CN221428738U - Multilayer stator core lamination stamping equipment - Google Patents

Abstract

The utility model provides a multilayer stator core stacking stamping device, and belongs to the technical field of stator core production. This kind of multilayer stator core piles up punching press equipment, including the equipment body, feeding mechanism and extracting mechanism, the equipment body includes the base, the workstation is installed at the top of base, core department inlays in the top of workstation is equipped with a pile-up section of thick bamboo, pile-up section of thick bamboo's inside activity is inserted and is equipped with the clamp plate, there is the punching press case at the top of workstation through a plurality of fastening bolt threaded connection, feeding mechanism includes mounting bracket and ejection of compact section of thick bamboo, the flitch is installed to the opposite side of mounting bracket, the inside activity of ejection of compact section of thick bamboo is inserted and is equipped with the jacking plate, a plurality of stator cores have been set gradually from bottom to top in the top of jacking plate, extracting mechanism includes a pair of first mounting panel, a pair of second mounting panel and a pair of slider, automatic telescopic link is all installed to one side of a pair of slider, the material frame is all installed to automatic telescopic link's one end, can effectively be carried out the material respectively before the punching press to stator core piles up, have higher practical value.

Description

Multilayer stator core lamination stamping equipment

Technical Field

The utility model relates to the technical field of stator core production, in particular to a multi-layer stator core stacking stamping device.

Background

The stator core is an important component of the magnetic circuit of the motor, and forms a complete magnetic circuit of the motor together with the rotor core and the air gap between the stator and the rotor. In an asynchronous motor, the magnetic flux in the stator core is alternating, thus generating core losses. The core loss includes two parts: hysteresis loss and eddy current loss, and lamination stamping equipment is needed in the current stator core production process.

When current lamination stamping equipment is to stator core lamination punching press, adopt the mode of manual feeding to place stator core in the position of lamination punching press generally, increase labour also can reduce production efficiency, current lamination stamping equipment is after accomplishing the lamination punching press of multilayer stator core simultaneously, needs the user to take out the stator core that the punching press was accomplished in lamination punching press position department by people's manual work, and it is comparatively inconvenient to get the material to there is certain potential safety hazard problem.

Disclosure of utility model

In order to solve the technical problems, the embodiment of the utility model provides a multi-layer stator core stacking stamping device, which is realized by the following technical scheme:

The utility model provides a multilayer stator core piles up equipment of assembling, includes equipment body, feeding mechanism and feeding mechanism, the equipment body includes the base, the workstation is installed at the top of base, core department inlays in the top of workstation is equipped with a pile-up section of thick bamboo, pile-up section of thick bamboo's inside activity is inserted and is equipped with the clamp plate, there is the punching press case at the top of workstation through a plurality of fastening bolt threaded connection, the second pneumatic cylinder is installed at the top of punching press case, the output of second pneumatic cylinder runs through the punching press case and extends to inside to install the briquetting, feeding mechanism includes mounting bracket and ejection of compact section of thick bamboo, the mounting bracket is arranged in top one side of workstation, just the cylinder is installed to outside one side of mounting bracket, the push away the flitch is installed to the opposite side of mounting bracket, ejection of compact section of thick bamboo sets up in the top of workstation is close to push away flitch department, the inside activity of ejection of compact section of thick bamboo is inserted and is equipped with the jacking plate, the top of jacking plate has set gradually from bottom to top a plurality of stator core, feeding mechanism includes a pair of first mounting plate, a pair of second mounting plate and a pair of slider, a pair of first mounting plate and a pair of automatic mounting plate and a pair of flexible pole all are close to one side of the automatic mounting plate and are all installed in the ram one side of ram.

Further, the output end of the cylinder penetrates through the mounting frame and is connected with one side of the pushing plate, and the pushing plate is matched with the mounting frame.

The beneficial effect of adopting above-mentioned further scheme is, through setting up the cylinder, when its during operation, can promote to push away the flitch and remove forward, pushes away the material to stator core.

Further, a first hydraulic cylinder is arranged at the bottom end of the base close to the discharging cylinder, the output end of the first hydraulic cylinder is connected with the bottom end of the jacking plate, and the discharging cylinder and the stacking cylinder are located at the same horizontal position.

The beneficial effect of adopting above-mentioned further scheme is, through setting up first pneumatic cylinder, when its during operation, can promote the jacking board and upwards move.

Further, a pair of lead screw and slide bar are installed between the first mounting plate and the second mounting plate, a pair of lead screw and slide bar penetrate through a pair of sliding blocks respectively, a pair of sliding blocks are in threaded connection with the pair of lead screw, and the pair of sliding blocks are in sliding connection with the pair of slide bars.

