CN210139019U - Rotary disc type tube-packed crystal feeding and pin cutting mechanism - Google Patents

Abstract

The utility model relates to a carousel formula barreled crystal material loading pin cutter constructs. It includes: the feeding device comprises a rotating disk and a rotary driving device, wherein the rotating disk is provided with an installation structure for installing the charging barrel, the lower end of the charging barrel is opened, an accommodating space is arranged in the charging barrel, the feeding device also comprises a base plate sleeved outside the rotating disk, the base plate is positioned below the charging barrel and is abutted against the charging barrel, and the base plate is provided with a notch; the material guide mechanism comprises an arc-shaped material guide groove body, and the material guide groove body is provided with a conveying groove matched with the tubular crystal; the transfer mechanism is arranged between the material guide mechanism and the feeding device and is used for transferring the tubular crystals in the material barrel into the output groove; the cutting device comprises a material conveying device, wherein an opening for extending a pin of the tube-packaged crystal is formed in the lower end of the material conveying device, and a cutter device is arranged below the opening. The utility model discloses an adopt the rotary disk material loading, guide the tubulose crystal to cutting device through guide mechanism and cut, wholly need not the manual work, convenient operation.

Description

Rotary disc type tube-packed crystal feeding and pin cutting mechanism

Technical Field

The utility model relates to a tube dress electronic product's pin cutting technical field especially relates to a carousel formula tube dress crystal material loading pin cutter constructs.

Background

In the production process of the tube-packaged electronic product, the electronic product is generally integrated in a shell to form a tube-packaged crystal, such as a transistor, and then the exposed pin of the tube-packaged crystal is cut; the existing cutting mode generally adopts a semi-automatic machine, a plurality of tube-packaged crystals are arranged in a jig manually, the jig is pushed to a cutting station through a linear module, then the tube pins are cut through a cutting mechanism, after the cutting is finished, new tube-packaged crystals are placed in the tube-packaged crystals after the material is taken manually, and the operation is repeated; because adopt artifical material loading and unload, cause machining efficiency lower, and the cost of labor is higher.

Disclosure of Invention

The utility model aims to provide a turntable type tubular crystal feeding and cutting mechanism aiming at the defects of the prior art, and the feeding and cutting mechanism can automatically feed and cut materials; the manual work is not needed, and the processing efficiency can be effectively improved.

Carousel formula tube dress crystal material loading pin cutter constructs, it includes:

the feeding device comprises a rotating disk and a rotary driving device for driving the rotating disk to rotate, wherein the rotating disk is provided with an installation structure for installing a charging barrel, the lower end of the charging barrel is opened, an accommodating space for installing the tube-packaged crystals is arranged in the charging barrel, the feeding device also comprises a base plate sleeved outside the rotating disk, the base plate is positioned below the charging barrel and is abutted against the charging barrel, and the base plate is provided with a notch for leading out the tube-packaged crystals;

the material guide mechanism comprises an arc-shaped material guide groove body, and the material guide groove body is provided with a conveying groove matched with the tubular crystal;

the transfer mechanism is arranged between the material guide mechanism and the feeding device and is used for transferring the tubular crystals in the material barrel into the output groove;

and the cutting device comprises a material conveying device connected with the material guide mechanism, the lower end of the material conveying device is provided with an opening for extending a pin of the tube-packaged crystal, and a cutter device is arranged below the opening.

Further, mounting structure includes the lantern ring of being connected with the rotary disk, and the side of the lantern ring outwards extends has the multiunit stationary blade, and every group stationary blade includes the stationary blade that two intervals set up, forms the installation space who is used for installing the feed cylinder between two stationary blades.

Preferably, a clamping groove is formed in the side face of the charging barrel, a clamping block matched with the clamping groove is arranged on the fixing piece, and the clamping block is inserted into the clamping groove.

