CN217622419U - Material distribution mechanism for compression molding equipment - Google Patents

Abstract

The utility model discloses a cloth mechanism for compression moulding equipment, include: the device comprises a raw material bin, a baffle plate, a material distribution box, an upper sealing plate, a rack, a material box guide strip, a telescopic mechanism and a lower sealing plate; the bottom of the baffle plate is connected with the side edge of the upper sealing plate, the baffle plate encloses a feeding channel, and the front end of the feeding channel is provided with a guide opening; a feed opening is formed in the bottom of the raw material bin, the feed opening is located in the feeding channel, and the bottom end of the feed opening is lower than the upper edge of the baffle; the front part of the upper sealing plate is provided with a feeding opening, the top of the material distribution box is connected to the lower part of the feeding opening, the upper and lower positions of the material distribution box are respectively provided with an opening, and a plurality of material stirring devices are arranged in the material distribution box; the bottoms of the rear sections of the two bin guide strips are connected to the lower sealing plate, the front sections of the two bin guide strips extend out, and the racks are connected to the upper parts of the bin guide strips; the telescopic mechanism is connected between the lower sealing plate and the side wall of the rear end of the material distribution box. The utility model discloses the pay-off is even, the card material condition can not appear.

Description

Material distribution mechanism for compression molding equipment

Technical Field

The utility model belongs to the technical field of raw materials conveying equipment, concretely relates to cloth mechanism for compression moulding equipment.

Background

The material distribution equipment is used for conveying raw materials to the compression molding equipment, and the conventional material distribution equipment is generally provided with a travelling mechanism which is used for approaching the compression molding equipment and conveying the raw materials; the material distributing mechanism without the walking equipment adopts a belt to convey raw materials.

Such design can prolong the production line usually for the production line flow lengthens, and the raw materials scatter easily moreover, is not convenient for realize automatic control. For irregular bulk materials, the irregular bulk materials are easily clamped at a feed opening after being conveyed to the hydraulic forming equipment, and the normal production of the hydraulic forming equipment is influenced.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a cloth mechanism for compression moulding equipment can realize the accurate pay-off to the mould to the pay-off is even, the card material condition can not appear.

The technical scheme is as follows:

a cloth mechanism for a press forming apparatus, comprising: the device comprises a raw material bin, a baffle plate, a material distribution box, an upper sealing plate, a rack, a material box guide strip, a telescopic mechanism and a lower sealing plate; the bottom of the baffle plate is connected with the side edge of the upper sealing plate, the baffle plate encloses a feeding channel, and the front end of the feeding channel is provided with a guide opening; a feed opening is formed in the bottom of the raw material bin, the feed opening is located in the feeding channel, and the bottom end of the feed opening is lower than the upper edge of the baffle; the front part of the upper sealing plate is provided with a feeding opening, the top of the material distribution box is connected to the lower part of the feeding opening, the upper part and the lower part of the material distribution box are respectively provided with an opening, and a plurality of material stirring devices are arranged in the material distribution box; the bottoms of the rear sections of the two bin guide strips are connected to the lower sealing plate, the front sections of the two bin guide strips extend out, and the racks are connected to the upper parts of the bin guide strips; the telescopic mechanism is connected between the lower sealing plate and the side wall of the rear end of the material distribution box.

Further, the kickoff includes: a deflector rod mounting shaft, a material poking rod, a material poking power gear and a bearing seat; the two bearing seats are respectively connected to the outer side wall of the material distributing box, two ends of the driving lever mounting shaft are respectively sleeved in the two bearing seats, the two material stirring power gears are respectively connected to the outer sides of the two bearing seats, and the end portions of the plurality of material stirring rods are connected to the outer wall of the driving lever mounting shaft.

Furthermore, a plurality of radially arranged material shifting rods form a material shifting rod group, and the material shifting rod groups are axially distributed on the material shifting rod mounting shaft.

Further, the bottom end of the feed opening is lower than the upper edge of the baffle.

Furthermore, the lower sealing plate and the upper sealing plate are parallel to each other.

Further, the telescopic mechanism includes: the material stirring hydraulic cylinder, the telescopic rod, the hydraulic supporting seat and the hinge seat; the hydraulic support seat is connected with the outer wall of the material shifting hydraulic cylinder, and the bottom of the hydraulic support seat is connected to the lower sealing plate; one end of the telescopic rod is positioned in the material stirring hydraulic cylinder, the other end of the telescopic rod is connected with the front end of the hinged seat, and the bottom of the hinged seat is connected to the side wall of the material distribution box.

