JP2021167104A - Slurry working device for injection molding production technique - Google Patents

Abstract

To provide a slurry working device that can perform unified stirring of slurry for quantitative working and can also perform polishing treatment to too large crystal grains inside the slurry.SOLUTION: A slurry working device comprises a stirring tub 1, a stirring shaft 2 is connected between the inner walls at upper and lower both edges in the stirring tub with a bearing, the upper edge of the stirring shaft is connected with a stirring motor 3 through the stirring tub, the stirring motor is fitted to the outer wall of the stirring tub by a motor bracket, the stirring shaft has a hollow structure, and the stirring shaft is provided with a pulverization mechanism 4 and a polishing mechanism 5 gradually from top to bottom. The pulverization mechanism comprises a driving ring 41 fitted to the outer wall of the stirring shaft, the outer wall of the driving ring is provided with stirring rods 42 at equal intervals along a circumferential direction, the lower edge of each stirring rod is provided with a stirring brush, the stirring brush is pasted on a filtration plate 43, and the filtration plate is provided with filtration holes at equal intervals.SELECTED DRAWING: Figure 1

Description

The present invention relates to the field of injection molding technology, and specifically to a slurry processing apparatus for injection molding manufacturing technology.

Injection molding is a molding method that combines injection and molding. The advantages of injection molding method are fast production speed, high efficiency, automation of operation, many colors and varieties, adjustable shape and size, accurate product dimensions, product update. It is easy to produce products with complicated shapes, is suitable for mass production, and is applied to the molding processing field such as products with complicated shapes. Products made by injection molding have a high demand for slurries, and the fineness of the slurry directly affects the density inside the injection molded product.

However, there are two problems with the slurry stirring process in the conventional injection molding process. First, in order to prevent the slurry from condensing into a large area during slurry stirring with a conventional stirrer, only rotary stirring is adopted, and large particles in the slurry cannot be completely removed, and injection molding is performed. The product after molding does not meet the specified standard because it affects the density inside the product afterwards. The second is that the conventional stirrer stirs the slurry all at once during the work, and the slurry cannot be finely divided into several times for quantitative processing, and the crystal particles that are too large inside the slurry are polished. Could not be performed, and the processing stirring effect was inferior.

Personnel in related technical fields conducted research on the technical issues existing in the current injection molding process, and then proceeded with improvements. For example, the slurry agitation improver described in CN207166899U can save costs and improve agitation efficiency, but does not mention the problems present in the injection molding process described above.

Chinese Patent Application Publication No. 207616899

An object of the present invention is to provide a slurry processing apparatus for injection molding manufacturing technology in order to solve the above-mentioned problems in the prior art.

In order to realize the above object, it is a slurry processing apparatus for injection molding manufacturing technology, including a stirring tub, and a stirring shaft is connected between the inner walls at both upper and lower ends of the stirring tub by a bearing, and the stirring is performed. The upper end of the shaft passes through the stirring tub and is connected to the stirring motor, the stirring motor is attached to the outer wall of the stirring tub by a motor bracket, the stirring shaft has a hollow structure, and the stirring shaft has a hollow structure. , A crushing mechanism and a polishing mechanism are gradually provided from top to bottom.

The crushing mechanism includes a drive ring attached to the outer wall of the stirring shaft, and stirring rods are provided at equal intervals along the circumferential direction on the outer wall of the driving ring, and stirring is performed at the lower end of the stirring rod. A brush is provided, the stirring brush is attached to a filter plate, the filter plate is provided with filtration holes at equal intervals, and the filter plate is externally attached to the stirring shaft by adopting sliding. The lower end of the filter plate is attached to the slurry discharge plate by a telescopic spring rod, the slurry discharge plate and the stirring shaft are connected by a bearing, the slurry discharge plate is fixed to the inner wall of the stirring tub, and the slurry is fixed. Slurry discharge ports are provided at equal intervals in the discharge holes.

The polishing mechanism includes a first polishing device and a second polishing device sequentially provided on the stirring shaft from top to bottom, and the first polishing device and the second polishing device are connected by a control device. The control device is attached to the inner wall of the stirring shaft, auxiliary devices are provided at equal intervals at the lower end of the first polishing device, and the first polishing device is polished to be exteriorized on the outer wall of the stirring shaft. Polishing components are symmetrically provided on the inner wall of the polishing frame, including the frame, and the polishing components are attached to the rotating columns between the inner walls of the polishing frame by bearings at equal intervals. A driven pulley is provided in the central portion, polishing balls are provided at equal intervals on the outer wall of the rotating column, two adjacent driven pulleys are connected by an interlocking belt, and the inner wall of the stirring tub is connected to the inner wall of the stirring tub. A guide frame to be combined with the polishing frame is provided.

