CN219293206U - Special-shaped shell loading attachment and dress box test machine - Google Patents

Abstract

The utility model discloses a special-shaped shell feeding device and discloses a boxing testing machine with the special-shaped shell feeding device, wherein the special-shaped shell feeding device comprises a vibration disc, a material channel and a material stirring assembly which are sequentially arranged, and is characterized in that: the material path is provided with a first limit groove, the first limit groove is used for accommodating the first rib of the bottom shell, the material path is further provided with a direction detection assembly and a direction correction assembly, the direction detection assembly comprises a detection needle, a first power piece and a sensor, the detection needle is used for detecting the directions of the first inner step and the first outer step of the bottom shell, the sensor is electrically connected with the detection needle, the direction correction assembly comprises a swivel base and a first motor, the first motor is electrically connected with the sensor, the sensor is used for receiving a detection signal of the detection needle and controlling the first motor to drive the swivel base to correct the direction of the bottom shell, and the special-shaped shell feeding device can automatically correct the placement direction of the bottom shell, so that the bottom shell is mutually aligned with the top shell during press fitting, and efficiency is improved.

Description

Special-shaped shell loading attachment and dress box test machine

Technical Field

The utility model relates to the technical field of magnetic ring production equipment, in particular to a special-shaped shell feeding device and a boxing testing machine.

Background

The magnetic ring is a ring-shaped magnetizer.

Structurally, the magnetic ring comprises a shell and a magnetic core arranged in the shell, the shell and the magnetic core are annular, and as shown in fig. 1, the shell comprises a bottom shell 100 and a top shell 110.

In order to facilitate the fitting of the bottom case 100 and the top case 110, the fitting of the bottom case 100 and the top case 110 may be configured in a shaped complementary shape, specifically, a first inner step 120 is disposed on an inner side of one side of an annular edge of the bottom case 100 in a radial direction, a first outer step 130 is disposed on an outer side of the other side of the annular edge of the bottom case 100 in the radial direction, a second inner step 140 is disposed on an inner side of one side of the annular edge of the top case 110 in the radial direction, a second outer step 150 is disposed on an outer side of the other side of the annular edge of the top case 110 in the radial direction, the first inner step 120 is fitted with the second outer step 150, and the first outer step 130 is fitted with the second inner step 140.

In addition, a side of the bottom case 100 facing away from the annular rim has a first rib 160 disposed along a radial direction of the bottom case 100, the first inner step 120 and the first outer step 130 are disposed on two sides of the first rib 160, a side of the top case 110 facing away from the annular rim has a second rib 170 disposed along a radial direction of the top case 110, and the second inner step 140 and the second outer step 150 are disposed on two sides of the second rib 170.

The cartoning machine is a device that assembles the bottom case 100, the top case 110, and the magnetic core into a magnetic ring, and tests the performance of the magnetic ring.

Structurally, the boxing testing machine comprises two feeding devices, an upper magnetic core device, a rotary table, a press-fitting device and a testing and sorting device, wherein the two feeding devices are respectively used for arranging and conveying the bottom shell 100 and the top shell 110 to the rotary table, the upper magnetic core device is used for arranging and conveying the magnetic cores to the rotary table, the press-fitting device is used for press-fitting the bottom shell 100, the magnetic cores and the top shell 110 distributed on the rotary table, and the testing and sorting device is used for testing the press-fitted magnetic rings and sorting qualified products and unqualified products.

In order for the bottom case 100 and the top case 110 to be aligned on the turntable, it is necessary to correct the arrangement direction of the bottom case 100 and the top case 110 in advance.

However, the existing feeding device needs to manually correct the placement direction of the bottom shell 100, and has low efficiency.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the utility model provides the special-shaped shell feeding device which can automatically correct the arrangement direction of the bottom shell, so that the bottom shell is mutually aligned with the top shell during press fitting, and the efficiency is improved.

The utility model further provides a boxing testing machine with the special-shaped shell feeding device.

