JPH02192523A - Cooling panel - Google Patents

Abstract

PURPOSE:To eliminate a singe dehumidifier and reduce a cost of facility by a method wherein a cooling pipe and a part of fins integral with the cooling pipe are buried in a light weight material absorbing radiation heat, air is blown by an air blower from one side of exposed fins to the exposed fins and then the air is discharged out of the other side. CONSTITUTION:A cooling pipe 11 is made such that one pipe member is bent to form a zig-zag shape and several fins 12 are arranged at an outer circumference of the cooling pipe so as to traverse a direction of the zig-zag shape of the pipe 11, Portions 12a of the fins 12 are buried in light weight mortar 13 absorbing radiation heat together with the pipe 11 and the remaining portions 12b are exposed. An outer circumference of the pipe 11 is coated with a far infra-red rays absorbing coating. The coating covers a circumference of the light weight mortar 13 absorbing the radiation heat and the entire exposed sides of the fins 12. Air is blown from one side 15a of the portions 12b of the fins exposed under an operation of an air blower 16 installed in a cover member 14 and then the blown air is discharged out of the other side 15b. Moisture formed into dew at the fins 12 is discharged by a drain hose.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a cooling panel suitable for use in body heat medium radiation cooling.

[Conventional technology]

Conventionally, in contrast to normal air heating medium cooling, there is building body heating medium radiant cooling. In other words, as shown in Fig. 4, the building frame heat medium radiant cooling
Construction of the building frame (ceiling, floor, walls, etc.) (1)
), etc., and a heat transfer liquid (refrigerant gas, cold water, antifreeze, etc.) is passed through the cooling pipe (2) from a heat source (3) to the concrete structure of the structure. J-) (1) is cooled as a thermal refrigerant, and the room is cooled by the cooling radiation effect. The humidity in the room is then reduced using a separate dehumidifier. This body heat storage uses concrete, so for example, the density is 2.2.
50kg/m', specific heat 0.2kcal/kg/℃
Therefore, the heat storage capacity of the building frame is approximately 172 times less than that of water.

Body heat transfer radiation cooling is ideal for buildings that require continuous use, for people who are weak in cooling, or for rooms that do not like air blowing out, such as hospital rooms, rooms for the elderly, etc.It is also suitable for schools, art galleries, museums, libraries, etc. where people think for long periods of time. It is also ideal for places where the building itself requires cool comfort, such as design rooms.

[Problem to be solved by the invention]

However, in conventional building body heat transfer radiation cooling, if the temperature of the building body is low, dew condenses on the surface of the building body.
It is necessary to separately install a dehumidifier in the room to reduce humidity, which is disadvantageous in that equipment costs increase.

In view of the above, an object of the present invention is to propose a cooling panel that can be used for heat medium radiation cooling of a building frame without the need for a separate dehumidifier, thereby significantly reducing equipment costs.

[Means to solve the problem]

The cooling panel (10) of the present invention is illustrated in FIGS. 1 and 2, for example.
As shown in the figure, a fin (12) is attached to a cooling pipe (11), and this cooling pipe (11) and this cooling pipe (1
Part (12a) of the fin (12) attached to 1)
is embedded in the radiant heat absorbing lightweight material (13), the remaining part (12b) of this fin (12) is exposed from the radiant heat absorbing lightweight material (13), and the surroundings of this radiant heat absorbing lightweight material (13) and this Radiant heat absorbing lightweight material (
A lid (14) is formed that covers the entire exposed side of the fin (12) of 13), and the fin (12b) is exposed from the radiant heat absorbing lightweight material (13) within the lid (14).
Send air from the - side (15a) with the blower (16),
The wind is blown out from the other side (15b) of this fin (12b).

