JPH0213207B2 - - Google Patents

Abstract

PURPOSE:To form a heat exchanger panel whose formation of a flow path of a heating medium is easy and heating medium does not leak out of the flow path, by forming the flow path of the heating medium by making a sealing material of a section joining between the sections of a panel body cut to several pieces into a partition. CONSTITUTION:The inside of a panel body 1 is formed into a space 2 through which a heating medium flows. The circumference of the space 2 is sealed with a sealing material 3 of the circumference. The panel body 1 is cut into two, and flow path of the heating medium is formed by a method wherein a sealing material 4 of a section having an I-shaped section and joining between the cut sections is made into a patition of the space 2. Enclosing components 5a, 5b are enclosed into both the edges of the space between the sections so that the space between the sections is covered from both the top and bottom sides. The titled panel is so constituted that one side enclosing component 5a is provided with an inflow and outflow nozzles 6a, 6b of the heating medium which are communicated respectively with the space 2 of the panel body 1. The heating medium entering through the inflow nozzle 6a follows the flow path as per arrow and flows out through the outflow nozzle 6a. Heat exchange is performed during the circulation.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field] The present invention relates to a heat exchange panel used in hot water circulation floor heating systems, other heating systems, and the like.

[Background technology]

A heat exchange panel is normally used in connection with a heat medium circulation device or the like. A heat exchange panel performs heating by exchanging heat by passing a heat medium such as hot water sent from a heat medium circulation device or the like through the panel.

In conventional heat exchange panels, upper and lower woven fabrics are arranged so that a space is formed between them through which a heat medium can flow through filaments, and a watertight resin layer is polymerized on the outer surface of each of these woven fabrics. The panel body was formed by The space through which the heat medium flows is formed by a flow path through which the heat medium circulates. Conventionally, when forming the flow path, a member of the same quality as the resin layer is applied to the necessary part of the panel body and the part is compressed with a hot press.
The woven fabric within the panel was crushed to form a barrier between the channels. However, the boundaries between the flow channels are reinforced by sewing to withstand pressure against the heat medium. When reinforcing this, there was a problem in that since the distance between the flow paths was quite long, a special sewing machine with a deep pocket to accommodate the length was required. Further, as the woven fabric in the panel, a fabric with good heat resistance is used because it comes into contact with a heat medium. Therefore, since the woven fabrics do not weld to each other, when forming the barrier between the flow channels, it is necessary to weld the outer resin layers together through the woven fabric, which makes it impossible to ensure that there is no leakage. It was difficult to form a barrier between the flow channels.

[Purpose of the invention]

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a heat exchange panel in which a flow path for a heat medium is easily formed and the heat medium does not leak out of the flow path.

[Disclosure of the invention]

In order to achieve the above object, the inventors conducted extensive studies and completed this invention.

In this invention, upper and lower woven fabrics are arranged so as to form a space in which a heat medium flows between them by means of filaments sewn together, and a watertight resin layer is polymerized on the outer surface of each of these woven fabrics to form a panel. It is a heat exchange panel in which a main body is formed, and the periphery of the space is sealed with a peripheral sealing material, and the cross-sectional sealing material that joins the cross sections of the panel main body, which is divided into several parts, is frequently used to prevent heat transfer. The gist thereof is a heat exchange panel characterized in that a medium flow path is formed. Hereinafter, this will be explained in detail based on the drawings showing the embodiments.

As shown in FIG. 1, the inside of the panel body 1 is formed into a space 2 through which a heat medium flows. The periphery of this space 2 is sealed with a surrounding sealing material 3.
The panel main body 1 is divided into two parts, and a cross-sectional sealing material 4 having an E-shaped cross section that joins the divided cross sections serves as a boundary between the space 2 and a flow path for the heat medium. That is, the cross-section sealing material 4 is made of thermoplastic resin, and after the panel main body 1 is inserted into the recess, it is welded between the cross-sections so that both ends of the cross-sections remain as flow paths for the heat medium. . Both ends between the cross sections are enclosed by enclosing members 5a and 5b so as to cover the cross sections from both upper and lower sides. One enclosing member 5a has an inflow nozzle 6a for the heat medium.
and an outflow nozzle 6b are provided, each communicating with the space 2 of the panel body 1. The heat medium entering from the inflow nozzle 6a follows a flow path like an arrow and flows out from the outflow nozzle 6b. Heat exchange takes place during the circulation.