The adoption of the further scheme has the beneficial effects that the sliding blocks are arranged, the sliding blocks are in threaded connection with the screw rod, and the sliding blocks are in sliding connection with the sliding rods, so that the sliding blocks can form linear motion under the rotation action of the screw rod and the sliding action of the sliding blocks when the screw rod rotates.

Further, one end of the pair of screw rods penetrates through one side of the first mounting plate, one side of the second mounting plate and one side of the workbench to extend to the inside of the workbench, belt pulleys are sleeved on the screw rods, and the pair of belt pulleys are driven by a belt.

The beneficial effect of adopting above-mentioned further scheme is, through setting up the belt pulley with the one end of a pair of lead screw to through belt transmission between a pair of belt pulley, when one of them lead screw rotated, can transmit the rotation force of one belt pulley to another belt pulley under the transmission effect of belt, thereby make another lead screw rotate.

Further, the workbench is L-shaped, a motor is arranged on one side of the workbench, and the output end of the motor penetrates through one side of the workbench and is in transmission connection with one end of one screw rod.

The beneficial effect of adopting above-mentioned further scheme is, through setting up the motor, when its during operation, conveniently drives one of them lead screw and rotates.

Further, a pair of hydraulic rods are installed at the bottom end of the base close to the stacking barrel, and the output ends of the pair of hydraulic rods extend to the outside through the top of the base and are connected with the bottom end of the pressing plate.

Adopt the beneficial effect of above-mentioned further scheme, through setting up a pair of hydraulic stem to the output and the clamp plate bottom of a pair of hydraulic stem are connected, can make the clamp plate top originally the stator core that punches well move down, and the convenience is located the top of the stator core that punches well under feeding mechanism's effect.

Further, a pair of get material frame's inside and a plurality of stator core looks adaptation, and a pair of get material frame's inside all is provided with the protection pad, the protection pad all belongs to the rubber material.

Adopt the beneficial effect of above-mentioned further scheme, through setting up a pair of material frame of getting, can arrange in order the stator core of stacking, avoid piling up the in-process and appear crookedly, a pair of material frame of getting also can pay-off the stator core after the lamination punching press equally, through setting up the protection pad, protect stator core's periphery.

Further, the pressing block and the pressing plate are positioned at the same vertical position.

The stator core pressing device has the beneficial effects that the pressing block and the pressing plate are arranged at the same position, so that the pressing block can conveniently press the stator core on the pressing plate.

The beneficial effects of the utility model are as follows: the multi-layer stator core stacking stamping equipment obtained by the design is convenient for stacking the stator cores by arranging the stacking cylinder, the jacking plate at the output end of the first hydraulic cylinder is moved upwards when the multi-layer stator core stacking stamping equipment works by arranging the first hydraulic cylinder, one stator core in the discharging cylinder is completely exposed from the discharging cylinder, the stator core after discharging is conveniently pushed to the pressing plate by arranging the cylinder and the pushing plate, the stator core is positioned at the center core of the workbench and is positioned at the same vertical position with the pressing block, the pair of automatic telescopic rods are conveniently pushed to the pressing plate by arranging the pair of material taking frames, the periphery of the stacked stator core is conveniently tidied, the stator core is conveniently stamped by arranging the second hydraulic cylinder and the pressing block, after the stamping is finished, the stator core is conveniently stamped by arranging the pair of hydraulic rods, the pressing plate drives the stamped stator core to move downwards in the stacking cylinder by a certain distance, namely a distance equivalent to the height of the stator core, the jacking plate is pushed by the first hydraulic cylinder to enable the stator core to discharge, the cylinder pushes the pushing plate to push and convey the stator core to the stacking cylinder, the non-stamped stator core and the stamped stator core are positioned at the same vertical position, stamping is carried out, the steps of discharging, feeding and finishing are repeated for a plurality of times, the multi-layer stator core stacking stamping work is completed, the multi-layer stator core after stacking stamping is clamped by a pair of automatic telescopic rods for convenient subsequent conveying, one screw rod is rotated by a motor, so that the pair of screw rods synchronously rotate under the action of a belt pulley and a belt, a pair of sliding blocks move away from the stamping position under the action of screw rod rotation and sliding of a sliding rod, the multi-layer iron core material obtained after repeated stacking stamping is obtained.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present utility model, the drawings that are needed in the embodiments will be briefly described below, it being understood that the following drawings only illustrate some examples of the present utility model and therefore should not be considered as limiting the scope, and other related drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic perspective view of a multi-layer stator core stacking and stamping device according to the present utility model;

Fig. 2 is a schematic perspective view of a pushing plate of a multi-layer stator core stacking and stamping device according to the present utility model;

Fig. 3 is a schematic perspective view of a material taking mechanism of a multi-layer stator core stacking and stamping device according to the present utility model;

Fig. 4 is a schematic front section view of a multi-layer stator core stacking and stamping device provided by the utility model;

fig. 5 is an enlarged schematic view of the structure a in fig. 3 according to the present utility model.

