KR102173887B1 - Mixing means - Google Patents

Abstract

The present invention relates to a method and means for mixing a synthetic resin, and in more detail,
In the mixing method of synthetic resin, the synthetic resin is wound around a first roller; A second roller spaced apart from the first roller pressurizes the synthetic resin wound around the first roller; It is installed above the first roller, and a blade having a blade surface guides the synthetic resin wound around the first roller to both sides of the blade; Each of the plate-shaped left and right flaps 605, each of which is hinged to the left and right angle adjustment hinge shafts 604 provided at the left and right rear ends of the blade, is angularly adjusted to adjust the proper guidance of the synthetic resin.
And in the mixing means for the synthetic resin, the first roller to which the synthetic resin is wound; A second roller spaced apart from the first roller to pressurize the synthetic resin wound around the first roller; A blade having a blade surface for mixing the synthetic resin wound on the first roller and guiding the synthetic resin to both sides; Blade transfer unit for transferring the blade; Left and right angle adjustment hinge shafts 604 provided at the left and right rear ends of the blade, respectively; And a plate-shaped left and right flap 605 in which the front ends are hinged to each of the left and right angle adjustment hinge shafts 604 to perform angle adjustment.

Description

Synthetic resin mixing means {MIXING MEANS}

The present invention relates to a method and means for mixing a synthetic resin necessary for manufacturing a synthetic resin.

The synthetic resin mixing means is provided including a first roller, a second roller, a blade, and the like, and more specifically, refer to Patent No. 1076687 (2011.10.19.) illustrated on the right side of FIG. 1A. In the process of mixing materials for the production of synthetic resin, the discharged synthetic resin is wound around one of the first roller and the second roller, rotated, and the rotating synthetic resin is automatically cut with a blade and wound on the roller again. Do it.

As a direct background technology for the present invention, Patent No. 1958524 (2019.03.08.) has been previously provided. In relation to the bar exemplified in FIG. 1 looking at the contents,

Each rear end of the blade surface 601 on the left and right sides of the blade 600 is provided with angle adjustment fixing portions 600a. The configuration of the angle adjustment fixing part 600a is hinged (connected through a hinge) so that the front ends of the left and right flaps 605 taking a plate shape on each of the left and right angle adjustment hinge shafts 604 can be diffracted (rotated or refracted). So that the angle adjustment (an) is fixed to be possible. The flap 605 connected to the angle adjustment hinge shaft 604 has its rear end widened or narrowed at a predetermined angle to determine an angle adjustment (an), and an angle adjustment fixing means capable of fixing the angle.

The flap 605 takes the shape of a plate and its front end is hinged to each of the rear end corners of the left and right sides of the blade 600 through the angle adjustment hinge shaft 604, so that the body or the rear end of the flap 605 is opened to the left and right. It is possible to change the angle to be reduced or narrowed. Through this, depending on direct factors such as viscosity, temperature, properties of the synthetic resin (VR) itself or changes in the working environment, the angle adjustment (an) of the opening or narrowing angle between the left and right flaps 605 is changed or the degree of processing required for the synthetic resin. Depending on the angle adjustment (an) can be changed. The blade 600 separates the synthetic resin (VR) at an angle of a necessary degree according to the situation together with the flap 605 to which the angle adjustment (an) function is provided, and guides it appropriately.

Each adjustment and fixing means can be provided with an expansion and contraction device 607 capable of extending and contracting the length, and the expansion and contraction device 607 operates to expand and contract the length by hydraulic pressure according to the in and out (ab) of the fluid. It includes a cylinder 607a and a piston 607b sliding in the cylinder 607a. A fluid inlet 609 opened in a section of the left end body of the telescopic device 607/cylinder 607a is formed, and a flexible fluid pipe through which fluid is introduced from the outside is connected to the fluid inlet 609.

