapsulation is not tight, and the initial state inner magnetic rotor needs to be heated before encapsulation; the existing heating device mostly adopts a heating box and other structures, and the box opening and the like are needed after the heating by the built-in heating mode, so that the transfer of the inner magnetic rotor is not facilitated, and the transfer time can be reduced if the inner magnetic rotor is directly heated on a transfer mechanism because the transfer time is longer; reducing heat loss.

Disclosure of Invention

An object of the utility model is to provide a heating mechanism that is used for magnetic rotor to process in the fluid pump to the not enough of prior art, this heating device adopts external heating methods, can reduce the transfer time.

A heating mechanism for machining an inner magnetic rotor of a fluid pump comprises a lifting mechanism for adjusting the position of the inner magnetic rotor, wherein heating components are arranged on two sides of the lifting mechanism respectively, and each heating component comprises a heating device and a transverse driving mechanism for driving the heating device to move left and right.

Further, elevating system includes the base plate, and the base plate is connected with the backup pad, and the upper end of backup pad is connected with the casing, is equipped with the linear module of vertical setting in the casing, and linear module is connected with the lifter, and the lower extreme of lifter stretches out the casing and is connected with the magnet.

Further, the transverse driving mechanism comprises a transverse moving block, and the transverse moving block is connected with the heating device through a transverse rod; the transverse moving block is connected with a transverse moving module.

Preferably, the two transverse moving modules are combined into a transverse linear module, the transverse linear module comprises a fixed plate, the fixed plate is connected with two fixed blocks, a screw rod is movably connected between the two fixed blocks, and the screw rod can rotate relative to the fixed blocks; one end of the screw rod penetrates through the corresponding fixed block and is connected with a transverse motor through a coupler, threads with opposite turning directions are arranged at two ends of the screw rod respectively, and two ends of the screw rod are in threaded connection with the two transverse moving blocks respectively.

Further, the fixed plate is provided with a transverse groove, the transverse moving block is connected with a transverse guide block, and the transverse guide block is inserted into the transverse groove.

Furthermore, the transverse moving block is provided with a threaded hole matched with the transverse rod, one end of the transverse rod is provided with an external thread, and the transverse rod is in threaded connection with the transverse moving block.

Preferably, the transverse rod is connected with a fixing nut at two sides of the transverse moving block respectively.

The utility model has the advantages that: the utility model discloses an elevating system and two sets of heating element cooperation carry out external heating to the internal magnet rotor, can effectively reduce the transfer time.

Drawings

Fig. 1 is a schematic structural diagram of the present embodiment.

FIG. 2 is a schematic diagram of a transverse linear module.

The reference numerals include:

1-a substrate; 2-a support plate; 3-a heating device; 4-transverse bar; 5-inner magnetic rotor; 6-magnet; 7-lifting rod; 8-a housing; 9-transverse motor; 10-coupling; 11-fixed plate; 12-lateral moving mass; 13-transverse grooves; 14-transverse guide block; 15-screw mandrel; and 16, fixing blocks.

Detailed Description

The following detailed description of the present invention is made with reference to the accompanying drawings. As shown in fig. 1-2.

Example 1: a heating mechanism 3 for processing an inner magnetic rotor of a fluid pump comprises a lifting mechanism for adjusting the position of the inner magnetic rotor 5, wherein heating components are respectively arranged on two sides of the lifting mechanism, and each heating component comprises a heating device 3 and a transverse driving mechanism for driving the heating device 3 to move left and right.

In view of the structure of the inner magnetic rotor 5, the technical scheme is provided with a bilateral symmetry heating mode, the position of the inner magnetic rotor 5 is adjusted to a proper position through the lifting mechanism, and then the transverse driving mechanisms on the left side and the right side drive the heating devices 3 to gradually approach the inner magnetic rotor 5 so as to be contacted with the inner magnetic rotor 5; when the heating device 3 is contacted with the inner magnetic rotor 5, the heating device 3 works, after the heating device is heated to a preset temperature, the transverse driving mechanisms on the two sides move the heating device 3 away, and then the inner magnetic rotor 5 is moved into the next procedure and enters the injection molding machine. The lifting mechanism and the heating device 3 can adopt the prior art; the lateral movement mechanism may employ a linear module.

Further, elevating system includes base plate 1, and base plate 1 is connected with backup pad 2, and the upper end of backup pad 2 is connected with casing 8, is equipped with the linear module (not drawn) of vertical setting in the casing 8, and linear module is connected with lifter 7, and the lower extreme of lifter 7 stretches out casing 8 and is connected with magnet 6.

The linear module can adopt a screw rod nut structure, if a vertically arranged screw rod is arranged in the shell 8, the screw rod is movably connected with the shell 8 through a bearing, a nut block is connected with the screw rod through threads, the lower end of the nut block is connected with the lifting rod 7, and the upper end of the screw rod is connected with the motor through a coupler. The lifting rod 7 can be driven to lift by a motor. And the lower end of the lifting rod 7 is fixedly connected with the inner magnetic rotor 5 through the connecting magnet 6.