In the figure: 100. an equipment body; 1001. a base; 1002. a first hydraulic cylinder; 1003. a hydraulic rod; 1004. a work table; 1005. a stacking barrel; 1006. a pressing plate; 1007. a motor; 1008. punching a box; 1009. a second hydraulic cylinder; 1010. briquetting; 200. a feeding mechanism; 2001. a mounting frame; 2002. a cylinder; 2003. a pushing plate; 2004. a discharging cylinder; 2005. a jacking plate; 2006. a stator core; 300. a material taking mechanism; 3001. a first mounting plate; 3002. a second mounting plate; 3003. a slide bar; 3004. a screw rod; 3005. a belt pulley; 3006. a belt; 3007. a slide block; 3008. an automatic telescopic rod; 3009. and a material taking frame.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model, and it is apparent that the described embodiments are some embodiments of the present utility model, but not all embodiments. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model.

Thus, the following detailed description of the embodiments of the utility model, as presented in the figures, is not intended to limit the scope of the utility model, as claimed, but is merely representative of selected embodiments of the utility model. All other embodiments, based on the embodiments of the utility model, which are apparent to those of ordinary skill in the art without inventive faculty, are intended to be within the scope of the utility model.

The embodiment I of the utility model relates to a multi-layer stator core stacking stamping device

The utility model provides the following technical scheme: as shown in fig. 1 to 5, a multi-layer stator core stacking and stamping device, which comprises a device body 100, a feeding mechanism 200 and a material taking mechanism 300, wherein the device body 100 comprises a base 1001, a workbench 1004 is installed at the top of the base 1001, a stacking barrel 1005 is embedded in the middle core of the top of the workbench 1004, a pressing plate 1006 is movably inserted in the stacking barrel 1005, a stamping box 1008 is connected to the top of the workbench 1004 through a plurality of fastening bolts, a second hydraulic cylinder 1009 is installed at the top of the stamping box 1008, the output end of the second hydraulic cylinder 1009 extends into the interior through the stamping box 1008 and is provided with a pressing block 1010, the feeding mechanism 200 comprises a mounting bracket 2001 and a discharging barrel 2004, the mounting bracket 2001 is arranged at one side of the top of the workbench 1004, a cylinder 2002 is installed at one side of the exterior of the mounting bracket 2001, a pushing plate 2003 is installed at the other side of the mounting bracket 2001, the discharging barrel 2004 is arranged at the top of the workbench 1004 near the pushing plate 2003, a jacking plate 2005 is movably inserted in the discharging barrel 2004, a plurality of stator cores 2006 are sequentially arranged at the top of the jacking plate 2005 from bottom to top, the material taking mechanism 300 comprises a pair of first mounting plates 3001, a pair of second mounting plates 3002 and a pair of sliding blocks 3007, the pair of first mounting plates 3001 and the pair of second mounting plates 3002 are respectively arranged at the top of the workbench 1004 and close to two sides of the punching box 1008, an automatic telescopic rod 3008 is respectively arranged at one side of the pair of sliding blocks 3007, a material taking frame 3009 is respectively arranged at one end of the automatic telescopic rod 3008, the stator cores 2006 are conveniently supported by the pressing plate 1006 and the jacking plate 2005, the stator cores 2006 are conveniently punched by the second hydraulic cylinders 1009 and the pressing blocks 1010, the stator cores 2006 are conveniently pushed to the pressing plate 1006 by the cylinder 2002 and the pushing plate 2003, the pair of material taking frames 3009 are conveniently pushed to the pressing plate 1006 by the pair of automatic telescopic rods 3008, the stacked stator core 2006 is convenient to carry out peripheral arrangement and the stacked and punched multilayer stator core 2006 is convenient to clamp and carry subsequently.

