阅读说明：本技术 爪极式电机机壳铆压机 (Claw pole type motor casing riveting press ) 是由 胥新华 朱贺 朱吴俊 于 2020-06-09 设计创作，主要内容包括：本申请涉及一种爪极式电机机壳铆压机,包括电气箱、与所述电器相连接的工作台、设置在所述工作台上的机架、及设置在所述机架上且与所述电气箱信号连接的铆压机构和送料机构,送料机构包括用以将爪极式电机内部组件输送至铆压位置的第一送料组件、及用以将爪极式电机机壳输送至铆压位置的第二送料组件,所述铆压机构用以将第二目标组件与第一目标组件铆压以成型爪极式电机。通过设置有第一送料组件和第二送料组件,第一送料组件用以先将爪极式电机内部组件输送至目标位置,第二送料组件用以将爪极式电机机壳输送至目标位置,然后铆压机构下压将爪极式电机机壳与爪极式电机内部组件铆压,方便快捷,提高了生产效率。(The utility model relates to a claw utmost point formula motor casing riveting machine, including the electric box, with workstation, setting that electrical apparatus is connected are in frame on the workstation and setting are in the frame and with riveting mechanism and feeding mechanism of electric box signal connection, feeding mechanism is including being used for carrying claw utmost point formula motor inner assembly to the first pay-off subassembly of riveting position, and being used for carrying claw utmost point formula motor casing to the second pay-off subassembly of riveting position, riveting mechanism is used for riveting second target subassembly and first target subassembly with shaping claw utmost point formula motor. Through being provided with first pay-off subassembly and second pay-off subassembly, first pay-off subassembly is used for carrying claw utmost point formula motor inner assembly to the target location earlier, and second pay-off subassembly is used for carrying claw utmost point formula motor casing to the target location, then riveting mechanism pushes down claw utmost point formula motor casing and claw utmost point formula motor inner assembly riveting, and convenient and fast has improved production efficiency.)

1. The riveting machine for the shell of the claw-pole motor is characterized by comprising an electric box, a workbench connected with the electric appliance, a rack arranged on the workbench, and a riveting mechanism and a feeding mechanism which are arranged on the rack and connected with the electric box through signals, wherein the feeding mechanism comprises a first feeding component used for conveying internal components of the claw-pole motor to a riveting position and a second feeding component used for conveying the shell of the claw-pole motor to the riveting position, and the riveting mechanism is used for riveting a second target component and the first target component to form the claw-pole motor.

2. The machine shell riveting press of claw-pole motor of claim 1, wherein the riveting mechanism comprises a riveting cylinder fixedly arranged on the frame and a riveting block connected with the riveting cylinder, and the riveting cylinder is used for driving the riveting block to move towards a target position.

3. The machine shell riveting press of claw-pole motor according to claim 2, wherein the riveting mechanism further comprises a connecting piece for connecting the riveting cylinder and the riveting block, the machine frame is provided with a slide rail, and the connecting piece is provided with a slide block connected with the slide rail in a sliding manner.

4. The claw-pole motor shell riveting press of claim 3, wherein the first feeding assembly comprises a feeding slide rail, a feeding slide block arranged on the feeding slide rail, and a first lead screw for driving the feeding slide block to slide relative to the feeding slide rail; and the feeding sliding block is connected with an internal component of the claw-pole motor.

5. The claw-pole motor housing riveter of claim 4 further comprising a docking station disposed on the table and docking with the second feed assembly, wherein the docking station has a through hole, and the first lead screw is configured to drive the feed slide to a position below the through hole.

6. The claw-pole motor housing riveter of claim 5 wherein the second feed assembly comprises a discharge table abutting the docking station and a second lead screw disposed on one side of the discharge table, the discharge table being configured to receive the claw-pole motor housing, the second lead screw being configured to drive the motor housing to move onto the docking station.

7. The claw-pole machine shell riveter of claim 6, wherein the height of the discharge table is equal to the height of the docking table.

8. The claw-pole machine shell riveter of claim 6 wherein one side of the docking station is provided with a stop.

Technical Field

The invention relates to a claw-pole motor shell riveting press machine, and belongs to the technical field of automatic processing equipment.

Background

At present, claw-pole permanent magnet synchronous motors are applied in various fields, and are particularly widely applied to various household appliances, such as air conditioner rotary blades, fan rotary heads and other equipment. The common claw-pole permanent magnet synchronous motor structure generally comprises a cup-shaped shell, the cup-shaped shell and other components are generally fastened through bolt and nut matching when being installed, and a worker generally needs one hand to fix a bolt and the other hand to tighten the nut through other tools when screwing the nut, so that the nut screwing operation is complicated.

Disclosure of Invention

The invention aims to provide a riveting press for a claw-pole motor shell, which can be used for quickly riveting and installing the claw-pole motor shell and internal components thereof, and is convenient and quick.