Furthermore, the transfer mechanism comprises a shell connected with the base plate, the shell comprises a material receiving part, the material receiving part is inserted into a gap of the base plate, the material receiving part is provided with a material receiving groove for guiding the tube-packed crystal, and the side surface of the shell is provided with a moving groove; the shell also comprises a discharging part, the discharging part is provided with a discharging groove for guiding out the tube-packed crystals, and the discharging groove is positioned above the conveying groove; the movable groove is respectively communicated with the material receiving groove and the material discharging groove; the movable groove is internally inserted with a push block used for transferring the tubular crystal in the material receiving groove to the material discharging groove, and one end of the push block extends out of the movable groove and is connected with a linear module used for driving the push block to move.

Preferably, the push block is provided with an accommodating through hole matched with the tube-mounted crystal.

Further, the linear module includes a cylinder.

Further, the material conveying device comprises two guide blocks which are arranged in parallel, a guide groove for conveying the pipe for loading crystals is formed between the two guide blocks, a supporting block is connected to the side surface of each guide block, the supporting block is connected with a vibrator, the material conveying device further comprises a top plate, and a lower protruding block for pressing the pipe for loading crystals is arranged at the lower end of the top plate; the top plate is connected with a lifting device.

Furthermore, the lifting device comprises two support rods, the upper ends of the two support rods are connected with an upper support plate, the upper support plate is connected with a lead screw through a bearing, the upper end of the lead screw is connected with an operating head, the support rods are connected with an intermediate block in a sliding manner, and the intermediate block can move up and down along the support rods; the middle block is in threaded connection with the screw rod, and the middle block is connected with the top plate through the middle plate.

Further, the cutting device includes: fixed shearing and activity are cut, the one end of fixed shearing is located the below of guide slot, and the lower extreme of this end is equipped with and is used for the activity to cut male shearing mouth, the one end that the activity was cut is connected with the cutting drive arrangement who is used for driving the activity and cuts the back and forth movement, and the other end that the activity was cut is equipped with and cuts mouthful matched with shearing section.

Furthermore, the cutting driving device comprises an eccentric wheel and a frame body, the eccentric wheel is positioned in the frame body and is abutted against the inner side faces of two sides of the frame body, and the frame body is fixedly connected with the movable scissors.

Further, a waste collecting container is arranged below the guide groove.

The utility model has the advantages that: the utility model discloses an adopt the rotary disk material loading, guide the tubulose crystal to cutting device through guide mechanism and cut, wholly need not the manual work, convenient operation.

Drawings

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

Fig. 2 is another schematic diagram of the present embodiment.

Fig. 3 is an enlarged schematic view of a portion a in fig. 2.

Fig. 4 is a third schematic diagram of the present embodiment.

Fig. 5 is a schematic view of the transfer mechanism.

Fig. 6 is another schematic view of fig. 5.

Fig. 7 is a schematic view of a cutting device.

The reference numerals include:

1-rotating disk; 2-a collar; 3, fixing a sheet; 4-a barrel; 5-backing plate; 6-a transfer mechanism; 7-middle plate; 8-operating head; 9-upper supporting plate; 10-middle block; 11-support bar; 12-a top plate; 13-eccentric wheel; 14-frame body; 15-lower bump; 16-a guide block; 17-fixed scissors; 18-a waste collection container; 19-a guide chute body; 20-screw mandrel; 21-a supporting block; 22-vibrator; 23-Movable shears; 31-a latch; 61-a housing; 62-push block; 63-air cylinder; 64-material receiving groove; 65-discharge chute.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings. As shown in fig. 1-4.