The utility model relates to a second embodiment of a multi-layer stator core stacking stamping device

Referring to fig. 1-5, the output end of the cylinder 2002 penetrates through the mounting frame 2001 and is connected with one side of the pushing plate 2003, the pushing plate 2003 is matched with the mounting frame 2001, a first hydraulic cylinder 1002 is installed at the inner bottom end of the base 1001 near the discharging cylinder 2004, the output end of the first hydraulic cylinder 1002 is connected with the bottom end of the lifting plate 2005, the discharging cylinder 2004 and the stacking cylinder 1005 are located at the same horizontal position, a screw rod 3004 and a slide rod 3003 are installed between the pair of first mounting plates 3001 and the pair of second mounting plates 3002, the pair of screw rods 3004 and the slide rod 3003 penetrate through a pair of sliding blocks 3007 respectively, the pair of sliding blocks 3007 are in threaded connection with the pair of screw rods 3004, one end of each of the pair of screw rods 3004 penetrates through one of the first mounting plates 3001, the second mounting plates 3002 and one side of the working table 1004, and is sleeved with a belt 3005, the working table 1004 is in an L shape, a motor 1007 is installed at one side of the working table 1004, when the motor 1007 is installed, the output end of the motor 1007 is installed and the pair of the sliding blocks 3004 penetrates through the pair of screw rods 3004, the sliding blocks 3004 are in sliding connection with the sliding blocks 3004, and the sliding blocks are arranged to slide-move up through the sliding blocks 3004, and the sliding blocks are arranged in sliding connection with the sliding blocks 3004, and the sliding blocks are arranged to slide-up the sliding blocks are arranged, and slide-down the sliding blocks are arranged on the sliding blocks and slide blocks are arranged by the sliding blocks 3004 and slide blocks are arranged to slide the sliding blocks and slide the one side blocks and the side blocks are arranged.

The utility model relates to an embodiment III of a multi-layer stator core stacking stamping device

Referring to fig. 1-5, a pair of hydraulic rods 1003 are installed at the bottom end of the base 1001 near the stacking cylinder 1005, the output ends of the pair of hydraulic rods 1003 extend to the outside through the top of the base 1001 and are connected with the bottom ends of the pressing plates 1006, the interiors of the pair of material taking frames 3009 are matched with the stator cores 2006, the interiors of the pair of material taking frames 3009 are provided with protection pads, the protection pads are all made of rubber materials, the pressing blocks 1010 and the pressing plates 1006 are located at the same vertical position, and when the pair of hydraulic rods 1003 drive the pressing plates 1006 to move downwards, the stator cores 2006 are stacked conveniently, and the peripheries of the stator cores 2006 are protected by the protection pads.

Specifically, the working principle of the multi-layer stator core stacking stamping equipment is as follows: when in use, a plurality of stator cores 2006 are stacked at the top of the jacking plate 2005 of the discharging cylinder 2004, then the first hydraulic cylinder 1002 is started to enable the jacking plate 2005 to move upwards, one stator core 2006 in the discharging cylinder 2004 is completely exposed from the discharging cylinder 2004, the pushing plate 2003 is pushed by the starting cylinder 2002, further the forward conveying of the stator cores 2006 at the front side of the pushing plate 2003 is realized, the stator cores 2006 are pushed to the pressing plate 1006, a pair of automatic telescopic rods 3008 are started to enable the distance of a pair of material taking frames 3009 to be pulled up, the positions of the stator cores 2006 at the pressing plate 1006 are sorted, the pressing block 1010 is pressed down to punch the stator cores 2006 by starting the second hydraulic cylinder 1009, after punching is completed, a pair of hydraulic rods 1003 are started to enable the pressing plate 1006 to drive the punched stator cores 2006 to move downwards in the stacking cylinder 1005, the first hydraulic cylinder 1002 is continued to push the jacking plate 2006 to realize the next stator core 2006, then the air cylinder 2002 pushes the pushing plate 2003 to push and convey the next stator core 2006, the non-punched stator core 2006 is located at the position of the already punched stator core 2006, a pair of material taking frames 3009 are pushed by a pair of automatic telescopic rods 3008 to carry out peripheral arrangement on the non-punched stator core 2006 and the already punched stator core 2006, the uniformity is ensured, the pressing block 1010 is continuously pressed down by a second hydraulic cylinder 1009 to punch the stator core 2006, the steps are repeated for a plurality of times, the stacked punching of the multi-layer stator core 2006 is realized, the multi-layer stator core 2006 is clamped by the pair of material taking frames 3009 by the pair of automatic telescopic rods 3008, then a motor 1007 is started, a pair of sliding blocks 3007 are moved to one side of a workbench 1004 under the action of rotation of a screw 3004 and sliding of a sliding rod 3003, a user can take materials from the multi-layer stator core 2006 on one side of the workbench 1004, avoiding the safety problem.

It should be noted that, in the multi-layer stator core stacking stamping device, specific model specifications of the first hydraulic cylinder 1002, the hydraulic rod 1003, the motor 1007, the second hydraulic cylinder 1009, the cylinder 2002 and the automatic telescopic rod 3008 need to be determined by selecting a model according to actual specifications of the device, and a specific model selection calculation method adopts the prior art in the art, so that detailed description is omitted.