In order to achieve the purpose, the invention provides the following technical scheme: a riveting machine for a claw-pole motor shell comprises an electrical cabinet, a workbench connected with an electrical appliance, a rack arranged on the workbench, and a riveting mechanism and a feeding mechanism which are arranged on the rack and connected with the electrical cabinet through signals, wherein the feeding mechanism comprises a first feeding component used for conveying internal components of the claw-pole motor to a riveting position and a second feeding component used for conveying the claw-pole motor shell to the riveting position, and the riveting mechanism is used for riveting a second target component and the first target component to form the claw-pole motor.

Furthermore, the riveting mechanism comprises a riveting cylinder fixedly arranged on the rack and a riveting block connected with the riveting cylinder, and the riveting cylinder is used for driving the riveting block to move towards a target position.

Furthermore, the riveting mechanism further comprises a connecting piece used for connecting the riveting cylinder and the riveting block, a sliding rail is arranged on the rack, and the connecting piece is provided with a sliding block in sliding connection with the sliding rail.

Furthermore, the first feeding assembly comprises a feeding slide rail, a feeding slide block arranged on the feeding slide rail and a first lead screw used for driving the feeding slide block to slide relative to the feeding slide rail; and the feeding sliding block is connected with an internal component of the claw-pole motor.

Furthermore, the claw-pole motor shell riveting machine further comprises a butt joint table which is arranged on the workbench and is in butt joint with the second feeding assembly, a through hole is formed in the butt joint table, and the first lead screw is used for driving the feeding sliding block to the position below the through hole.

Furthermore, the second feeding assembly comprises a discharging platform in butt joint with the butt joint platform and a second lead screw arranged on one side of the discharging platform, the discharging platform is used for placing a claw-pole motor shell, and the second lead screw is used for driving the motor shell to move to the butt joint platform.

Further, the height of the discharging platform is equal to that of the butt joint platform.

Furthermore, one side of the butt joint platform is provided with a stop piece.

The invention has the beneficial effects that: through being provided with first pay-off subassembly and second pay-off subassembly, first pay-off subassembly is used for carrying claw utmost point formula motor inner assembly to the target location earlier, and second pay-off subassembly is used for carrying claw utmost point formula motor casing to the target location, then riveting mechanism pushes down claw utmost point formula motor casing and claw utmost point formula motor inner assembly riveting, and convenient and fast has improved production efficiency.

The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical solutions of the present invention more clearly understood and to implement them in accordance with the contents of the description, the following detailed description is given with reference to the preferred embodiments of the present invention and the accompanying drawings.

Drawings

Fig. 1 is a schematic structural diagram of a claw-pole motor casing riveting press machine of the invention.

Fig. 2 is another schematic structural diagram of the claw-pole motor casing riveting press of the present invention.

Fig. 3 is a schematic view of a part of the structure of the riveting press for the claw-pole motor casing according to the present invention.

Fig. 4 is another schematic structural diagram of the claw-pole motor casing riveting press of the present invention.

Detailed Description

The following detailed description of embodiments of the present invention is provided in connection with the accompanying drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

Referring to fig. 1 and 2, a riveting machine for a housing of a claw-pole motor in a preferred embodiment of the invention includes an electrical box 1, a workbench 2 connected to the electrical appliance, a frame 3 disposed on the workbench 2, and a riveting mechanism 4 and a feeding mechanism 5 disposed on the frame 3 and connected to the electrical box 1 by signals, wherein the feeding mechanism 5 includes a first feeding component 51 for conveying internal components of the claw-pole motor to a riveting position, and a second feeding component 52 for conveying the housing of the claw-pole motor to the riveting position. After the first feeding assembly 51 is used to transport the internal components of the claw pole type motor to the target position, the second feeding assembly 52 transports the casing of the claw pole type motor to the target position, and then the riveting mechanism 4 is used to rivet and press the second target component and the first target component to form the claw pole type motor. Or, the first feeding assembly 51 is used to transport the internal components of the claw pole type motor to the first target position, the second feeding assembly 52 is used to transport the casing of the claw pole type motor to the second target position, the second target position is right above the first target position in the height direction of the riveting machine of the casing of the claw pole type motor, and then the riveting mechanism 4 presses down to rivet and mold the casing of the claw pole type motor and the internal components of the claw pole type motor, which is not specifically limited herein, depending on the actual situation. In the present embodiment, the feeding manner of the first feeding assembly 51 and the second feeding assembly 52 is the latter.