Example (b): referring to fig. 1, carousel formula tube dress crystal material loading pin-cutting mechanism, it includes:

the feeding device comprises a rotating disk 1 and a rotary driving device for driving the rotating disk 1 to rotate, wherein the rotating disk 1 is provided with an installation structure for installing a charging barrel 4, the lower end of the charging barrel 4 is opened, an accommodating space for installing the tube-packaged crystals is arranged in the charging barrel 4, the feeding device also comprises a backing plate 5 sleeved outside the rotating disk 1, the backing plate 5 is positioned below the charging barrel 4 and is abutted against the charging barrel 4, and the backing plate 5 is provided with a notch for guiding out the tube-packaged crystals;

the material guide mechanism comprises an arc-shaped material guide groove body 19, and the material guide groove body 19 is provided with a conveying groove matched with the tube-mounted crystal;

the transfer mechanism 6 is arranged between the material guide mechanism and the feeding device and is used for transferring the tube-packaged crystals in the material barrel 4 into the output groove;

and the cutting device comprises a material conveying device connected with the material guide mechanism, the lower end of the material conveying device is provided with an opening for extending a pin of the tube-packaged crystal, and a cutter device is arranged below the opening.

When the technical scheme works, the plurality of charging barrels 4 are arranged in the installation structure of the rotating disk 1, and the backing plate 5 is positioned below the rotating disk 1, so that the tubular crystals in the charging barrels 4 are supported by the backing plate 5; the rotating disc 1 rotates and enables an outlet at the lower end of one of the material cylinders 4 to be opposite to a discharging port of the backing plate 5, the tube-packed crystals enter the transfer mechanism 6 from the material cylinders 4, the transfer mechanism 6 transfers the tube-packed crystals to the conveying grooves of the material guide mechanism in sequence, the conveying grooves are arranged in an arc shape, the tube-packed crystals gradually move to the material conveying device under the action of self gravity, the material conveying device conveys the tube-packed crystals, the pins of the tube-packed crystals extend out of the openings at the lower ends, and the cutter device cuts the pins, so that the pins are cut; the tube-packed crystals enter the next working procedure or are directly collected under the conveying of the material conveying device. The rotary drive device may employ a rotary motor or the like.

Referring to fig. 3, further, the mounting structure includes a collar 2 connected to the rotating disk 1, a plurality of sets of fixing pieces 3 extend outwards from the side of the collar 2, each set of fixing pieces 3 includes two fixing pieces 3 arranged at intervals, and a mounting space for mounting the charging barrel 4 is formed between the two fixing pieces 3.

Preferably, a clamping groove is formed in the side surface of the material barrel 4, a clamping block 31 matched with the clamping groove is arranged on the fixing piece 3, and the clamping block 31 is inserted into the clamping groove.

The charging barrel 4 can rotate along with the rotating disk 1 by connecting a sleeve on the side surface of the rotating disk 1; a mounting space which is spliced with the charging barrel 4 is formed between the two fixing pieces 3 on the lantern ring 2, so that the charging barrel 4 is convenient to mount. Secondly, set up the draw-in groove on feed cylinder 4, set up fixture block 31 on stationary blade 3, both can be injectd feed cylinder 4 in the installation space, also have installation guide effect simultaneously, easy to assemble.

See fig. 5, 6; further, the transfer mechanism 6 comprises a shell 61 connected with the backing plate 5, the shell 61 comprises a material receiving portion, the material receiving portion is inserted into a gap of the backing plate 5, the material receiving portion is provided with a material receiving groove 64 for guiding the tube-packed crystals, and the side surface of the shell 61 is provided with a moving groove; the shell 61 further comprises a discharging part, the discharging part is provided with a discharging groove 65 for guiding out the tube-packed crystals, and the discharging groove 65 is positioned above the conveying groove; the movable groove is respectively communicated with the material receiving groove 64 and the material discharging groove 65; a pushing block 62 for transferring the tubular crystal in the material receiving groove 64 to the material discharging groove 65 is inserted in the moving groove, and one end of the pushing block 62 extends out of the moving groove and is connected with a linear module for driving the pushing block 62 to move.

The transfer mechanism 6 adopts the mode that the ejector pad 62 shifts, and the shifting chute communicates with material receiving groove 64, blown down tank 65 respectively, and after the pipe dress crystal got into the shifting chute from material receiving groove 64, under the drive of ejector pad 62, shift to blown down tank 65 and fall to the conveyer trough under the effect of self gravity. Simple structure and convenient operation. Of course, the transfer mechanism 6 may be implemented by a robot.