[Effect]

According to the present invention, when a heat medium liquid is passed through the cooling pipe (11) and air is sent by the blower (16), dew condensation occurs on the exposed fins (12b), and the heat medium liquid for cooling is heated. The room is dehumidified, making a separate dehumidifier unnecessary, and the temperature of the radiant heat absorbing lightweight material (13) decreases, lowering the indoor temperature. ) absorbs the heat, producing a radiant cooling effect. In addition, the air circulation by the blower (16) creates a moderate airflow, and this airflow quickly carries away the layer of air that has become saturated with sweat evaporation on the surface of the body, and also has the effect of dissipating heat from the human body through convection. It also increases the rate of heat dissipation through radiation, increasing the sense of pleasure in the body.

〔Example〕

Hereinafter, one embodiment of the cooling panel of the present invention will be described with reference to FIGS. 1 to 3.

FIGS. 1 and 2 show an embodiment of the cooling panel of the present invention, and this cooling panel (10) has a third layer (described later) in the membrane.
It is used in combination with the building frame radiant heat absorption cooling panel (20) shown in the figure.

In Figures 1 and 2, (11) is a cooling pipe;
This cooling pipe (11) is made of, for example, copper, aluminum,
It is made of vinyl chloride or the like, and is formed by bending a length of pipe material in a meandering manner. (12
) is attached to the outer periphery of the cooling pipe (11).
), and a large number of fins arranged in parallel to cross the meandering direction of the cooling pipe (11), a part (12a) of this fin (12) is part of the cooling pipe (
11) is embedded in the radiant heat absorbing part 1 mortar (13) as a radiant heat absorbing lightweight material, and the remaining part (12b) of this fin (12) is made of radiant heat absorbing lightweight mortar (13).
13) More exposed. Furthermore, far infrared absorbing paint is applied to the outer periphery of the cooling pipe (11) so that the heat absorbed by the radiant heat absorbing lightweight mortar (13) is not reflected on the surface of the cooling pipe (11).

Both ends of this cooling pipe (11) protrude from the radiant heat absorbing lightweight mortar (13) and serve as an inlet and an outlet for a heat medium (refrigerant gas, cold water, antifreeze, etc.) passing through the inside of the cooling pipe (11).

(14) shows the surroundings of the radiant heat absorbing lightweight mortar (13) in which the cooling pipe (11) is buried together with a part (12a) of the fin (12) and the radiant heat absorbing lightweight mortar (13).
) is a lid body that covers the entire exposed side of the fin (12),
It consists of four surrounding fire-resistant plate members (14a) and a bottom fire-resistant heat insulating plate member (14b).

(16) is a blower located on one side inside the lid (14), and from the negative side (15a) of the part (12b) of the fin (12) exposed by this blower (16). Send the wind so that it comes out from the other side (15b). (17) is a hook for attachment.

In FIG. 3, reference numeral (21) denotes a cooling pipe, which is formed by bending two pipe members in a meandering manner. This cooling pipe (21) is buried in radiant heat absorbing lightweight mortar (22), and both ends of the cooling pipe (21) are buried in radiant heat absorbing lightweight mortar (22).
) protrudes from the inside of the pipe and serves as the population and outlet for the heat transfer liquid passing through the pipe. Note that an infrared absorbing material is applied to the outer periphery of the cooling pipe (21) so that the heat absorbed by the radiant heat absorbing lightweight mortar (22) is not reflected on the surface of the cooling pipe (21).

Now, when the building frame radiant heat absorption cooling panel (20) shown in Fig. 3 is attached to the ceiling or wall and the heat medium liquid is passed through the cooling pipe (21), for example, if the temperature of the heat medium liquid is 18°C, the radiant heat absorption light weight The surface of mortar (22) is 23℃ with a difference of 5℃.
becomes. According to the psychrometric diagram, if the room temperature is 28°C, the relative humidity is 83% and dew condensation will form on the surface of the radiant heat absorbing lightweight mortar (22). If this body radiant heat absorbing cooling panel (20) is used alone for cooling, dew will condense on the surface of the radiant heat absorbing lightweight mortar (22), and the air will become still, creating a layer of air saturated with evaporation of sweat on the surface of the body. This makes it difficult for sweat to evaporate, making you uncomfortable.

Therefore, the cooling panel (10) shown in FIGS. 1 and 2 is installed alongside the cooling panel (20) that absorbs radiant heat from the building structure.