Further, the telescopic mechanism adopts an electric telescopic rod.

Furthermore, the edges of the two sides of the upper sealing plate are provided with a plurality of guide blocks.

Compared with the prior art, the utility model have following advantage:

the utility model discloses can form the cooperation with hydraulic pressure mechanism's action, realize accurate pay-off in to the mould to the pay-off is even, the card material condition can not appear

Drawings

FIG. 1 is a schematic perspective view of a hydraulic press and a distributing mechanism of the present invention;

FIG. 2 is a schematic structural view of a material distributing mechanism of the present invention;

FIG. 3 is a schematic structural view of the material stirring device of the present invention;

fig. 4 is a schematic diagram of the cooperation of the middle hydraulic press, the material distribution mechanism and the mold.

Detailed Description

The following description sufficiently illustrates specific embodiments of the invention to enable those skilled in the art to practice and reproduce it.

As shown in fig. 1, it is a schematic perspective view of the medium hydraulic press 1 and the material distribution mechanism 2 of the present invention.

A press forming apparatus comprising: hydraulic pressure machine 1, cloth mechanism 2, mould 3. The material distribution mechanism 2 is used for feeding the mixture into a die 3 arranged in a hydraulic press 1, and the hydraulic press 1 presses the aluminum particles in the die into blocky aluminum briquetting deoxidizer.

The hydraulic press 1 includes: hydraulic cylinder 101, upper fixed beam 102, movable beam 103, fixed base beam 104 and upright 105.

An oil inlet at the top of the hydraulic cylinder 101 is connected with a hydraulic system through a hydraulic pipeline. Go up fixed beam 102 and be provided with pneumatic cylinder fixing through hole, connect fixed through hole on four, pneumatic cylinder fixing through hole is located fixed beam 102 middle part on, connects fixed through hole on four and is located the pneumatic cylinder fixing through hole outside. The bottom of pneumatic cylinder 101 is fixed in the pneumatic cylinder fixed through-hole, and the telescopic link one end that pushes down of pneumatic cylinder 101 is located pneumatic cylinder 101, and the other end stretches out pneumatic cylinder fixed through-hole and is connected with walking beam 103.

The fixed base beam 104 is provided with a jacking cylinder fixing through hole 107 and four lower connecting fixing through holes, the jacking cylinder fixing through hole is positioned in the middle of the fixed base beam 104, and the four lower connecting fixing through holes are positioned outside the jacking through hole. A jacking cylinder 106 is arranged in the jacking through hole, and a jacking rod is arranged in the jacking cylinder 106. An oil inlet at the lower part of the jacking cylinder 106 is connected with a hydraulic system through a hydraulic pipeline.

The movable beam 103 is provided with four positioning through holes, four upright posts 105 are respectively sleeved in the four positioning through holes, the upper parts of the upright posts 105 are connected in the upper connecting and fixing through holes, and the lower parts of the upright posts 105 are connected in the lower connecting and fixing through holes and are fixed by bolts.

The fixed base beam 104 is provided with a fixed support 109, the material distribution mechanism 2, the die hole assembly 31 and the separated material outlet 108 are respectively connected to the fixed support 109, the material distribution mechanism 2 and the separated material outlet 108 are respectively positioned at two sides of the die 3, and the material distribution mechanism 2, the die 3 and the separated material outlet 108 are positioned between the fixed base beam 104 and the movable beam 103.

As shown in fig. 2, is a schematic structural diagram of the material distribution mechanism 2 of the present invention. As shown in fig. 3, is a schematic structural diagram of the material stirring device 231 in the present invention.

The distributing mechanism 2 includes: the device comprises a raw material bin 21, a baffle plate 22, a material distribution box 23, an upper sealing plate 24, a rack 25, a box guide strip 26, a telescopic mechanism 27 and a lower sealing plate 28.

The bottom of the baffle plate 22 is connected with the side edge of the upper closing plate 24, the baffle plate 22 encloses a feeding channel 221, and the front end of the feeding channel 221 is provided with a guide opening 222; a feed opening is formed in the bottom of the raw material bin 21, the feed opening is located in the feeding channel 221, and the bottom end of the feed opening is lower than the upper edge of the baffle 22; the front part of the upper sealing plate 24 is provided with a feeding opening 241, the top of the material distribution box 23 is connected with the lower part of the feeding opening 241, the upper part and the lower part of the material distribution box 23 are respectively provided with an opening, and a plurality of material stirring devices 231 are arranged in the material distribution box 23; the lower sealing plate 28 and the upper sealing plate 24 are parallel to each other, the bottoms of the rear sections of the two bin guide bars 26 are connected to the lower sealing plate 28, and the front sections of the two bin guide bars extend out of two sides of the die hole assembly 31; the rack 25 is connected to the upper part of the feed box guide bar 26, the lower part of the telescopic mechanism 27 is fixed on the lower sealing plate 28, and the telescopic component is connected to the outer wall of the cloth feed box 23.