According to an embodiment of the first aspect of the utility model, the special-shaped shell feeding device comprises a vibration disc, a material channel and a material stirring assembly, wherein the vibration disc, the material channel and the material stirring assembly are sequentially arranged, the material channel is used for arranging a bottom shell from the vibration disc, and the material stirring assembly is used for stirring the bottom shell on the material channel to move, and the special-shaped shell feeding device is characterized in that: the material way has first spacing groove, first spacing groove is followed the length direction of material way extends and sets up, the first rib of first spacing groove holding drain pan, still be provided with direction detection subassembly and direction correction subassembly on the material way, direction detection subassembly is located the top of material way, direction detection subassembly includes detection needle, first power piece and sensor, first power piece is used for driving the detection needle and goes up and down, the detection needle is used for detecting the direction of the first inner step and the first outer step of drain pan, the sensor with the detection needle electricity is connected, the direction correction subassembly includes the swivel base and drives swivel base pivoted first motor, the swivel base is used for supporting the drain pan after the detection needle detects, first motor with the sensor electricity is connected, the sensor is used for receiving the detected signal of detection needle and control first motor drives the direction is corrected to the drain pan.

According to the embodiment of the utility model, the feeding device for the special-shaped shell has at least the following beneficial effects:

1. according to the utility model, the vibration disc, the material channel and the material stirring assembly are sequentially arranged, the material channel is used for arranging the bottom shell from the vibration disc, and the material stirring assembly is used for stirring the bottom shell on the material channel to move, so that the bottom shell is conveniently fed from the vibration disc to the next process, and the bottom shell feeding efficiency is improved.

2. According to the utility model, the first limiting groove is formed in the material channel, and extends along the length direction of the material channel, and the first limiting groove is used for accommodating the first rib of the bottom shell, so that the bottom shell can be limited on the material channel to move in the arrangement direction parallel to the first rib and the first limiting groove, and further, the arrangement direction of the bottom shell on the material channel is corrected into two types, and the subsequent correction of the arrangement direction of the bottom shell is facilitated.

3. According to the utility model, the direction detection assembly is arranged on the material channel and comprises the detection needle, the first power piece and the sensor, the first power piece is used for driving the detection needle to lift, the detection needle is used for detecting the directions of the first inner step and the first outer step of the bottom shell, the sensor is electrically connected with the detection needle, it can be understood that when the bottom shell is stirred below the detection needle, the first power piece drives the detection needle to descend, so that the detection needle can detect the placement direction of the bottom shell, when the detection needle detects the first inner step of the bottom shell, the sensor receives a direction signal of one bottom shell placement direction detected by the detection needle, and when the detection needle detects the first outer step of the bottom shell, the sensor receives a direction signal of the other bottom shell placement direction detected by the detection needle, so that the sensor can conveniently compare the received direction signal with the set direction signal, and further, the sensor can judge whether the placement direction of the detected bottom shell is the correct direction or the opposite direction.

4. According to the utility model, the direction correcting component is arranged on the material channel and comprises the rotary seat and the first motor for driving the rotary seat to rotate, the rotary seat is used for supporting the bottom shell after the detection needle is detected, the first motor is electrically connected with the sensor, the sensor is used for receiving a detection signal of the detection needle and controlling the first motor to drive the rotary seat to correct the bottom shell, and it is understood that when the sensor judges and compares the arrangement direction of the detected bottom shell, if the arrangement direction of the bottom shell is consistent with the set direction, the sensor transmits a signal to the first motor and controls the first motor not to rotate, so that the bottom shell is directly stirred to the next station, and if the arrangement direction of the bottom shell is opposite to the set direction, the sensor transmits the signal to the first motor and controls the first motor to drive the rotary seat to rotate 180 degrees, so that the arrangement direction of the rotary seat is corrected, and then the rotary seat is stirred to the next station, so that the feeding device can automatically correct the arrangement direction of the bottom shell, and the top shell are mutually aligned when the bottom shell is pressed.