The power supply and the principle of the multi-layered stator core stacking stamping apparatus, the first hydraulic cylinder 1002, the hydraulic rod 1003, the motor 1007, the second hydraulic cylinder 1009, the cylinder 2002, and the automatic telescopic rod 3008 will be apparent to those skilled in the art, and will not be described in detail herein.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, and various modifications and variations may be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (9)

1. The utility model provides a multilayer stator core piles up punching press equipment, a serial communication port, including equipment body (100), feeding mechanism (200) and extracting mechanism (300), equipment body (100) include base (1001), workstation (1004) are installed at the top of base (1001), inlay in the top middle core department of workstation (1004) has folded a section of thick bamboo (1005), the inside activity of folding section of thick bamboo (1005) is inserted and is equipped with clamp plate (1006), there is punching press case (1008) at the top of workstation (1004) through a plurality of fastening bolt threaded connection, second pneumatic cylinder (1009) are installed at the top of punching press case (1008), the output of second pneumatic cylinder (1009) runs through punching press case (1008) and extends to inside to install briquetting (1010), feeding mechanism (200) include mounting bracket (2001) and ejection of compact section of thick bamboo (2004), mounting bracket (2001) are set up in top one side of workstation (1004), and outside one side of mounting bracket (2001) installs cylinder (2002), push away flitch (2003) are installed to the opposite side of mounting bracket (2001), push away flitch (2004) are located inside (2004) of pushing away movable push away section of thick bamboo (2004), the top of jacking board (2005) has set gradually a plurality of stator core (2006) from bottom to top, extracting mechanism (300) are including a pair of first mounting panel (3001), a pair of second mounting panel (3002) and a pair of slider (3007), a pair of first mounting panel (3001) and a pair of second mounting panel (3002) all set up in workstation (1004) top and are close to punching press case (1008) both sides, a pair of automatic telescopic link (3008) are all installed to one side of slider (3007), extracting frame (3009) are all installed to one end of automatic telescopic link (3008).

2. The multi-layered stator core stacking stamping apparatus of claim 1, wherein the output end of the cylinder (2002) penetrates the mounting frame (2001) and is connected to one side of a pushing plate (2003), and the pushing plate (2003) is matched with the mounting frame (2001).

3. The multi-layer stator core stacking stamping device according to claim 1, wherein a first hydraulic cylinder (1002) is installed at the inner bottom end of the base (1001) close to the discharging cylinder (2004), the output end of the first hydraulic cylinder 1 (002) is connected with the bottom end of the jacking plate (2005), and the discharging cylinder (2004) and the stacking cylinder (1005) are located at the same horizontal position.

4. The multi-layered stator core stacking stamping apparatus of claim 1, wherein a screw rod (3004) and a slide rod (3003) are mounted between the pair of first mounting plates (3001) and the pair of second mounting plates (3002), the pair of screw rods (3004) and the slide rod (3003) respectively penetrate a pair of slide blocks (3007), the pair of slide blocks (3007) are in threaded connection with the pair of screw rods (3004), and the pair of slide blocks (3007) are in sliding connection with the pair of slide rods (3003).

5. The multi-layered stator core stacking stamping apparatus as claimed in claim 4, wherein one end of each of the pair of lead screws (3004) extends through one side of one of the first mounting plate (3001), the second mounting plate (3002) and the table (1004) to the inside of the table (1004), and is each sleeved with a pulley (3005), and a transmission is provided between the pair of pulleys (3005) through a belt (3006).

6. The multi-layer stator core stacking stamping device according to claim 1, wherein the workbench (1004) is in an L shape, a motor (1007) is installed on one side of the workbench (1004), and an output end of the motor (1007) penetrates through one side of the workbench (1004) and is in transmission connection with one end of one screw rod (3004).

7. The multi-layer stator core stacking stamping apparatus of claim 1, wherein a pair of hydraulic rods (1003) are mounted at the inner bottom end of the base (1001) near the stacking cylinder (1005), and the output ends of the pair of hydraulic rods (1003) extend to the outside through the top of the base (1001) and are connected to the bottom end of the pressing plate (1006).

8. The multi-layer stator core stacking stamping device according to claim 1, wherein the interiors of the material taking frames (3009) are matched with the stator cores (2006), and the interiors of the material taking frames (3009) are provided with protection pads, and the protection pads are made of rubber materials.

9. The multi-layered stator core lamination stamping apparatus of claim 1, wherein the press block (1010) is located at the same vertical position as the press plate (1006).