Preferably, the control device includes a drive motor that is attached to the inner wall of the stirring shaft by a motor bracket, a control sprocket is attached to the output shaft of the drive motor, and two controls are attached to the inner wall of the stirring shaft. The shaft is attached by a bearing, the two control shafts are symmetrically located on both the upper and lower sides of the control sprocket, the stirring shaft is formed with a through groove to be combined with the control shaft, and the control shaft is controlled. A pulley and a driven sprocket are attached, the driven sprocket is connected to the control sprocket by a chain, a transmission belt is attached to the control pulley, and the transmission belt passes through the through groove in the polishing frame. It is connected to the driven pulley on the inside.

Preferably, the auxiliary device includes an auxiliary support attached to the lower end surface of the guide frame, and an auxiliary kneading table is connected to the outer wall of the auxiliary support by a repositioning spring rod, and the lower end surface of the auxiliary kneading table is connected. The kneading balls are provided at equal intervals, a repositioning groove is formed at the lower end of the auxiliary support, an auxiliary rod is attached to the auxiliary kneading base, and the auxiliary rod is placed in the repositioning groove. Slidably provided, an auxiliary motor is attached to the inner wall of the auxiliary support by a motor bracket, the auxiliary motor is provided with a cam, and the cam abuts on the auxiliary rod.

Preferably, the lower end surface of the auxiliary kneading table is parallel to the upper end surface of the polishing frame.

Preferably, a control rod is provided at the upper end of the filter plate, the upper end of the control rod abuts on the drive ring, and the end surface of the drive ring and the control rod in contact has a curved uneven structure. ..

Preferably, partition blocks are provided at the lower ends of the filter plate at equal intervals, the partition blocks have a T-shaped structure, the partition blocks are located in the slurry discharge port, and are below the partition blocks. The end face and the lower end face of the slurry discharge port are located in the same horizontal plane.

Preferably, the polishing frame has a hollow trapezoidal structure in which the diameter gradually decreases downward, the guide frame has a trapezoidal annular structure in which the diameter gradually decreases downward, and the polishing frame has a lower end surface thereof. It is parallel to the upper end surface of the guide frame.

Preferably, the upper end of the stirring tub is provided with a slurry inlet, the lower end of the stirring tub has a trapezoidal structure in which the diameter gradually increases from top to bottom, and the stirring tub has a circumferential direction. Slurry feed ports are formed at equal intervals.

Compared with the prior art, the present invention has the following advantages:
The present invention can solve the above problems in the prior art.
The crushing mechanism in the present invention can completely stir the slurry inside the stirring tub during the work, and the slurry that has been sufficiently agitated during the stirring work is discharged from the filtration hole, and the drive ring and the control rod are used during the stirring work. By controlling the opening and closing of the slurry discharge port in cooperation with the above, the slurry can be discharged quantitatively from the slurry discharge port, and the slurry can be processed quantitatively in several times.
The polishing mechanism in the present invention can polish the slurry during the work, finely process the slurry, crush the crystal particles inside the slurry completely, and do not affect the density of the product after injection molding. Guarantee the quality of manufactured products.

Each direction described in the present application is a direction when the device is viewed in the same direction as in FIG.

It is a top view of the slurry processing apparatus for injection molding manufacturing technology. It is a locally enlarged view in the I direction in FIG. It is a structural drawing between a stirring shaft and a control device. It is a structural drawing between a rotary column, a driven pulley, and a polishing ball.

As shown in FIGS. 1 to 4, it is a slurry processing apparatus for injection molding manufacturing technology, and includes a stirring tub 1, and a stirring shaft 2 is connected by a bearing between the inner walls at both upper and lower ends of the stirring tub 1. The upper end of the stirring shaft 2 passes through the stirring tub 1 and is connected to the stirring motor 3, the stirring motor 3 is attached to the outer wall of the stirring tub 1 by a motor bracket, and the stirring shaft 2 is hollow. It has a structure, and the stirring shaft 2 is gradually provided with a crushing mechanism 4 and a polishing mechanism 5 from top to bottom.