According to some embodiments of the utility model, the first power member comprises a lifting rod, the lifting rod is used for driving the detection needle to lift, the direction detection assembly further comprises a pressure head and a first spring, the pressure head is arranged at the bottom of the lifting rod and is connected with the lifting rod in an up-down sliding mode, the first spring is located between the lifting rod and the pressure head, and the first spring drives the pressure head to be away from the lifting rod downwards so as to press the bottom shell.

According to some embodiments of the utility model, the pressure head comprises a slide bar part and an outer convex ring arranged at the bottom of the slide bar part, a sliding hole for accommodating the slide bar part to slide is arranged at the bottom of the lifting rod, a waist hole extending up and down is arranged on the side wall of the sliding hole, a limit pin is arranged on the side wall of the slide bar part, and the limit pin is matched with the waist hole to limit up and down.

According to some embodiments of the utility model, the first spring is sleeved outside the sliding rod part, one end of the first spring is abutted with the bottom of the lifting rod, and the other end of the first spring is abutted with the convex ring.

According to some embodiments of the utility model, the material channel is provided with a containing cavity, the containing cavity contains the rotary seat for rotation, the rotary seat is provided with a second limit groove, the second limit groove is communicated with the first limit groove, and the second limit groove is used for containing the first rib of the bottom shell.

According to some embodiments of the utility model, the stirring assembly comprises a stirring piece, a second power piece and a third power piece, wherein the stirring piece is used for stirring the bottom shell, the second power piece is used for driving the stirring piece to reciprocate along the length direction of the material channel, and the third power piece is used for driving the stirring piece to reciprocate along the direction perpendicular to the length direction of the material channel.

According to some embodiments of the utility model, a plurality of clamping grooves are formed in one side of the poking piece, the clamping grooves are arranged in a manner of being arranged along the length direction of the material channel, and the clamping grooves are used for poking the bottom shell.

According to some embodiments of the present utility model, the discharge end of the vibration disc is located below the feed end of the material channel, and a jacking component is disposed between the discharge end of the vibration disc and the feed end of the material channel, where the jacking component includes a jacking seat, and a fourth power element driving the jacking seat to lift, and the jacking seat accommodates a bottom shell, and the jacking seat is configured to receive the bottom shell from the vibration disc and jack the bottom shell to the feed end of the material channel.

According to some embodiments of the utility model, the jacking seat is provided with a third limit groove, the third limit groove is parallel to the first limit groove, and the third limit groove is used for accommodating the first rib of the bottom shell.

According to a second aspect of the utility model, the boxing testing machine comprises the special-shaped shell feeding device.

The boxing testing machine provided by the embodiment of the utility model has at least the following beneficial effects:

1. according to the utility model, the vibration disc, the material channel and the material stirring assembly are sequentially arranged, the material channel is used for arranging the bottom shell from the vibration disc, and the material stirring assembly is used for stirring the bottom shell on the material channel to move, so that the bottom shell is conveniently fed from the vibration disc to the next process, and the bottom shell feeding efficiency is improved.

2. According to the utility model, the first limiting groove is formed in the material channel, and extends along the length direction of the material channel, and the first limiting groove is used for accommodating the first rib of the bottom shell, so that the bottom shell can be limited on the material channel to move in the arrangement direction parallel to the first rib and the first limiting groove, and further, the arrangement direction of the bottom shell on the material channel is corrected into two types, and the subsequent correction of the arrangement direction of the bottom shell is facilitated.

3. According to the utility model, the direction detection assembly is arranged on the material channel and comprises the detection needle, the first power piece and the sensor, the first power piece is used for driving the detection needle to lift, the detection needle is used for detecting the directions of the first inner step and the first outer step of the bottom shell, the sensor is electrically connected with the detection needle, it can be understood that when the bottom shell is stirred below the detection needle, the first power piece drives the detection needle to descend, so that the detection needle can detect the placement direction of the bottom shell, when the detection needle detects the first inner step of the bottom shell, the sensor receives a direction signal of one bottom shell placement direction detected by the detection needle, and when the detection needle detects the first outer step of the bottom shell, the sensor receives a direction signal of the other bottom shell placement direction detected by the detection needle, so that the sensor can conveniently compare the received direction signal with the set direction signal, and further, the sensor can judge whether the placement direction of the detected bottom shell is the correct direction or the opposite direction.