Preferably, the pushing block 62 is provided with a receiving through hole for fitting the tube-mounted crystal.

The push block 62 is provided with a containing through hole, so that the tube-mounted crystal directly enters the containing through hole when entering the moving groove from the material receiving groove 64, then is transferred to the discharge groove 65 under the driving of the push block 62, and then freely falls into the discharge groove 65 and the conveying groove. Thereby avoiding the tube-packed crystal from being extruded or collided in the conveying groove and improving the quality.

Further, the linear module includes a cylinder 63.

The pushing block 62 is driven to move by the air cylinder 63, and the operation is simple and convenient. Of course, other configurations are possible, such as a lead screw and nut mechanism.

Referring to fig. 2 and 4, further, the material conveying device comprises two guide blocks 16 arranged in parallel, a guide groove for conveying the crystals is formed between the two guide blocks 16, a support block 21 is connected to the side surface of the guide block 16, a vibrator 22 is connected to the support block 21, the material conveying device further comprises a top plate 12, and a lower convex block 15 for pressing and pressing the crystals is arranged at the lower end of the top plate 12; the top plate 12 is connected with a lifting device.

After entering the guide groove from the conveying groove, the tube-packed crystal is driven by the vibrator 22 to move forward step by step; in order to prevent the shape and position of the transistor-packaged crystal from changing, such as side turning; this technical scheme has set up roof 12, and in operation, roof 12 and two guide blocks 16 butts under elevating gear's drive, and lower protruding piece 15 is close to the tubulose crystal or with the tubulose crystal butt, prevents its upset.

Referring to fig. 4 and 2, further, the lifting device comprises two support rods 11, the upper ends of the two support rods 11 are connected with an upper support plate 9, the upper support plate 9 is connected with a screw rod 20 through a bearing, the upper end of the screw rod 20 is connected with an operating head 8, the support rods 11 are slidably connected with an intermediate block 10, and the intermediate block 10 can move up and down along the support rods 11; the middle block 10 is in threaded connection with the screw rod 20, and the middle block 10 is connected with the top plate 12 through the middle plate 7.

The lifting device adjusts the height of the top plate 12 through the operating head 8, and the operation is convenient. Other configurations for the elevator arrangement are possible.

Referring to fig. 7, further, the cutting device includes: fixed scissors 17 and activity are cut 23, the one end of fixed scissors 17 is located the below of guide slot, and the lower extreme of this end is equipped with and is used for the activity to cut 23 male cutting opening, the one end of activity is cut 23 and is connected with the cutting drive arrangement who is used for driving the activity to cut 23 back and forth movement, and the other end of activity is cut 23 and is equipped with and cuts a mouthful matched with shearing section.

When the tube-packed crystal enters the guide groove, the movable shears 23 are driven by the cutting driving device to move towards the fixed shears 17 and insert into the shear notch, and meanwhile, the tube-packed crystal is subjected to pin cutting. Is simple and convenient.

Furthermore, the cutting driving device includes an eccentric wheel 13 and a frame 14, the eccentric wheel 13 is located in the frame 14 and abuts against the inner side surfaces of two sides of the frame 14, and the frame 14 is fixedly connected with the movable shears 23.

The cutting driving device can also be an air cylinder and the like. After the eccentric wheel 13 and the frame 14 are arranged, the frame 14 is driven to move back and forth through the rotation of the eccentric wheel 13, and the back and forth movement of the movable scissors 23 is realized.

Further, a waste collecting container 18 is provided below the guide groove.