The left end of the telescopic device 607 is diffracted by being hinged to the inner body of the left flap 605 by the telescopic device hinge shaft 606, and similarly, the right end of the telescopic device 607 is hinged to the inner body of the right flap 605. It is fixed by the hinge shaft 606 of the telescopic device to be coupled. More specifically, the left end of the cylinder 607a is hinged to the left flap 605 by the expansion/contraction device hinge shaft 606 and fixed to enable diffraction, and the right end of the piston 607b inserted in the left side of the cylinder 607a is the right side. It is hinged to the flap 605 by a hinge shaft 606 of the expansion/contractor and is fixed to enable diffraction. However, the left and right sides of the drawings shown as examples may be changed.

In its operation, a method of adjusting the hydraulic pressure through the entrance (ab) of fluid from the outside or blocking the entry (ab) so that the expansion and contraction device 607 acts as an expansion and contraction (bc) in the longitudinal direction or is fixed so as not to expand or contract. As a result, the left flap 605 and the right flap 605 are pushed or pulled to each other so that the angle adjustment (an) is made, or the angle already set to the angle adjustment (an) is maintained. That is, by the longitudinal movement of the piston 607b, the entire expansion and contraction device 607 expands and contracts, and the expansion and contraction action is hinged on both ends of the expansion device 607 through the expansion and contraction hinge shafts 606. ) To take or stop the angle adjustment (an) by pushing or pulling.

However, when the pressure applied to the flap 605 is excessive or instantaneously changes, and a minute angular vibration (an2) occurs due to a minute angular change, a load is added to the expansion/contractor 607, and thus the movement of the piston 607b As the pressure of the fluid (fl) in the cylinder (607a) increases, a microfluid (f2) (fine flow) of the fluid occurs, giving vibrations and loads to the entire device, and a means to resolve this is required. A fine-angle vibration adaptation device 610 is provided for canceling and absorbing (an2) by the elastic force of the compression coil spring 613.

First, the micro-angle vibration adaptation device 610 is disposed between the extension device hinge shaft 606 and the position when the left end of the piston 607b moves all the way to the left, and partially opens the body of one side of the cylinder 607a. , A cylinder dedicated to the micro-angular vibration adaptation device 610, that is, a mini-cylinder 611, is mounted in the opened area, and a mini-piston 612, which is a dedicated piston for the micro-angle vibration adaptation device 610, is interposed on the mini-cylinder 611 (Embedded). One end of the mini-piston 612 is in contact with the fluid fl in the cylinder 607a, and the other end of the mini-piston 612 is in contact with one end of the compression coil spring 613 interposed in the mini-cylinder 611. And the other end of the compression coil spring 613 is in contact with one end of the control bar (615).

As the production work progresses, the piston 607b finely vibrates (moves) left and right in the cylinder 607a according to the fine angular vibration an2 of the flap 605, causing a microfluidic flow f2 to occur. As a result, micro-vibration ab2 of the mini-piston 612 is generated. At this time, the microscopic vibration (ab2) of the mini-piston 612 is absorbed by the compression coil spring 613 and, as a result, the synthetic resin cut while allowing a certain portion of the fine angular vibration (an2) of the flap 605 is better. It allows it to flow in the rear direction, and absorbs and cancels minute vibrations to reduce damage to the entire device installed in the frame 90 so that the entire device can flexibly and elastically adapt to this.

The present invention enables a more efficient response to a load or microscopic vibration biased toward one side that may occur in the process of automatically mixing the synthetic resin, so that the durability of the components required for the mixing means of the synthetic resin is improved. It is intended to provide a method and a means to extend more and to respond more efficiently in mixing materials.

The present invention in the mixing method of synthetic resin,

Synthetic resin is wound around the first roller; A second roller spaced apart from the first roller pressurizes the synthetic resin wound around the first roller; It is installed above the first roller, and a blade having a blade surface guides the synthetic resin wound around the first roller to both sides of the blade; It is provided to adjust the appropriate guide of the synthetic resin by adjusting the angle of the plate-shaped left and right flaps 605 to which the front ends are hinged to the left and right angle adjustment hinge shafts 604 respectively provided at the left and right rear ends of the blade.

In addition, the present invention in the mixing means of the synthetic resin,

A first roller on which a synthetic resin is wound; A second roller spaced apart from the first roller to pressurize the synthetic resin wound around the first roller; A blade having a blade surface for mixing the synthetic resin wound on the first roller and guiding the synthetic resin to both sides; Blade transfer unit for transferring the blade; Left and right angle adjustment hinge shafts 604 provided at the left and right rear ends of the blade, respectively; And a plate-shaped left and right flap 605 in which the front ends are hinged to each of the left and right angle adjustment hinge shafts 604 to perform angle adjustment.