4. According to the utility model, the direction correcting component is arranged on the material channel and comprises the rotary seat and the first motor for driving the rotary seat to rotate, the rotary seat is used for supporting the bottom shell after the detection needle is detected, the first motor is electrically connected with the sensor, the sensor is used for receiving a detection signal of the detection needle and controlling the first motor to drive the rotary seat to correct the bottom shell, and it is understood that when the sensor judges and compares the arrangement direction of the detected bottom shell, if the arrangement direction of the bottom shell is consistent with the set direction, the sensor transmits a signal to the first motor and controls the first motor not to rotate, so that the bottom shell is directly stirred to the next station, and if the arrangement direction of the bottom shell is opposite to the set direction, the sensor transmits the signal to the first motor and controls the first motor to drive the rotary seat to rotate 180 degrees, so that the arrangement direction of the rotary seat is corrected, and then the rotary seat is stirred to the next station, so that the feeding device can automatically correct the arrangement direction of the bottom shell, and the top shell are mutually aligned when the bottom shell is pressed.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The foregoing and/or additional aspects and advantages of the utility model will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

fig. 1 is a schematic structural view of a bottom case and a top case according to an embodiment of the present utility model;

FIG. 2 is a schematic structural view of a cartoning machine according to an embodiment of the present utility model;

fig. 3 is a schematic structural view of a feeding device for a special-shaped shell shown in fig. 2;

fig. 4 is an enlarged view at a shown in fig. 3.

Reference numerals: 100-bottom shell, 110-top shell, 120-first inner step, 130-first outer step, 140-second inner step, 150-second outer step, 160-first rib, 170-second rib, 180-vibration disk, 190-material channel, 200-material shifting component, 210-first limit slot, 220-detection needle, 230-first power piece, 240-sensor, 250-swivel base, 260-first motor, 270-lifting rod, 280-pressure head, 290-first spring, 300-slide bar part, 310-outer convex ring, 320-waist hole, 330-limit pin, 340-accommodating cavity, 350-second limit slot, 360-pulling piece, 370-second power piece, 380-third power piece, 390-clamping slot, 400-lifting component, 410-lifting seat, 420-fourth power piece, 430-third limit slot.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

In the description of the present utility model, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present utility model and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, a number means one or more, a number means two or more, and greater than, less than, exceeding, etc. are understood to not include the present number, and above, below, within, etc. are understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

The following describes a special-shaped shell feeding device and a boxing testing machine according to the embodiment of the utility model with reference to the accompanying drawings.

Referring to fig. 2, 3 and 4, a cartoning testing machine according to an embodiment of the present utility model includes a frame, two feeding devices, a magnetic core loading device, a turntable, a press-fitting device and a test sorting device.

For the loading device, one loading device is used for arranging and conveying the bottom shell 100, and the other loading device is used for arranging and conveying the top shell 110, so that automatic arrangement and conveying of the bottom shell 100 and the top shell 110 are realized, and further, the loading efficiency is submitted.

In some specific embodiments, the feeding device includes a vibration tray 180, a material channel 190 and a material stirring assembly 200, which are sequentially arranged, the material channel 190 is used for arranging the bottom shell 100 from the vibration tray 180, and the material stirring assembly 200 is used for stirring the bottom shell 100 on the material channel 190 to move, so that the bottom shell 100 is conveniently fed from the vibration tray 180 to the next process, and the feeding efficiency of the bottom shell 100 is improved.

Further, the material channel 190 is provided with a first limit groove 210, the first limit groove 210 extends along the length direction of the material channel 190, and the first limit groove 210 accommodates the first rib 160 of the bottom shell 100, so that the bottom shell 100 can be limited to move in the placement direction parallel to the first rib 160 and the first limit groove 210 on the material channel, and further, the placement direction of the bottom shell 100 on the material channel is corrected into two types, and the correction of the placement direction of the bottom shell 100 is facilitated.

