JPH0233291B2 - RENZOKUKAATSUSOCHI - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] This invention is applicable to reinforcing materials such as paper, cloth, glass fiber, etc. impregnated with liquid thermosetting resin, or thermoplastic resin sheets or films. This invention relates to a continuous pressurizing device suitable for use in compression molding a laminated product.

[Prior Art] The present applicant previously proposed Japanese Patent Application No. 61-56424 as a continuous pressurizing device of this type.

FIGS. 2 and 3 are diagrams showing the configuration of the continuous pressurizing device according to this proposal. In the figure, 1a, 1
a, 1b, and 1b are drums arranged vertically with a fixed distance apart, respectively. Endless steel belts (conveyor belts) 2, 2 are hung under tension on the two sets of drums 1a, 1b.
It is driven around at the same speed up and down. The object 3 to be compressed is sandwiched between these endless steel belts 2, 2 and conveyed.

On the back side of each endless steel belt 2, that is, on the side that does not come into contact with the object 3 to be compressed, the openings of the fixed pressurizing chambers 4, 4 face each other. Fixed pressurization chamber 4
is a pressurizing chamber with a rectangular horizontal cross section, in which a pressurizing fluid 6 supplied from the outside pressurizes an object 3 to be compressed with uniform surface pressure via an endless steel belt 2. There is.

Peripheral portion 8a of housing 8 forming pressurizing chamber 4
A sealing portion 5 is formed between the belt 2 and the endless steel belt 2, and the sealing portion 5 is filled with sealing fluid 7 pushed out from the peripheral edge 8a. This prevents the pressurized fluid 6 from flowing out to the outside, and forms a gap between the endless steel belt 2 and the peripheral edge 8a due to the sealing fluid 7. Therefore, the endless steel belt 2 is transported without contacting the peripheral edge 8a. Although the seal portion 5 is drawn large in the figure for convenience of explanation, it actually has a size of about 0.1 μm to 0.1 mm.

Each of the pressurizing chambers 4 is attached to a fixed frame 10 via a plurality of ribs 9, as shown in FIG. In this way, the pressurizing chamber 4 and the fixed frame 10 are thermally connected. Note that the distance between the pressurizing chambers 4, 4 can be set and maintained at a constant distance by using a hydraulic cylinder, a connecting shaft, or the like. Further, the endless steel belt 2 is configured to circulate around the pressurizing chamber 4 and the fixed frame 10.

In such a configuration, the object 3 to be compressed is held between the endless steel belts 2 and is pressurized while being conveyed to the right in FIG. That is, the pressurizing fluid 6 injected into the pressurizing chamber 4 pressurizes the endless steel belt 2 with a uniform surface pressure while circulating within the pressurizing chamber 4, and the compressed object 3 is compressed by this force. Apply pressure with uniform surface pressure. Further, the sealing fluid 7 is filled in the sealing portion 5 to confine the pressurizing fluid 6 in the pressurizing chamber 4 and forming a gap between the peripheral edge 8a of the pressurizing chamber 4 and the endless steel belt 2. . As a result, the endless steel belt 2 is driven with almost no friction. Note that the compressed object 3 is heated or cooled by the temperature difference between the pressurizing fluid 6 and the endless steel belt 2.

According to this proposal, a sealing fluid 7 is provided between the pressurizing chamber peripheral portion 8a and the endless steel belt 2.
Since the endless steel belt 2 is transferred without contacting the fixed pressurizing chamber, excessive frictional force is not applied to the endless steel belt 2 or the pressurizing chamber 4. Therefore, the endless steel belt 2 can maintain a good polished surface for a long period of time, and extremely excellent pressure processing is possible.

[Problems to be solved by the invention] By the way, in the continuous pressurization method described above,
There are still some shortcomings as follows. That is, when pressurizing the pressurizing chamber 4 by heating or cooling it, a temperature difference occurs between the housing 8 of the pressurizing chamber 4 and the fixed frame 10, and each part of the machine is deformed due to the difference in thermal expansion. In particular, since the fixed frame 10 is usually stronger than the housing 8,
Distortion occurs in the pressurizing chamber 4. As a result, the distance between the seal portions 5 is no longer constant, and a sufficient sealing effect cannot be obtained. Further, there were other inconveniences such as wasteful loss of the sealing fluid 7.

The present invention was made against this background, and an object thereof is to provide a continuous pressurizing device that can prevent mechanical deformation due to thermal expansion.