That is, the cooling pipe (11) and the cooling pipe (21) are connected via a joint (not shown), so that the cooling pipe <11
) When a heat transfer liquid is passed through the inlet of the fin (
The temperature in step 12) also immediately becomes 18°C. Cooling pipe (11
) At the same time, the blower (16) is activated to send air from the - side (15a) of the exposed part (12b) of the fin (12), and from the other side (15b). Take it out and circulate the air.The room temperature is 28℃ and the humidity is 80%.
At this time, the 18°C fins (12) condense and dehumidify the room using the heat medium for cooling. However, the temperature of the surface of the radiant heat absorbing lightweight mortar (13) does not drop immediately due to the heat capacity of the radiant heat absorbing lightweight mortar (13). When the relative humidity in the room begins to decrease, the surface of the radiant heat absorbing lightweight mortar (13) also begins to decrease in temperature due to conduction heat from the buried cooling pipe (11), lowering the indoor air temperature and absorbing the radiant heat generated by humans. Radiant heat absorption lightweight mortar (13)
absorbs the heat, producing a radiant cooling effect.

In addition, the air circulation by the blower (16) creates a moderate airflow, and this airflow quickly carries away the layer of air that has become saturated with sweat evaporation on the surface of the body, and also has the effect of dissipating heat from the human body through convection. It also works to increase the rate of heat dissipation through radiation, increasing the sense of pleasure in the body. In addition,
Moisture condensed on the fins (12) is drained through a drain hose (not shown). Although one cooling panel (10) may be attached to the surface of the ceiling or wall, the building body radiant heat absorption cooling panel (20) is installed as a base, and an appropriate number of cooling panels (10) are attached to the building body radiant heat absorption cooling panel. Panel (2
0) may also be installed.

In this embodiment, the blower (16) is connected to the fins (12) of the cooling pipe (11) via the heat medium liquid for cooling.
Since the air conditioner cools the room while blowing more air and dehumidifying it, it can fully demonstrate the radiation cooling effect even with building-frame heat transfer radiation cooling, and eliminates the need for a separate dehumidifier, significantly reducing equipment costs. can be achieved.

It should be noted that the present invention is not limited to the above-described embodiments, and it goes without saying that various configurations may be made without departing from the gist of the present invention.

〔Effect of the invention〕

As described above, according to the present invention, the cooling pipe and a part of the fins integrated with the cooling pipe are buried in the radiant heat absorbing lightweight material, and the blower is inserted into the portion of the fin exposed from the radiant heat absorbing lightweight material from one side. Since the wind is sent from one side and the air is emitted from the other side, the air is cooled while dehumidifying through the cooling refrigerant liquid with an appropriate airflow, and the body heat transfer medium that fully demonstrates the radiant cooling effect. In addition to being able to use radiant cooling, there is an advantage that a separate dehumidifier is not required, and equipment costs can be significantly reduced.

[Brief explanation of the drawing]

Fig. 1 is a perspective view showing one embodiment of the cooling panel of the present invention, Fig. 2 is a vertical cross-sectional view of Fig. 1, Fig. 3 is a perspective view of a cooling panel that absorbs radiant heat from the structure, and Fig. 4 shows the heat medium radiation from the structure. It is a schematic block diagram of an air conditioner. (10) is a cooling panel, (11) is a cooling pipe, (12)
) is fin, (13) is radiant heat absorption lightweight mortar, (1
4) is a lid body, and (16) is a blower.

Claims (1)

[Claims] A fin is attached to a cooling pipe, the cooling pipe and a part of the fin attached to the cooling pipe are buried in a radiant heat absorbing lightweight material, the remaining part of the fin is exposed from the radiant heat absorbing lightweight material, and the radiant heat is A lid body is formed that covers the entire exposed side of the fins of the radiant heat absorbing lightweight material and the radiant heat absorbing lightweight material, and a blower is used to blow air from one side of the fins exposed from the radiant heat absorbing lightweight material in the lid body. ,
A cooling panel characterized in that air is blown out from the other side of the fin.