Further, the two sidewalls of the feeding end of the first limiting groove 210 are inclined in the direction away from each other, so that the first rib 160 of the bottom shell 100 is guided by the first limiting groove 210 conveniently, and the first rib 160 is easier to enter the first limiting groove 210.

In some specific embodiments, the discharge end of the vibration tray 180 is located below the feed end of the material channel 190, a jacking assembly 400 is disposed between the discharge end of the vibration tray 180 and the feed end of the material channel 190, the jacking assembly 400 includes a jacking seat 410, a fourth power member 420 driving the jacking seat 410 to lift, the jacking seat 410 accommodates one bottom shell 100, and the jacking seat 410 is used for receiving the bottom shell 100 from the vibration tray 180 and jacking the bottom shell 100 to the feed end of the material channel 190, so that the bottom shells 100 in the vibration tray 180 are conveniently transferred onto the material channel 190 one by one, so that a space is left between adjacent bottom shells 100 on the material channel 190, and further, the stirring assembly 200 conveniently stirs the bottom shell 100 in the space of the adjacent bottom shells 100 on the material channel 190.

In some specific embodiments, the jack 410 is provided with a third limiting groove 430, the third limiting groove 430 is parallel to the first limiting groove 210, and the third limiting groove 430 is used for accommodating the first rib 160 of the bottom shell 100, so that the jack 410 can conveniently screen the positioning direction of the bottom shell 100.

Further, the two side walls of the feeding end of the third limiting groove 430 are obliquely arranged along the direction away from each other, so that the third limiting groove 430 is convenient for guiding the first rib 160 of the bottom shell 100, and the first rib 160 is easier to enter the third limiting groove 430.

In some specific embodiments, the material stirring assembly 200 includes a stirring piece 360, a second power piece 370 and a third power piece 380, the stirring piece 360 is used for stirring the bottom shell 100, the second power piece 370 is used for driving the stirring piece 360 to reciprocate along the length direction of the material channel 190, and the third power piece 380 is used for driving the stirring piece 360 to reciprocate along the direction perpendicular to the length direction of the material channel 190, so that the stirring piece 360 can reset along the moving direction of the bottom shell 100 after being far away from the bottom shell 100 after each stirring movement of the bottom shell 100, and further, the bottom shell 100 on one side of the stirring piece 360 back to the conveying direction of the bottom shell 100 is prevented from obstructing the reset of the stirring piece 360.

It should be noted that the second power element 370 may be fixed on the frame, the second power element 370 drives the third power element 380 to move, the third power element 380 drives the pulling piece 360 to move, or the third power element 380 may be fixed on the frame, the third power element 380 drives the second power element 370 to move, and the second power element 370 drives the pulling piece 360 to move.

Further, the second power member 370 may be configured as a cylinder or an oil cylinder, and the third power member 380 may be configured as a cylinder or an oil cylinder.

In some specific embodiments, a plurality of clamping grooves 390 are formed in one side of the shifting piece 360, the plurality of clamping grooves 390 are arranged along the length direction of the material channel 190, and the clamping grooves 390 are used for shifting the bottom shell 100, so that the shifting piece 360 can synchronously shift a plurality of bottom shells 100 each time, and further, the shifting efficiency of the shifting assembly 200 is improved.

Further, the second power member 370 or the third power member 380 is disposed on a side of the paddle 360 away from the opening of the slot 390.

In some specific embodiments, the material channel 190 is further provided with a direction detecting assembly, the direction detecting assembly is located above the material channel 190, the direction detecting assembly includes a detecting needle 220, a first power member 230 and a sensor 240, the first power member 230 is used for driving the detecting needle 220 to lift, the detecting needle 220 is used for detecting the direction of the first inner step 120 and the first outer step 130 of the bottom shell 100, and the sensor 240 is electrically connected with the detecting needle 220.