According to the present invention, in order to perform the process of automatically mixing the synthetic resin, while operating the equipment required for the operation, it is possible to more effectively cope with the pressure or microscopic vibration biased to either side of the blade compared to the conventional one, There is an effect that the duration of the mixing means can be made longer, and the synthetic resin material can be more effectively mixed.

1 is a diagram of an embodiment of the background art.
Hereinafter, as a city related to the present invention,
2 is a perspective view from a plan view of an embodiment.
3 is a perspective view of an embodiment.
4 is a perspective view as seen from a plan view of another embodiment.
5 is a perspective view and a state diagram showing the operation as seen from the plan view of another embodiment.

Hereinafter, a detailed description will be disclosed in relation to the mixing method (construction method) and the means (equipment, apparatus) of the synthetic resin together with the examples of the accompanying drawings. First, an embodiment will be described with examples of FIGS. 2 and 3. see.

If the load is biased or acts differently on either side of the left and right sides during the work, the angle adjustment (an) of the left and right flaps 605 becomes different from each other, and the load is shifted to only one of the flaps 605 and gradually adjusts the angle. As the difference in (an) increases, a more severe load may be applied. In this case, the synthetic resin (VR) cannot be properly divided and guided to both sides at a required angle according to the situation, and even in the configuration where the blade 600 is fixed and supported, the load and vibration biased on only one side act, and the entire mechanism May cause problems in the durability of the product.

In order to prevent the above-described problem, the synchronization device 660 is configured to allow the left and right flaps 605 to have the same angle adjustment (an). The synchronization device 660 includes a synchronization connector 661, a synchronization gear 662, a synchronization piston 663, an auxiliary piston 664, and a synchronization cylinder 665, and includes an auxiliary piston 664 or a fluid inlet ( 669) may be included.

The synchronization connector 661 takes the shape of a pipe and is provided as a pair of left and right sides, and each end of each of the left and right sides is hinged (sl) so as to be directly diffracted to the body near the left and right ends of the stretching device 607 illustrated in FIG. 1. The expansion/contraction device 607 is configured (installed) so that it can be expanded and contracted, including a cylinder 607a and a piston 607b. The diagram shows a state in which one end of the right synchronization connector 661a is hinged (sl) to the body of the cylinder 607a, and one end of the left synchronization connector 661b is hinged (sl) to the body of the piston 607b. It is illustrated in And the other ends of the left and right sides of the synchronization connector 661 are hinged (s3) to the synchronization piston (663) to enable diffraction (m1a) (m1b), respectively. That is, the other end of the right synchronization connector 661a is hinged (s3) to the right side of the rear end of the synchronization piston 663, and the other end of the left synchronization connector 661b is hinged (s3) on the left side of the rear end of the synchronization piston 663. To achieve. Through the above, the expansion and contraction device 607 is not inclined to either side, but is expanded and contracted in a state maintained horizontally, and the left and right flaps 605 connected to the expansion and contraction hinge shaft 606 are relatively the same angle adjustment (an) ( It can be operated as an1)(an2).

The left and right synchronization gears 662 (662a, 662b) are provided (formed, attached, fixed, and coupled) at each other end of the left and right synchronization connector 661, so that the two synchronization gears 662 are meshed with each other (the teeth of the gears are meshed). It can be configured in a state. Accordingly, the diffraction (m1a) (mb) of the two synchronization gears 662 are completely synchronized at the same speed (m1), so that the right synchronization connector 661a connected to the right synchronization gear 662a and the left synchronization gear 662b, respectively. And as the left synchronization connector 661b can always be diffracted and unfolded at the same angle in any case, in the end, the left and right flaps 605 can be operated with completely identical angle adjustment an. In the drawing, a right synchronization gear 662a is provided at the other end of the right synchronization connector 661a, and its center is hinged (s3) to the synchronization piston 663, and the left synchronization gear 662b is at the other end of the left synchronization connector 661b. ) Is provided so that its center is hinged to the synchronization piston 663 (s3), and is illustrated in a state of being engaged with each other.