Lower seal plate 28 is attached to mounting bracket 109 and lower seal plate 28 serves to support upper seal plate 24 and the components mounted on upper seal plate 24. The lower sealing plate 28 is used for sealing or opening the opening at the lower part of the material distribution box 23 along with the position change of the material distribution box 23 relative to the lower sealing plate 28. Along with the position change of the feed opening of the raw material bin 21 and the upper sealing plate 24, the upper sealing plate 24 is used for plugging or opening the feed opening.

The material setting device 231 includes: a shifting rod mounting shaft 232, a shifting rod 233, a shifting power gear 234 and a bearing seat 235; the two bearing blocks 235 are respectively connected to the outer side wall of the material distribution box 23, two ends of the deflector rod mounting shaft 232 are respectively sleeved in the two bearing blocks 235, and the two material shifting power gears 234 are respectively connected to the outer sides of the two bearing blocks 235; the ends of the plurality of driver rods 233 are connected to the outer wall of the driver rod mounting shaft 232.

The plurality of radially arranged material shifting rods 233 form a material shifting rod group, and the plurality of material shifting rod groups are axially distributed on the material shifting rod mounting shaft 232.

The telescopic mechanism 27 includes: the material shifting hydraulic cylinder 271, the telescopic rod 272, the hydraulic support seat 273 and the hinge seat 274; the hydraulic support 273 is connected with the outer wall of the material shifting hydraulic cylinder 271, and the bottom of the hydraulic support 273 is connected with the lower sealing plate 28; one end of the telescopic rod 272 is located in the material stirring hydraulic cylinder 271, the other end of the telescopic rod is connected with the front end of the hinged seat 274, and the bottom of the hinged seat 274 is connected to the side wall of the material distribution box 23.

Of course, the telescopic mechanism 27 may be an electric telescopic rod.

In order to make the material distribution box 23 advance along a straight line, the edges of two sides of the upper sealing plate 24 are provided with guide blocks, and the material distribution box 23 always keeps advancing straight line in the process that the telescopic mechanism 27 pushes the material distribution box 23 and the upper sealing plate 24 to move.

As shown in fig. 4, it is a schematic diagram of the present invention that the hydraulic press 1, the material distribution mechanism 2, and the mold 3 are used in cooperation.

The using process is as follows:

1. the aluminum particles in the main bin are conveyed to the raw material bin 21, the aluminum particles in the raw material bin 21 fall into the material distribution bin 23, the material stirring hydraulic cylinder 271 is filled with pressure oil, the telescopic rod 272 pushes the material distribution bin 23 to move forwards to the upper part of the die hole assembly 31, the upper sealing plate 24 seals a feed opening of the raw material bin 21 in the process of forward movement of the material distribution bin 23, after the material distribution bin 23 reaches the upper part of the die hole sleeve 312, an opening in the lower part of the material distribution bin 23 is opened, the rack 25 drives the material stirring power gear 234 to rotate, and the material stirring rod 233 charges the aluminum particles into the hole cavity of the die hole sleeve 312 in the rotating process;

2. after the aluminum particles are filled, the telescopic rod 272 retracts to drive the material distribution box 23 to move backwards, the material distribution box 23 scrapes the aluminum particles of the die hole sleeve 312 flat, the material distribution box 23 moves backwards to the lower part of the raw material bin 21, the upper sealing plate 24 opens the feed opening of the raw material bin 21, the lower sealing plate 28 closes the lower opening of the material distribution box 23, and the aluminum particles fall into the material distribution box 23;

3. the hydraulic cylinder 101 of the compression molding equipment injects pressure oil, the telescopic rod is pressed downwards to move downwards, the movable beam 103 is pushed to move downwards, the movable beam 103 drives the compression rod assembly 32 to move downwards, the pressure head 323 at the lower part of the pressure rod 322 extends into the hole cavity of the die hole sleeve 312, and the pressure head 323 compresses and molds aluminum particles to form a blocky aluminum pressure block molding deoxidizer;