The crushing mechanism 4 includes a drive ring 41 attached to the outer wall of the stirring shaft 2. The outer wall of the drive ring 41 is provided with stirring rods 42 at equal intervals along the circumferential direction, and the stirring rod 42 is provided. A stirring brush is provided at the lower end of the above, the stirring brush is attached to the filter plate 43, the filter plate 43 is provided with filtration holes at equal intervals, and the filter plate 43 adopts smoothing. The lower end of the filter plate 43 is attached to the slurry discharge plate 45 by the telescopic spring rod 44, and the slurry discharge plate 45 and the stirring shaft 2 are connected by a bearing to form the slurry. The discharge plate 45 is fixed to the inner wall of the stirring tub 1, and slurry discharge ports are provided at equal intervals in the slurry discharge holes.

A control rod 46 is provided at the upper end of the filtration plate 43, the upper end of the control rod 46 abuts on the drive ring 41, and the end surface where the drive ring 41 and the control rod 46 come into contact is curved and uneven. Make a structure. While the drive ring 41 rotates, it engages with the control rod 46 to raise and lower the filter plate 43.

Partition blocks 47 are provided at equal intervals at the lower end of the filtration plate 43, the partition blocks 47 have a T-shaped structure, the partition blocks 47 are located in the slurry discharge port, and the partition blocks 47 are located. The lower end surface of the slurry and the lower end surface of the slurry discharge port are located in the same horizontal plane. The filter plate 43 can move the partition block 47 to the lower end of the slurry discharge port while moving up and down, and the slurry flows downward from the gap between the slurry discharge port and the partition block 47. The slurry can be divided into several times and finely processed in a quantitative manner.

When the crushing mechanism 4 operates, the stirring motor 3 operates to rotate the stirring shaft 2, and the rotating stirring shaft 2 causes the stirring rod 42 to rotate and stir the slurry inside the stirring tub 1. The stirring rod 42 can avoid the occurrence of large-area solidification of the slurry and can crush large particles inside the slurry by rotating at a high speed, and the stirring brush in the stirring rod 42 can rotate the filter plate 43 during rotation. By cleaning the slurry quickly, it is possible to prevent large particles crystallized inside the slurry from blocking the filtration port, and the rotating drive ring 41 moves up and down the filtration plate 43 in cooperation with the control rod 46. While the filter plate 43 moves up and down, the partition block 47 is moved to the lower end of the slurry discharge port, and the slurry flows downward from the gap between the slurry discharge port and the partition block 47.

The polishing mechanism 5 includes a first polishing device 51 and a second polishing device 52 which are sequentially provided on the stirring shaft 2 from top to bottom, and the first polishing device 51 and the second polishing device 52 are Connected by a control device 53, the control device 53 is attached to the inner wall of the stirring shaft 2, and auxiliary devices 54 are provided at equal intervals at the lower end of the first polishing device 51, and the first polishing device 51 is provided. Includes a polishing frame 511 that is externally attached to the outer wall of the stirring shaft 2, and polishing components 512 are symmetrically provided on the inner wall of the polishing frame 511. It is attached to the rotating columns 513 between the inner walls of the above rotating columns 513 at equal intervals, a driven pulley 514 is provided in the middle of the rotating columns 513, and polishing balls 515 are provided at equal intervals on the outer wall of the rotating columns 513. The two adjacent driven pulleys 514 are connected by an interlocking belt 516, and a guide frame 517 to be combined with the polishing frame 511 is provided on the inner wall of the stirring tub 1.

The polishing frame 511 has a hollow trapezoidal structure in which the diameter gradually decreases downward, the guide frame 517 has a trapezoidal ring structure in which the diameter gradually decreases downward, and the polishing frame 511 has a lower end surface thereof. It is parallel to the upper end surface of the guide frame 517.

In the operating polishing mechanism 5, the slurry flows downward from the polishing frame 511 along the inclination direction, and the rotating stirring shaft 2 rotates the polishing frame 511 synchronously and is rotating. The polishing frame 511 cooperates with the guide frame 517, the slurry flows downward from the gap between the polishing frame 511 and the guide frame 517, and the polishing frame 511 primaryly polishes the slurry by rotary polishing, and the polishing is performed. The control device 53 operates to operate the first polishing device 51 and the second polishing device 52 at the same time, and the operating first polishing device 51 and the second polishing device 52 are in a flowing slurry. On the other hand, secondary polishing is performed by rolling polishing, and the auxiliary device 54 performs tertiary polishing by reciprocating polishing on the slurry flowing on the polishing frame 511.