Further, the transverse driving mechanism comprises a transverse moving block 12, and the transverse moving block 12 is connected with the heating device 3 through the transverse rod 4; the transverse moving block 12 is connected with a transverse moving module.

The transverse moving module can adopt a linear motor and the like.

Preferably, the two transverse moving modules are combined into a transverse linear module, the transverse linear module comprises a fixed plate 11, the fixed plate 11 is connected with two fixed blocks 16, a screw rod 15 is movably connected between the two fixed blocks 16, and the screw rod 15 can rotate relative to the fixed blocks 16; one end of the screw rod 15 penetrates through the corresponding fixed block 16 and is connected with the transverse motor 9 through the coupler 10, threads with opposite turning directions are respectively arranged at two ends of the screw rod 15, and two ends of the screw rod 15 are respectively in threaded connection with the two transverse moving blocks 12.

The two transverse moving blocks 12 are driven to move towards and away from each other through a screw rod 15; the whole structure is simplified, and the cost is reduced.

Further, the fixing plate 11 is provided with a transverse groove 13, the transverse moving block 12 is connected with a transverse guide block 14, and the transverse guide block 14 is inserted into the transverse groove 13.

In order to avoid the transverse block from shaking in the moving process to influence the moving precision, the technical scheme is provided with the transverse groove 13, and the transverse moving block 12 moves along the transverse groove 13 through the transverse guide block 14 to form directional movement and move stably.

Further, the transverse moving block 12 is provided with a threaded hole matched with the transverse rod 4, one end of the transverse rod 4 is provided with an external thread, and the transverse rod 4 is in threaded connection with the transverse moving block 12.

When heating, it is necessary to adjust the position of the heating device 3, and the traverse rod 4 is screwed to the traverse block 12, so that the heating device 3 can be laterally adjusted.

Preferably, the transverse rod 4 is connected with a fixing nut at both sides of the transverse moving block 12.

In order to prevent the transverse bar 4 from shaking during movement and moving, two fixing nuts are connected to the transverse bar 4, and the two fixing nuts clamp the transverse moving block 12, so that the position of the transverse bar 4 is fixed.

The above description is only a preferred embodiment of the present invention, and for those skilled in the art, there are variations on the detailed description and the application scope according to the idea of the present invention, and the content of the present description should not be interpreted as a limitation to the present invention.

Claims (7)

1. A heating mechanism for processing a magnetic rotor in a fluid pump is characterized in that: the magnetic rotor type magnetic motor comprises a lifting mechanism for adjusting the position of an inner magnetic rotor, wherein heating components are arranged on two sides of the lifting mechanism respectively, and each heating component comprises a heating device and a transverse driving mechanism for driving the heating device to move left and right.

2. A heating mechanism for machining of a magnetic rotor in a fluid pump according to claim 1, wherein: elevating system includes the base plate, and the base plate is connected with the backup pad, and the upper end of backup pad is connected with the casing, is equipped with the linear module of vertical setting in the casing, and linear module is connected with the lifter, and the lower extreme of lifter stretches out the casing and is connected with the magnet.

3. A heating mechanism for machining of a magnetic rotor in a fluid pump according to claim 1, wherein: the transverse driving mechanism comprises a transverse moving block, and the transverse moving block is connected with the heating device through a transverse rod; the transverse moving block is connected with a transverse moving module.

4. A heating mechanism for machining of a magnetic rotor in a fluid pump according to claim 3, wherein: the two transverse moving modules are combined into a transverse linear module, the transverse linear module comprises a fixed plate, the fixed plate is connected with two fixed blocks, a screw rod is movably connected between the two fixed blocks, and the screw rod can rotate relative to the fixed blocks; one end of the screw rod penetrates through the corresponding fixed block and is connected with a transverse motor through a coupler, threads with opposite turning directions are arranged at two ends of the screw rod respectively, and two ends of the screw rod are in threaded connection with the two transverse moving blocks respectively.

5. A heating mechanism for machining of a magnetic rotor in a fluid pump according to claim 4, wherein: the fixed plate is provided with a transverse groove, the transverse moving block is connected with a transverse guide block, and the transverse guide block is inserted into the transverse groove.

6. A heating mechanism for machining of a magnetic rotor in a fluid pump according to claim 5, wherein: the transverse moving block is provided with a threaded hole matched with the transverse rod, one end of the transverse rod is provided with an external thread, and the transverse rod is in threaded connection with the transverse moving block.

7. A heating mechanism for machining of a magnetic rotor in a fluid pump according to claim 6, wherein: the transverse rods are respectively connected with fixing nuts on two sides of the transverse moving block.

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