It can be appreciated that, when the bottom shell 100 is moved below the detecting pin 220, the first power member 230 drives the detecting pin 220 to descend, so that the detecting pin 220 can detect the placement direction of the bottom shell 100, when the detecting pin 220 detects the first inner step 120 of the bottom shell 100, the sensor 240 receives a direction signal of the placement direction of one bottom shell 100 detected by the detecting pin 220, when the detecting pin 220 detects the first outer step 130 of the bottom shell 100, the sensor 240 receives a direction signal of the placement direction of the other bottom shell 100 detected by the detecting pin 220, thereby facilitating the sensor 240 to compare the received direction signal with the set direction signal, and further, the sensor 240 can determine whether the placement direction of the detected bottom shell 100 is the correct direction or the opposite direction.

In some embodiments, the first power member 230 includes a lifting rod 270, the lifting rod 270 is used for driving the detecting needle 220 to lift, the direction detecting assembly further includes a pressing head 280 and a first spring 290, the pressing head 280 is disposed at the bottom of the lifting rod 270, the pressing head 280 is connected to the lifting rod 270 in a sliding manner up and down, the first spring 290 is located between the lifting rod 270 and the pressing head 280, and the first spring 290 drives the pressing head 280 to move away from the lifting rod 270 downward to press the bottom shell 100.

It can be appreciated that when the lifting rod 270 drives the detecting needle 220 to descend, the lifting rod 270 simultaneously drives the pressure head 280 to descend, in the descending process of the lifting rod 270, the pressure head 280 is firstly abutted against the bottom shell 100 to limit, then the lifting rod 270 continues to descend, when the lifting rod 270 descends to the detecting position of the detecting needle 220, the lifting rod 270 stops descending, at this time, the pressure head 280 and the lifting rod 270 cooperate to compress the first spring 290, so that the first spring 290 presses the pressure head 280 to press the bottom shell 100 downwards, and therefore, the bottom shell 100 can be more stable when the detecting needle 220 detects the bottom shell 100.

Further, the pressure head 280 includes a sliding rod portion 300 and an outer protruding ring 310 disposed at the bottom of the sliding rod portion 300, a sliding hole for accommodating the sliding rod portion 300 to slide is disposed at the bottom of the lifting rod 270, a waist hole 320 extending up and down is disposed on a side wall of the sliding hole, a limiting pin 330 is disposed on a side wall of the sliding rod portion 300, and the limiting pin 330 is matched with the waist hole 320 to limit up and down, so that when the sliding rod portion 300 slides up and down in the sliding hole, the limiting pin 330 can move up and down in the waist hole 320, meanwhile, the top end and the bottom end of the waist hole 320 can limit the limiting pin 330, and further, the sliding rod portion 300 is prevented from being separated from the sliding hole.

Further, the first spring 290 is sleeved outside the sliding rod 300, one end of the first spring 290 is abutted with the bottom of the lifting rod 270, and the other end of the first spring 290 is abutted with the outer convex ring 310, so that the bottom of the lifting rod 270 and the outer convex ring 310 are convenient to cooperate to compress the first spring 290.

In some specific embodiments, two detection pins 220 are provided, two detection pins 220 are matched with two ends of the first inner step 120 or the first outer step 130 of the detection bottom shell 100, a mounting seat is provided on the lifting rod 270, and the detection pins 220 are mounted on the mounting seat.

In some specific embodiments, a riser is provided on the frame, and the mounting base is slidably connected to the riser up and down.

In some embodiments, the top of the riser is provided with a cross plate on which the first power member 230 is mounted.

In some embodiments, a second spring is disposed between the mount and the bottom of the riser.

In some specific embodiments, the material channel 190 is further provided with a direction correcting component, the direction correcting component includes a rotating base 250 and a first motor 260 driving the rotating base 250 to rotate, the rotating base 250 is used for supporting the bottom shell 100 after the detection of the detection needle 220, the first motor 260 is electrically connected with the sensor 240, and the sensor 240 is used for receiving the detection signal of the detection needle 220 and controlling the first motor 260 to drive the rotating base 250 to correct the direction of the bottom shell 100.