The control device 53 includes a drive motor 531 attached to the inner wall of the stirring shaft 2 by a motor bracket, a control sprocket 532 is attached to the output shaft of the drive motor 531, and the inner wall of the stirring shaft 2 has a control sprocket 532. Two control shafts 533 are attached by bearings, the two control shafts 533 are symmetrically located on both the upper and lower sides of the control sprocket 532, and the stirring shaft 2 is formed with a through groove to be combined with the control shaft 533. A control pulley 534 and a driven sprocket 535 are attached to the control shaft 533, the driven sprocket 535 is connected to the control sprocket 532 by a chain 536, and a transmission belt 537 is attached to the control pulley 534. The transmission belt 537 passes through the through groove and is connected to the driven pulley 514 inside the polishing frame 511.

The drive motor 531 operates to rotate the control sprocket 532, the control sprocket 532 rotates the control shaft 533 by chain transmission, and the rotating control shaft 533 rotates the rotary column 513 by belt transmission. The rotating column 513 causes the polishing ball 515 to perform rolling type secondary polishing on the slurry flowing on the guide frame 517.

The auxiliary device 54 includes an auxiliary support 541 attached to the lower end surface of the guide frame 517, and an auxiliary kneading table 543 is connected to the outer wall of the auxiliary support 541 by a repositioning spring rod 542. Kneading balls are provided at equal intervals on the lower end surface of the 543, a repositioning groove is formed at the lower end of the auxiliary support 541, and an auxiliary rod 544 is attached to the auxiliary kneading base 543. The 544 is slidably provided in the repositioning groove, an auxiliary motor 545 is attached to the inner wall of the auxiliary support 541 by a motor bracket, and a cam 546 is provided on the auxiliary motor 545. 546 comes into contact with the auxiliary rod 544.

The lower end surface of the auxiliary kneading table 543 is parallel to the upper end surface of the polishing frame 511.

The operating auxiliary motor 545 reciprocates and retracts the auxiliary kneading table 543 by the cam 546, and the repositioning spring rod 542 performs a position regulating action and a repositioning action on the auxiliary kneading table 543 and reciprocates. The auxiliary kneading table 543 causes the kneading balls to perform reciprocating tertiary polishing on the slurry flowing on the polishing frame 511.

A slurry inlet is provided at the upper end of the stirring tub 1, and the lower end of the stirring tub 1 has a trapezoidal structure in which the diameter gradually increases from top to bottom, and the stirring tub 1 has a circumferential direction. Slurry feed ports are formed at equal intervals. The slurry after stirring and polishing flows to the bottom of the stirring tub 1 and is discharged from the slurry feeding port by the action of gravity.

Principle of operation:
First, the slurry is injected into the stirring tub 1 from the slurry feeding port.
Next, the crushing mechanism 4 completely stirs the slurry in the stirring tub, and at the same time, discharges the slurry from the slurry discharge port in a fixed quantity, and sends the slurry in a fixed quantity in several times for processing.
Finally, the polishing mechanism 5 performs primary polishing, secondary polishing, and tertiary polishing on the slurry, and the polished slurry does not contain crystallized particles, and the processed slurry is discharged from the slurry feed port.

Claims (8)