4. oil is drained by the hydraulic cylinder 101, the telescopic rod is pressed downwards to rise, the movable beam 103 drives the pressing rod assembly 32 to rise, and the pressing rod 322 and the pressing head 323 leave from the hole cavity of the die hole sleeve 312; lifting the lifting rod of the lifting cylinder 106 to push the lifting rod assembly 33 to lift, wherein the ejector rod 332 and the ejector head 333 extend into the hole cavity of the die hole sleeve 312 to eject the aluminum briquetting deoxidizer out of the hole cavity;

5. the telescopic rod 272 pushes the material distribution box 23 to move forward, and the front scraper of the material distribution box 23 pushes the aluminum briquetting deoxidizer to the separated discharge port 108 and falls into the collection box at the lower part; while the distributing box 23 moves forward to push the aluminum briquette forming deoxidizer, the aluminum particles are again filled into the hole cavity of the die hole sleeve 312, and the pressing and forming equipment presses the aluminum particles into the aluminum briquette forming deoxidizer again.

Aluminum particles scattered in the filling process enter the raw material bin 21 again, and after the aluminum briquetting forming deoxidizer in the collecting box is filled, the aluminum briquettes are conveyed to be stored in a warehouse through a conveying belt or a forklift.

The terminology used herein is for the purpose of description and illustration, rather than of limitation. As the present invention may be embodied in several forms without departing from the spirit or essential characteristics thereof, it should also be understood that the above-described embodiments are not limited by any of the details of the foregoing description, but rather should be construed broadly within its spirit and scope as defined in the appended claims, and therefore all changes and modifications that fall within the meets and bounds of the claims, or equivalences of such meets and bounds are therefore intended to be embraced by the appended claims.

Claims (8)

1. A cloth mechanism for a press forming apparatus, comprising: the device comprises a raw material bin, a baffle plate, a material distribution box, an upper sealing plate, a rack, a material box guide strip, a telescopic mechanism and a lower sealing plate; the bottom of the baffle is connected with the side edge of the upper sealing plate, the baffle encloses a feeding channel, and the front end of the feeding channel is provided with a guide opening; a feed opening is formed in the bottom of the raw material bin, the feed opening is located in the feeding channel, and the bottom end of the feed opening is lower than the upper edge of the baffle; the front part of the upper sealing plate is provided with a feeding opening, the top of the material distribution box is connected to the lower part of the feeding opening, the upper and lower positions of the material distribution box are respectively provided with an opening, and a plurality of material stirring devices are arranged in the material distribution box; the bottoms of the rear sections of the two bin guide strips are connected to the lower sealing plate, the front sections of the two bin guide strips extend out, and the racks are connected to the upper parts of the bin guide strips; the telescopic mechanism is connected between the lower sealing plate and the side wall of the rear end of the material distribution box.

2. The distributing mechanism for a press forming apparatus as claimed in claim 1, wherein the material setting device comprises: a deflector rod mounting shaft, a material poking rod, a material poking power gear and a bearing seat; the two bearing seats are respectively connected to the outer side wall of the material distributing box, two ends of the driving lever mounting shaft are respectively sleeved in the two bearing seats, the two material stirring power gears are respectively connected to the outer sides of the two bearing seats, and the end portions of the plurality of material stirring rods are connected to the outer wall of the driving lever mounting shaft.

3. The distributing mechanism for a press forming apparatus as claimed in claim 2, wherein the plurality of radially arranged material shifting rods form a material shifting rod group, and the plurality of material shifting rod groups are axially distributed on the shifting rod mounting shaft.

4. The distributing mechanism for a press forming apparatus according to claim 1, wherein the lower end of the feed opening is lower than the upper edge of the baffle.

5. The distributing mechanism for a press forming apparatus according to claim 1, wherein the lower plate and the upper plate are parallel to each other.

6. The distributing mechanism for the press forming apparatus according to claim 1, wherein the telescoping mechanism comprises: the material shifting hydraulic cylinder, the telescopic rod, the hydraulic supporting seat and the hinge seat; the hydraulic support seat is connected with the outer wall of the material shifting hydraulic cylinder, and the bottom of the hydraulic support seat is connected to the lower sealing plate; one end of the telescopic rod is positioned in the material stirring hydraulic cylinder, the other end of the telescopic rod is connected with the front end of the hinged seat, and the bottom of the hinged seat is connected onto the side wall of the material distribution box.

7. The distributing mechanism for the press forming equipment according to claim 1, wherein the telescoping mechanism is an electric telescopic rod.

8. The distributing mechanism for a press forming apparatus as claimed in claim 1, wherein a plurality of guide blocks are provided at both side edges of the upper sealing plate.

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