It can be appreciated that, after the sensor 240 determines and compares the detected placement direction of the bottom shell 100, if the placement direction of the bottom shell 100 is consistent with the set direction, the sensor 240 transmits a signal to the first motor 260 and controls the first motor 260 not to rotate, so that the bottom shell 100 is directly stirred to the next station, if the placement direction of the bottom shell 100 is opposite to the set direction, the sensor 240 transmits a signal to the first motor 260 and controls the first motor 260 to drive the swivel base 250 to rotate 180 ° so that the bottom shell 100 is corrected by the swivel base 250 and then stirred to the next station, thereby enabling the feeding device to automatically correct the placement direction of the bottom shell 100, enabling the bottom shell 100 to be mutually aligned with the top shell 110 during press-fitting, and improving efficiency.

In some specific embodiment shafts, the material channel 190 is provided with a containing cavity 340, the containing cavity 340 contains the rotary seat 250 to, thereby, make the rotary seat 250 can be flush with the material channel 190, make things convenient for the drain pan 100 to remove between material channel 190 and rotary seat 250, the rotary seat 250 is provided with second spacing groove 350, second spacing groove 350 intercommunication first spacing groove 210, second spacing groove 350 is used for the first rib 160 of holding drain pan 100, thereby, make things convenient for rotary seat 250 to fix a position drain pan 100.

In some embodiments, the loading device further includes a first conveyor at the discharge end of the lane 190 for transporting the bottom shell 100 from the lane 190.

In some specific embodiments, a first transfer mechanism is further disposed between the loading device and the turntable, and the first transfer mechanism is configured to transfer the bottom shell 100 on the first conveyor belt onto the turntable.

In some specific embodiments, another feeding device is used for arranging and conveying the top shell 110, and the structure of the feeding device for arranging and conveying the top shell 110 may be the same as the feeding device for arranging and conveying the bottom shell 100, or may be other structures capable of realizing the arranging and conveying function of the top shell 110.

Further, a second transfer mechanism is disposed between the feeding device for arranging and conveying the top cases 110 and the turntable, and the second transfer mechanism is used for turning over the top cases 110 on the feeding device for arranging and conveying the top cases 110 and transferring the top cases 110 onto the bottom cases 100 of the turntable.

For the upper core device, the upper core device is used for arranging and feeding the cores, and moving the cores into the bottom shell 100 of the turntable one by one.

For the turntable, a plurality of positioning seats are arranged on the turntable along the rotation axis of the turntable in a circumferential direction, and one positioning seat is used for positioning one bottom shell 100 from the feeding device.

For the press-fit device, the press-fit device is arranged on one side of the turntable and used for pressing the matched magnetic rings on the turntable.

And for the test sorting device, the test sorting device is used for performing performance test on the pressed magnetic ring and sorting qualified products and unqualified products of the magnetic ring according to the structure of the performance test.

In the description of the present specification, reference to the terms "one embodiment," "some embodiments," "illustrative embodiments," "examples," "specific examples," or "some examples," etc., means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the utility model. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The embodiments of the present utility model have been described in detail with reference to the accompanying drawings, but the present utility model is not limited to the above embodiments, and various changes can be made within the knowledge of one of ordinary skill in the art without departing from the spirit of the present utility model.

Claims (10)

1. The utility model provides a special-shaped shell loading attachment, includes vibrations dish (180), material way (190) and dialling material subassembly (200) that set gradually, material way (190) are used for arranging and come from drain pan (100) of vibrations dish (180), dialling material subassembly (200) are used for dialling drain pan (100) on material way (190) remove, its characterized in that: the material way (190) has first spacing groove (210), first spacing groove (210) are followed the length direction that material said (190) extends and sets up, first spacing groove (210) holding drain pan (100) first rib (160), still be provided with direction detection subassembly and direction correction subassembly on material said (190), direction detection subassembly is located the top that material said (190), direction detection subassembly includes detection needle (220), first power piece (230) and sensor (240), first power piece (230) are used for driving detection needle (220) go up and down, detection needle (220) are used for detecting the direction of first interior step (120) and first outer step (130) of drain pan (100), sensor (240) with detection needle (220) electricity is connected, direction correction subassembly includes (250) and drives rotary first motor (260), rotary seat (250) are used for supporting detection needle (220) detection motor, first motor (260) are used for carrying over detection needle (240) and detecting signal to drain pan (240) after the direction of rotation of first motor (260) is used for correcting signal to drain pan (240).