Slurry processing equipment for injection molding manufacturing technology
Including the stirring tub (1),
A stirring shaft (2) is connected by a bearing between the inner walls of the upper and lower ends of the stirring tub (1).
The upper end of the stirring shaft (2) passes through the stirring tub (1) and is connected to the stirring motor (3).
The stirring motor (3) is attached to the outer wall of the stirring tub (1) by a motor bracket.
The stirring shaft (2) has a hollow structure and has a hollow structure.
The stirring shaft (2) is gradually provided with a crushing mechanism (4) and a polishing mechanism (5) from top to bottom.
The crushing mechanism (4) includes a drive ring (41) attached to the outer wall of the stirring shaft (2).
Stirring rods (42) are provided at equal intervals along the circumferential direction on the outer wall of the drive ring (41).
A stirring brush is provided at the lower end of the stirring rod (42).
The stirring brush is attached to the filtration plate (43) and is attached to the filter plate (43).
The filtration plate (43) is provided with filtration holes at equal intervals.
The filtration plate (43) is externally attached to the stirring shaft (2) by adopting smoothing.
The lower end of the filtration plate (43) is attached to the slurry discharge plate (45) by the telescopic spring rod (44).
The slurry discharge plate (45) and the stirring shaft (2) are connected by bearings.
The slurry discharge plate (45) is fixed to the inner wall of the stirring tub (1).
Slurry discharge holes are provided at equal intervals in the slurry discharge holes.
The polishing mechanism (5) includes a first polishing device (51) and a second polishing device (52) which are sequentially provided on the stirring shaft (2) from top to bottom.
The first polishing device (51) and the second polishing device (52) are connected by a control device (53).
The control device (53) is attached to the inner wall of the stirring shaft (2).
Auxiliary devices (54) are provided at equal intervals at the lower end of the first polishing device (51).
The first polishing apparatus (51) includes a polishing frame (511) that is externally attached to the outer wall of the stirring shaft (2).
Polishing components (512) are symmetrically provided on the inner wall of the polishing frame (511).
The polishing component (512) is attached by bearings to the rotating columns (513) between the inner walls of the polishing frame (511) at equal intervals.
A driven pulley (514) is provided in the middle of the rotating column (513).
Polishing balls (515) are provided at equal intervals on the outer wall of the rotating column (513).
The two adjacent driven pulleys (514) are connected by an interlocking belt (516).
A guide frame (517) to be combined with the polishing frame (511) is provided on the inner wall of the stirring tub (1).
A slurry processing device for injection molding manufacturing technology, which is characterized in that. The control device (53) includes a drive motor (531) attached to the inner wall of the stirring shaft (2) by a motor bracket.
A control sprocket (532) is attached to the output shaft of the drive motor (531).
Two control shafts (533) are attached to the inner wall of the stirring shaft (2) by bearings.
The two control axes (533) are symmetrically located on both the upper and lower sides of the control sprocket (532).
The stirring shaft (2) is formed with a through groove to be combined with the control shaft (533).
A control pulley (534) and a driven sprocket (535) are attached to the control shaft (533).
The driven sprocket (535) is connected to the control sprocket (532) by a chain (536).
A transmission belt (537) is externally attached to the control pulley (534).
The transmission belt (537) passes through the through groove and is connected to the driven pulley (514) inside the polishing frame (511).
The slurry processing apparatus for the injection molding manufacturing technique according to claim 1. The auxiliary device (54) includes an auxiliary support (541) attached to the lower end surface of the guide frame (517).
An auxiliary kneading table (543) is connected to the outer wall of the auxiliary support (541) by a repositioning spring rod (542).
Kneading balls are provided at equal intervals on the lower end surface of the auxiliary kneading table (543).
A repositioning groove is formed at the lower end of the auxiliary support (541).
An auxiliary rod (544) is attached to the auxiliary kneading table (543).
The auxiliary rod (544) is slidably provided in the repositioning groove.
An auxiliary motor (545) is attached to the inner wall of the auxiliary support base (541) by a motor bracket.
The auxiliary motor (545) is provided with a cam (546).
The cam (546) comes into contact with the auxiliary rod (544).
The slurry processing apparatus for the injection molding manufacturing technique according to claim 1. The lower end surface of the auxiliary kneading table (543) is parallel to the upper end surface of the polishing frame (511).
The slurry processing apparatus for the injection molding manufacturing technique according to claim 3. A control rod (46) is provided at the upper end of the filtration plate (43).
The upper end of the control rod (46) abuts on the drive ring (41).
The end face in contact between the drive ring (41) and the control rod (46) has a curved uneven structure.
The slurry processing apparatus for the injection molding manufacturing technique according to claim 1. Partition blocks (47) are provided at equal intervals at the lower end of the filtration plate (43).
The partition block (47) has a T-shaped structure.
The partition block (47) is located in the slurry discharge port and is located in the slurry discharge port.
The lower end surface of the partition block (47) and the lower end surface of the slurry discharge port are located in the same horizontal plane.
The slurry processing apparatus for the injection molding manufacturing technique according to claim 1. The polishing frame (511) has a hollow trapezoidal structure in which the diameter gradually decreases downward.
The guide frame (517) has a trapezoidal ring structure in which the diameter gradually decreases downward, and the lower end surface of the polishing frame (511) is parallel to the upper end surface of the guide frame (517).
The slurry processing apparatus for the injection molding manufacturing technique according to claim 1. A slurry inlet is provided at the upper end of the stirring tub (1).
The lower end of the stirring tub (1) has a trapezoidal structure in which the diameter gradually increases from top to bottom.
In the stirring tub (1), slurry feeding ports are formed at equal intervals along the circumferential direction.
The slurry processing apparatus for the injection molding manufacturing technique according to claim 1.

Images