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

Claims (10)

1. Carousel formula tube dress crystal material loading pin cutter constructs, its characterized in that: it includes:

the feeding device comprises a rotating disk and a rotary driving device for driving the rotating disk to rotate, wherein the rotating disk is provided with an installation structure for installing a charging barrel, the lower end of the charging barrel is opened, an accommodating space for installing the tube-packaged crystals is arranged in the charging barrel, the feeding device also comprises a base plate sleeved outside the rotating disk, the base plate is positioned below the charging barrel and is abutted against the charging barrel, and the base plate is provided with a notch for leading out the tube-packaged crystals;

the material guide mechanism comprises an arc-shaped material guide groove body, and the material guide groove body is provided with a conveying groove matched with the tubular crystal;

the transfer mechanism is arranged between the material guide mechanism and the feeding device and is used for transferring the tubular crystals in the material barrel into the output groove;

and the cutting device comprises a material conveying device connected with the material guide mechanism, the lower end of the material conveying device is provided with an opening for extending a pin of the tube-packaged crystal, and a cutter device is arranged below the opening.

2. The carousel tubular crystal loading and cutting mechanism of claim 1, wherein: the mounting structure includes the lantern ring of being connected with the rotary disk, and the outside extension in side of the lantern ring has the multiunit stationary blade, and every group stationary blade includes the stationary blade that two intervals set up, forms the installation space who is used for installing the feed cylinder between two stationary blades.

3. The carousel tubular crystal loading and cutting mechanism of claim 2, wherein: the side of feed cylinder is equipped with the draw-in groove, the stationary blade is equipped with the fixture block with draw-in groove matched with, and the fixture block inserts the draw-in groove.

4. The carousel tubular crystal loading and cutting mechanism of claim 1, wherein: the transfer mechanism comprises a shell connected with the base plate, the shell comprises a material receiving part, the material receiving part is inserted into a gap of the base plate, the material receiving part is provided with a material receiving groove for leading in the tube-packed crystals, and the side surface of the shell is provided with a moving groove; the shell also comprises a discharging part, the discharging part is provided with a discharging groove for guiding out the tube-packed crystals, and the discharging groove is positioned above the conveying groove; the movable groove is respectively communicated with the material receiving groove and the material discharging groove; the movable groove is internally inserted with a push block used for transferring the tubular crystal in the material receiving groove to the material discharging groove, and one end of the push block extends out of the movable groove and is connected with a linear module used for driving the push block to move.

5. The carousel tubular crystal loading and cutting mechanism of claim 4, wherein: the push block is provided with an accommodating through hole matched with the tube-mounted crystal.

6. The carousel tubular crystal loading and cutting mechanism of claim 1, wherein: the material conveying device comprises two guide blocks which are arranged in parallel, a guide groove for conveying the pipe to load crystals is formed between the two guide blocks, the side surface of each guide block is connected with a supporting block, the supporting block is connected with a vibrator, the material conveying device further comprises a top plate, and the lower end of the top plate is provided with a lower protruding block for pressing the pipe to load crystals; the top plate is connected with a lifting device.

7. The carousel tubular crystal loading and cutting mechanism of claim 6, wherein: the lifting device comprises two supporting rods, the upper ends of the two supporting rods are connected with an upper supporting plate, the upper supporting plate is connected with a lead screw through a bearing, the upper end of the lead screw is connected with an operating head, the supporting rods are connected with an intermediate block in a sliding manner, and the intermediate block can move up and down along the supporting rods; the middle block is in threaded connection with the screw rod, and the middle block is connected with the top plate through the middle plate.

8. The carousel tubular crystal loading and cutting mechanism of claim 6, wherein: the cutting device includes: fixed shearing and activity are cut, the one end of fixed shearing is located the below of guide slot, and the lower extreme of this end is equipped with and is used for the activity to cut male shearing mouth, the one end that the activity was cut is connected with the cutting drive arrangement who is used for driving the activity and cuts the back and forth movement, and the other end that the activity was cut is equipped with and cuts mouthful matched with shearing section.

9. The carousel tubular crystal loading and cutting mechanism of claim 8, wherein: the cutting driving device comprises an eccentric wheel and a frame body, the eccentric wheel is positioned in the frame body and is abutted against the inner side faces of two sides of the frame body, and the frame body is fixedly connected with the movable scissors.

10. The carousel tubular crystal loading and cutting mechanism of claim 6, wherein: and a waste material collecting container is arranged below the guide groove.

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