The synchronization connector 661 may be provided with a sliding expansion and contraction device (s2) in the middle of the body as necessary, and the expansion and contraction device (s2) is of the expansion and contraction device 607 consisting of a mini cylinder 611 and a mini piston 612. Composition can be cited. The expansion and contraction device (s2) of the synchronization connector (661) overcomes and adjusts the microscopic distance difference caused by the rotation radius of the rotation radius of 606 and the rotation radius by the hinge coupling (s3) of the synchronization piston (663), helping to achieve smoother refraction. Can give.

The synchronization piston 663 takes the shape of a piston and is inserted into a synchronization cylinder 665 provided in the form of a cylinder inside the rear end of the blade 600 to perform a front-rearward sliding motion (m2). In this way, since the synchronization piston 663 moves only to the front and rear sides, the right synchronization connector 661a and the left synchronization connector 661b hinged here are the same geometrical conditions as mirror reflection in relation to other components. Because it is in the same angle adjustment (an) is made. A rotation shaft that hinges (s) the other end of the right synchronization connector (661a) to the rear right of the synchronization piston (663), and hinges the other end of the left synchronization connector (661b) to the rear end of the synchronization piston (663). Are each formed.

Synchronization cylinder 665 takes a cylinder shape by digging a hole having a predetermined length in the front-rear direction in the center of the rear end of the blade 600 body. Synchronization piston 663 corresponding thereto is tightly fitted so that it can move back and forth.

On the other hand, the extension device 607 is not externally used and is built into the blade itself, and the end of the synchronization connector 661 is directly hinged to the extension device hinge shaft 606 of the flap 605, while the angle adjustment of the flap 605 Another embodiment where control is simple and direct, and thus more efficient, is illustrated in Fig. 4 below.

In FIG. 4, a fluid inlet 669 having a hole connected to the outside of the blade 600 body is formed at the front end of the synchronization cylinder 665 to guide the fluid in and out for the angle adjustment an of the flap 605. . Here, a flexible fluid pipe through which the fluid flows from the outside may be connected to the inlet of the fluid inlet 669. In the example of the drawing, the inlet of the fluid inlet 669 is provided at the rear end of the blade 600 body.

Further, one end of each of the left and right sides of the synchronization connector 661 is hinged (sl) so as to allow direct diffraction to the inside near the rear end of the left and right flaps 605. That is, the right synchronization connector 661a is directly hinged to the right flap 605, and the left synchronization connector 661b is directly hinged to the left flap 605 (slb).

Through the above, a pressure change in the synchronization cylinder 665 occurs due to the ingress (ab) of fluid from the outside, and accordingly, a sliding motion (m2) of the synchronization piston 663 in the forward and backward direction occurs, and at this time, the synchronization piston The synchronization connector 661 connected to the other end of (663) moves (moves) in the forward and backward direction along the movement (m2) of the synchronization piston 663, while the left and right flaps 605 connected to one end of the synchronization connector 661 are removed. Angle adjustment (an) of the flap 605 is made by pushing or pulling in and out. In this way, a triangle is formed with the angular adjustment hinge shaft 604, the telescopic device hinge shaft 606, and the hinge coupling (s3) as vertices, so that when the position of a vertex of one element moves, the angle of the other vertices changes. It is to perform angular adjustment (an) accordingly. That is, as the position of the hinge coupling (s3) connecting the other end of the synchronization connector 661 and the rear end of the synchronization piston 663 moves in the front and rear direction, the angle adjustment (an) is made.

In addition to the configuration of FIG. 4, another embodiment of a mixing means for a synthetic resin will be described with reference to FIG. 5.

A groove is formed in the inside of the synchronization piston 663 and the inside is emptied to take the shape of a cylinder, and the auxiliary piston 664 in the form of a corresponding piston is tightly inserted and built in, and is synchronized with the rear end of the auxiliary piston 664 A cushion member (sp) that imparts a cushion, such as a compression coil spring, is interposed between one end of the inner cylinder of the piston (663) so that the minute angular vibration (an2) can be absorbed directly from the inside of the blade 600 body. .