2. The special-shaped shell feeding device according to claim 1, wherein the first power piece (230) comprises a lifting rod (270), the lifting rod (270) is used for driving the detection needle (220) to lift, the direction detection assembly further comprises a pressing head (280) and a first spring (290), the pressing head (280) is arranged at the bottom of the lifting rod (270), the pressing head (280) is connected with the lifting rod (270) in an up-down sliding mode, the first spring (290) is located between the lifting rod (270) and the pressing head (280), and the first spring (290) drives the pressing head (280) to be away from the lifting rod (270) downwards so as to press the bottom shell (100).

3. The special-shaped shell feeding device according to claim 2, wherein the pressure head (280) comprises a sliding rod portion (300) and an outer convex ring (310) arranged at the bottom of the sliding rod portion (300), a sliding hole for accommodating the sliding rod portion (300) to slide is formed in the bottom of the lifting rod (270), a waist hole (320) extending up and down is formed in the side wall of the sliding hole, a limiting pin (330) is arranged on the side wall of the sliding rod portion (300), and the limiting pin (330) is matched with the waist hole (320) to limit up and down.

4. A special-shaped shell feeding device according to claim 3, wherein the first spring (290) is sleeved outside the sliding rod part (300), one end of the first spring (290) is abutted with the bottom of the lifting rod (270), and the other end of the first spring (290) is abutted with the outer convex ring (310).

5. The special-shaped shell feeding device according to claim 1, wherein the material channel (190) is provided with a containing cavity (340), the containing cavity (340) contains the rotating seat (250) to rotate, the rotating seat (250) is provided with a second limit groove (350), the second limit groove (350) is communicated with the first limit groove (210), and the second limit groove (350) is used for containing the first rib (160) of the bottom shell (100).

6. The special-shaped shell feeding device according to claim 1, wherein the stirring assembly (200) comprises a stirring piece (360), a second power piece (370) and a third power piece (380), the stirring piece (360) is used for stirring a bottom shell (100), the second power piece (370) is used for driving the stirring piece (360) to reciprocate along the length direction of the material channel (190), and the third power piece (380) is used for driving the stirring piece (360) to reciprocate along the direction perpendicular to the length direction of the material channel (190).

7. The special-shaped shell feeding device according to claim 6, wherein a plurality of clamping grooves (390) are formed in one side of the poking sheet (360), the clamping grooves (390) are arranged in a manner of being arranged along the length direction of the material channel (190), and the clamping grooves (390) are used for poking the bottom shell (100).

8. The special-shaped shell feeding device according to claim 1, wherein the discharging end of the vibration disc (180) is located below the feeding end of the material channel (190), a jacking component (400) is arranged between the discharging end of the vibration disc (180) and the feeding end of the material channel (190), the jacking component (400) comprises a jacking seat (410) and a fourth power piece (420) driving the jacking seat (410) to lift, the jacking seat (410) accommodates a bottom shell (100), and the jacking seat (410) is used for receiving the bottom shell (100) from the vibration disc (180) and jacking the bottom shell (100) to the feeding end of the material channel (190).

9. The special-shaped shell feeding device according to claim 8, wherein the jacking seat (410) is provided with a third limit groove (430), the third limit groove (430) is parallel to the first limit groove (210), and the third limit groove (430) is used for accommodating the first rib (160) of the bottom shell (100).

10. A cartoning machine comprising a profiled casing loading apparatus as claimed in any one of claims 1 to 9.

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