Next, another embodiment of the heat exchange panel according to the present invention will be described based on FIG. As shown in this figure, the inside of the panel body 11 is formed into a space 12 through which a heat medium flows. A peripheral sealing material 13 made of thermoplastic resin and having a U-shaped cross section is fitted around the space 12. Panel body 11
is divided into two parts, and for each divided cross section,
Cross-sectional sealing materials 14, 14 made of the same material and having the same shape as the peripheral sealing material 13 are fitted so that both ends of the cross-section remain. In this situation,
The two separate cross-sectional sealing materials 14, 14 are butted against each other in the direction of the arrow, and are hot-pressed simultaneously with the surrounding sealing material 13. As a result, the cross-sectional sealing material, which was originally separate, is welded and integrated by hot pressing, and the integrated cross-sectional sealing material joins the separated cross-sections of the panel main body. Furthermore, this cross-section sealing material is welded to each cross-section of the panel main body, forming a continuous flow path for the heat medium.
On the other hand, the peripheral sealing material reliably seals the periphery of the space in the heat exchange panel by heat pressing. The enclosing member shown in FIG. 1 is used for enclosing both ends of the cross section. However, the shape of the enclosing member is not limited to this.

Inside the heat exchange panel, as shown in FIG.
are arranged to form a These woven fabrics 7,
A panel body 11 is formed by polymerizing watertight resin layers 9, 9 on each outer surface of the panel 7. In the figure, 13
14 is a peripheral sealing material, and 14 is a cross-sectional sealing material. The structure of the heat exchange panel mentioned as the first example is also
It is the same as above.

By using a cross-section sealing material to close off the cross-section, the heat medium will not enter other flow paths through the cross-section sealant, that is, the heat medium will not leak out of the flow path. In addition, the cross section of the panel can be created without going through the time-consuming work of sewing.
A flow path for the heat medium can be easily formed by simply joining them using a cross-sectional sealing material using a method such as welding.

As the cross-sectional sealing material constituting the heat exchange panel according to the present invention, thermoplastic resin such as vinyl chloride is used, for example. However, it is not limited to this.

The cross-sectional sealing material and the surrounding sealing material may be made of different materials. Moreover, it is not particularly necessary that both be hot-pressed at the same time.

There are no particular restrictions on the divided shape of the panel body. For example, as shown in FIG. 4, the panel body 11 may be divided approximately diagonally. In the figure,
14 is a cross-sectional sealing material. Further, it may be divided into three or more pieces.

There are no particular restrictions on the shape of the cross-sectional sealing material. For example, as shown in Figure 5a, there is a butt-shaped structure 15 made by the same yawning process, a type 21 between the nut and tenon as shown in Figure 5d, and a flat plate-like structure as shown in Figure 5b. It may be a member 16 consisting of a member 17 and a member 18 having a convex portion 19 that serves as a barrier between flow channels, or a member 20 which is integrally molded in an E-shape from the beginning as shown in FIG. In addition, the cross-section sealing material that is separate between the panel cross-sections is
They do not necessarily have to be integrated by welding.

〔Effect of the invention〕

As described above, in the heat exchange panel according to the present invention, the upper and lower woven fabrics are arranged so as to form a space in which a heat medium flows between them by means of the filament stitched therebetween, and the outer surfaces of each of these woven fabrics are A heat exchange panel in which a watertight resin layer is polymerized to form a panel body, and the periphery of the space is sealed with a surrounding sealing material, and the cross sections of the panel body, which are divided into several parts, are joined together. The cross section of the sealing material is narrow to form a flow path for the heat medium, so the narrow section blocks the heat medium from entering, allowing the heat medium to pass through the gap and exit the flow path. The effect is that there is no leakage. In addition, the flow path for the heat medium can be formed simply by sealing the cross sections of the panel body with the cross section sealing material, so the effect that the flow path can be formed is very simple.

[Brief explanation of drawings]

FIG. 1 is an exploded perspective view showing one embodiment of the heat exchange panel according to the present invention, and FIG. 2 is a panel main body, peripheral sealing material, and cross-sectional sealing material constituting another embodiment of the heat exchange panel according to the present invention. Figure 3 is a cross-sectional view taken along line A-A' in Figure 2;
FIG. 4 is a perspective view showing a state in which the panel main body of FIG. 2 is separated from another direction and a cross-sectional sealing material and a surrounding sealing material are fitted, and FIG. 5 is a cross-sectional seal constituting the heat exchange panel according to the present invention. FIG. 3 is a side view showing various aspects of the material. 1, 11... Panel body, 2, 12... Space,
3, 13... Surrounding sealing material, 4, 14, 15, 1
6, 20, 21... Cross section sealing material, 7... Woven fabric,
8...Filament, 9...Resin layer.

Claims (1)

[Claims] 1. Upper and lower woven fabrics are arranged so as to form a space in which a heat medium flows between them by means of filaments stitched therebetween, and a watertight resin layer is polymerized on the outer surface of each of these woven fabrics. The heat exchange panel is a heat exchange panel in which the space is sealed with a surrounding sealing material, and the cross-sectional sealing material that joins the sections of the panel main body that is divided into several parts is frequently used. A heat exchange panel characterized in that a heat medium flow path is formed in a curved manner. 2. The heat exchange panel according to claim 1, wherein the cross-sectional sealing material is originally a separate body that is welded and integrated by heat pressing.