In the operation method, when the synchronizing piston 663 and the auxiliary piston 664 together cause a forward-rearward sliding motion (m2) due to the ingress of fluid (ab), the synchronization connector 661 connected to the synchronization piston 663 is also While moving, angle adjustment (an) of the flap 605 connected to the synchronization connector 661 is performed.

At this time, the forward and backward sliding motion m2b of the synchronization piston 663 accompanies the motion of the built-in auxiliary piston 664. On the other hand, the auxiliary piston 664 forward and backward sliding motion (m2a) may be different in detail from the forward and backward sliding motion (m2b) of the synchronization piston 663. For example, the ingress of fluid acts on the auxiliary piston 664 Even if the flap 605 is diffracted, when resistance (load, load) is acting due to factors such as weight viscosity of the synthetic resin, the cushion member sp is compressed or elongated correspondingly along the length in the front and rear direction, so that the synchronization piston ( The degrees of sliding movements (m2a, m2b) in each of the front and rear directions 663 and the auxiliary piston 664 are different from each other.

After the initial angle adjustment (an) is made in a state where there is no load and the hydraulic entry (ab) is fixed, thereafter, the fine angular vibration (an2) due to resistance applied to the flap 605 during the mixing process of the synthetic resin. ) Is all absorbed by the cushion member (sp). In other words, if the hydraulic pressure is not in or out (ab), the position of the auxiliary piston 664 in the forward and backward direction (m2a) is not performed and the position is fixed in one place. At this time, even though the position of the auxiliary piston 664 is fixed and stopped, the cushion member sp performs an expansion and contraction action, so that the microscopic sliding movement m2b of the synchronization piston 663 in the forward and backward direction corresponds to the fine angular vibration an2 ( In response), it is made elastically and effectively,

Through the above-described configuration and method, the synchronization piston 663 performs a forward-rearward sliding motion (m2) and at the same time assists the fine-angle vibration adaptation device 610 and shares the load to pursue a finer and more efficient operation. Remove the configuration of the micro-angle vibration adaptation device 610 installed in the expansion device 607, which may be cumbersome or jamming, and move it to the inside of the blade 600 so that it is not exposed to the outside. You can provide an environment.

Blade 600; Angle adjustment hinge shaft 604; Flap 605; Telescopic device hinge shaft 606; Telescopic device 607;
Synchronization device 660; Synchronization connector 661; Synchronization gear 662; Synchronization piston 663; Synchronization cylinder 665;

Claims (2)

As a mixing means for synthetic resin,
A synthetic resin is wound on a first roller, a second roller spaced apart from the first roller presses the synthetic resin wound on the first roller, and a blade installed above the first roller and having a blade surface is provided with the first roller. The synthetic resin wound on the roller is guided to both sides of the blade, and the plate-shaped left and right flaps 605 are each hinged to each of the left and right angle adjustment hinge shafts provided at the left and right rear ends of the blade, respectively, to provide proper guidance of the synthetic resin In being adjusted,
Synchronization connector taking the form of a pipe; Synchronization gears that take the form of gears; Synchronization piston taking the form of a piston; And a synchronization device consisting of;
The synchronization connector is provided as a pair of a right synchronization connector and a left synchronization connector, one end of the right synchronization connector is hinged directly to the right flap 605, and one end of the left synchronization connector is the left flap 605. ) Is directly hinged,
The synchronization gear is provided so that diffraction is synchronized with each other by engaging a pair of a right synchronization gear provided at the other end of the right synchronization connector and a left synchronization gear provided at the other end of the left synchronization connector,
The other end of the right synchronization connector is hinged on the right side of the rear end of the synchronization piston, and the other end of the left synchronization connector is hinged on the left side of the rear end of the synchronization piston,
The synchronization cylinder is provided as a groove formed in the rear end center of the blade in the front-rear direction, and the synchronization piston is closely inserted into the synchronization cylinder to perform a front-rearward sliding motion while adjusting the angle of the left and right flaps 605 Made identical to each other,
Synthetic resin mixing means, characterized in that. delete

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