[Means for Solving the Problems] In order to solve the above problems, the present invention includes at least a pair of pressurizing chambers whose openings face each other, and a housing forming the pressurizing chambers with a plurality of ribs. a fixed frame supported through the opening, and at least a pair of conveyor belts circulating between the openings; In a continuous pressurizing device that continuously applies pressure via the conveyor belt by pressurizing fluid supplied to a pressure chamber, a heat insulating layer is formed inside a housing forming the pressurizing chamber. Features.

[Function] According to the above configuration, heat conduction between the pressurizing chamber and the housing is suppressed. Therefore, the temperature difference between the housing and the fixed frame can be kept small. Thereby, mechanical thermal deformation caused by the temperature difference can be suppressed.

[Example] Hereinafter, an example of the present invention will be described with reference to the drawings.

FIG. 1 is a cross-sectional view showing the configuration of essential parts of a continuous pressurizing device according to an embodiment of the present invention.

This continuous pressurizing device differs from conventional continuous pressurizing devices in that a heat insulating layer 11 is formed on the inner surface of a housing 8 forming a pressurizing chamber 4. This heat insulating layer 11 is made of polytetrafluoroethylene, polyimide,
It is made of an insulating material such as wood.

According to such a configuration, the pressurizing chamber 4 and the housing 8 are thermally isolated, and mutual heat conduction is suppressed. Therefore, for example, even if the high temperature pressurizing fluid 6 is supplied to the pressurizing chamber 4 and the pressurizing chamber 4 becomes high temperature,
The housing 8 is kept at a relatively low temperature, with the temperature T1 of the fixed frame 10 and the temperature T of the housing 8
2 is maintained at a small value. Then,
Thermal deformation due to the temperature difference T2-T1 can be suppressed. As a result, the sealing effect of the seal portion 5 can be maintained well, and the sealing fluid 7 can be prevented from being wasted.

Note that the following modifications can be considered to this embodiment.

By providing a heating device or a cooling device inside the pressurizing chamber 4 for heating or cooling, or by dividing the pressurizing chamber 4 into multiple chambers and changing the temperature for each chamber, it is possible to adjust the temperature under various temperature conditions. Pressure processing can be performed with.

By using the drums 1a, 1b as heating drums or by inserting a preheating device between the drums 1a, 1b and the pressurizing chamber 4, the endless steel belt 2 and the material to be compressed 3 are preheated to achieve the desired temperature conditions. You can also get it.

The pressurizing fluid 6 may be circulated as described above, but it may also be pressurized in a sealed state without being circulated.

Instead of the endless steel belt 2, a sheet-like belt made of a material such as plastic may be used.

Furthermore, since there is less heat dissipation, the energy saving effect is excellent. Further, since the predetermined temperature is reached in a short heating time, the start-up time can be shortened and productivity can be improved.

[Effects of the Invention] As explained above, the present invention forms a heat insulating layer on the inner surface of the housing that forms the pressurized chamber, thereby reducing the temperature difference between the housing and the fixed frame that supports it. be able to. Thereby, thermal deformation of the pressurizing chamber can be suppressed, and a good sealing effect can be obtained. As a result, the pressure in the pressurizing chamber can be maintained, and the peripheral edge and the conveyor belt can be kept in a non-contact state, and the polished surface of the polished steel belt can be kept in good condition while being continuously pressurized at high pressure. Can be processed. Further, the outflow of the sealing fluid from the seal portion can be minimized.

[Brief explanation of drawings]

FIG. 1 is a side sectional view showing the configuration of essential parts of a continuous pressurizing device according to an embodiment of the present invention, FIG. 2 is a side sectional view showing the overall configuration of a conventional continuous pressurizing device, and FIG. 3 is a conventional FIG. 2 is an enlarged sectional view showing the configuration of a pressurizing section of the continuous pressurizing device. 1a, 1b...Drum, 2...Endless steel belt (conveyor belt), 3...Object to be compressed, 4
...Fixed pressurizing chamber, 5... Seal portion, 6... Pressurizing fluid, 7... Seal fluid, 8a... Peripheral portion, 9
... Cooling jacket, 10 ... Fixed frame,
11...Insulating layer.

Claims (1)

[Scope of Claims] 1. A fixed frame that supports at least a pair of pressurizing chambers with openings facing each other, a housing forming the pressurizing chambers via a plurality of ribs, and a housing that passes between the openings. and at least a pair of conveyor belts that circulate around the conveyor belt, and the compressed object that is conveyed while being sandwiched between the pair of conveyor belts is compressed by the pressurizing fluid supplied to the pressurizing chamber by the conveyor belts. What is claimed is: 1. A continuous pressurizing device that continuously pressurizes through the pressurizing chamber, characterized in that a heat insulating layer is formed inside a housing that forms the pressurizing chamber.