The riveting mechanism 4 includes a riveting cylinder 41 fixedly disposed on the frame 3 and a riveting block 42 connected to the riveting cylinder 41, and the riveting cylinder 41 is configured to drive the riveting block 42 to move toward a target position. In the height direction of the claw-pole motor casing riveting machine, the riveting cylinder 41 is fixedly arranged at the uppermost part of the rack 3. In order to enable the riveting cylinder 41 to drive the riveting block 42 to operate better, the riveting mechanism 4 further includes a connecting member 43 for connecting the riveting cylinder 41 and the riveting block 42, the rack 3 is provided with a slide rail 31, and the connecting member 43 has a slide block slidably connected with the slide rail. In this embodiment, two slide rails 31 are provided, and two slide rails 31 are provided on one side of the frame 3. Correspondingly, the number of the sliding blocks is two, and the two sliding blocks are connected with the connecting piece 43. The connecting member 43 and the slider are integrally formed, or are separately formed and then fixedly connected by welding, bonding, or the like, which is not limited herein and is determined according to actual conditions. The number of the slide rails 31 and the slide blocks is not particularly limited, and is determined according to actual conditions.

In this embodiment, the first feeding assembly 51 is disposed below the second feeding assembly 52, the claw-pole motor casing riveting machine further includes a docking station 6 disposed on the workbench 2 and in butt joint with the second feeding assembly 52, a through hole is disposed on the docking station 6, the through hole is a second target position, the first target position is directly below the through hole, and after the claw-pole motor casing is conveyed to the second target position by the second feeding assembly 52, the riveting mechanism 4 presses down to rivet the claw-pole motor casing passing through the through hole and the claw-pole motor internal assembly. In this embodiment, the size of the through hole is close to the size of the claw pole type motor casing, so that when the claw pole type motor casing is located at the second target position, the claw pole type motor casing does not directly drop due to the fact that the through hole is too large, and does not fall due to the fact that the through hole is too small, and accordingly, the diameter of the riveting block 42 is smaller than or equal to the diameter of the through hole.

Referring to fig. 3, the first feeding assembly 51 includes a feeding slide rail 512, a feeding slide block 513 disposed on the feeding slide rail 512, and a first lead screw 511 for driving the feeding slide block 513 to slide relative to the feeding slide rail 512; and the feeding sliding block 513 is connected with an internal component of the claw-pole motor. In this embodiment, one end of the feeding slide rail 512 extends to the lower side of the through hole. The claw-pole type motor internal component is placed on the feeding sliding block 513, and the first lead screw 511 drives the feeding sliding rail 512 to move to the position below the through hole so that the claw-pole type motor internal component can displace to a first target position.

The second feeding assembly 52 includes a material discharging platform 521 butted with the docking station 6 and a second lead screw 522 disposed on one side of the material discharging platform 521, the material discharging platform 521 is used for placing a claw-pole motor casing, and the second lead screw 522 is used for driving the motor casing to move onto the docking station 6. In this embodiment, the height of the discharging platform 521 is equal to the height of the docking platform 6, so that the claw pole type motor casing on the discharging platform 521 can smoothly move to the docking platform 6. However, in other embodiments, the height of the material placing table 521 may be greater than or less than the height of the docking table 6, and is not limited herein. In order to prevent the claw-pole motor casing from sliding out of the second target position, a stop member is arranged on one side of the docking station 6.

The riveting press for the claw-pole motor shell further comprises a screw base 7 used for placing the two second screws 522 and a driving slide rail in sliding fit with the screw base 7, and the screw base 7 is provided with a driving slide block in sliding fit with the driving slide rail. One of the second lead screws 522 is fixedly disposed on the frame 3 to drive the base to move on the driving slide rail, and the other second lead screw 522 is used to drive the claw-pole motor casing. That is, one of the second lead screws 522 is used to adjust the position of the other second lead screw 522 relative to the claw-pole motor casing, which is convenient and fast.

Referring to fig. 4, the bottom of the electrical box 1 is further provided with a height adjustment mechanism 9 and a roller mechanism 8 for adjusting the height, the height adjustment mechanism 9 is adjusted to be high when the claw-pole motor housing riveting machine does not need to be moved so that the roller mechanism 8 does not contact the ground, and the roller mechanism 8 contacts the ground when the claw-pole motor housing riveting machine needs to be moved so as to move the whole device. In this embodiment, the height adjustment mechanism 9 is a conventional structure, that is, the two adjustment members can adjust the height of one of the two adjustment members compared with the other adjustment member through screws, which is not described herein. The roller mechanism 8 comprises four rollers, so that the claw-pole motor shell riveting machine can move stably.

In summary, the following steps: through being provided with first pay-off subassembly 51 and second pay-off subassembly 52, first pay-off subassembly 51 is used for carrying claw utmost point formula motor inner assembly to the target location earlier, and second pay-off subassembly 52 is used for carrying claw utmost point formula motor casing to the target location, then riveting mechanism 4 pushes down claw utmost point formula motor casing and claw utmost point formula motor inner assembly riveting, and convenient and fast has improved production efficiency.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.