JP6856923B2 - Radiant air conditioner - Google Patents

Description

The present invention relates to a radiant air conditioner.

In air conditioners, the blowout of cold air or hot air may directly hit people and make them feel uncomfortable. In addition, when the air conditioner is automatically turned on and off by the thermo switch, the room temperature may rise and fall accordingly, causing discomfort. Furthermore, turning on and off the air conditioner switch also causes wasteful power consumption.

On the other hand, there is an air conditioner that cools or heats a radiant panel using cold water or hot water as a heat medium. This is for cooling and heating by the cooled panel absorbing far infrared rays or the heated panel emitting far infrared rays. However, this has a problem that a water conveyance facility for introducing cold water or hot water as a heat medium is required. Further, in order for a person in the room to feel comfortable, it is necessary that not only radiant heat such as far infrared rays but also some cold and hot air come into contact with the skin, but this radiant air conditioner also has a problem that this point is lacking.

Therefore, a radiant air conditioner that cools or heats a radiant panel using cold / hot air adjusted by an air conditioner as a heat medium has been proposed. For example, in the radiant panel unit and the radiant air conditioner described in Patent Document 1, the radiant panel is suspended from the ceiling, and the space between the radiant panel and the ceiling is used as an air passage as a heat medium. Alternatively, a vertical radiant panel may be attached at a certain distance from the wall, and the space between the radiant panel and the wall may be used as an air passage as a heat medium.

The radiant panel is provided with a large number of slit holes, and the cold and hot air blown out from the air conditioner is discharged into the room through the large number of slit holes provided in the panel while cooling or heating the radiant panel. The air released into the room is taken into the air conditioner again. Such an air conditioner does not require a pipe for introducing cold water or hot water, and the man-hours for installation at the site are reduced. In addition, the device also has the ability for cold and hot air to come into contact with the skin.

Further, Patent Document 2 describes a radiant type heating / cooling device having a configuration in which a radiant panel and an air passage are integrated into a duct with a radiant panel. The device has a long duct structure in which three sides are heat-insulating walls and the other one is a radiant panel made of aluminum. Further, in this device, a vertical aluminum heat transfer member is provided on the air passage side of the radiant panel. This is a structure provided for the purpose of efficiently exchanging heat with the radiant panel, rather than simply passing the cold and hot air through the air passage. This duct structure with a radiation panel can also be installed on the ceiling or on a vertical wall.

Japanese Unexamined Patent Publication No. 2013-190183 Japanese Unexamined Patent Publication No. 2012-225517

By the way, Patent Document 1 has the following problems. That is, on-site man-hours are required in which the frame is passed to the ceiling or wall in a grid pattern, fixtures are attached, and the radiation panel is suspended from the frame. Therefore, there is a demand to further reduce the man-hours at the site. In addition, since the radiant air conditioner has many slit holes in the radiant panel, when it is installed vertically on the wall, cold air for cooling is released from the many slit holes located at the feet. , There is a problem that people in the room feel uncomfortable. On the other hand, the radiant heating / cooling device described in Patent Document 2 has a problem that it is not possible to obtain the comfort that some cold / hot air touches the skin because the cold / hot air is not discharged into the room.

Therefore, the object of the present invention, that is, the technical problem to be solved, is that the hot and cold air can be released into the room while the air passage for the cold and hot air, which is a heat medium, is configured by a duct, and the cold air is generated at the feet during cooling. It is an object of the present invention to provide a radiant air conditioner for preventing emission.

Therefore, the invention of claim 1 is formed of an upper wall surface and a bottom wall surface having heat insulating properties, a pair of left and right side wall surfaces having heat insulating properties, a back wall surface having heat insulating properties, and a metal plate constituting the front wall surface. A heat medium air introduction pipe that introduces heat medium air into an air passage composed of a radiation panel, the radiation panel, the upper wall surface and the bottom wall surface, and a pair of left and right side wall surfaces and the back wall surface. A discharge hole for discharging the heat medium air is provided on at least one of the left and right side wall surfaces, and the air passage is a space connected to the heat medium air discharge hole for discharge. The heat medium air has a pair of left and right discharge air passage walls that are partitioned between the air passage and the heat exchange air passage, which is a space connected to the heat medium air introduction pipe, but are partially provided with communication holes. When the introduction pipe is above the vertical center of the air passage, the communication hole is provided below the vertical center of the air passage, and the heat medium air introduction pipe is above and below the air passage. When the air passage hole is located below the central portion in the direction, the above problem is solved by using a radiant air conditioner characterized in that the communication hole is provided above the central portion in the vertical direction of the air passage. ..

According to the invention of claim 2, in the radiant air conditioner according to claim 1, as the heat medium air discharge holes, an upper discharge hole provided above the central portion in the vertical direction of the air passage and the air blower. The radiant air conditioner is characterized by having a lower discharge hole provided below the central portion in the vertical direction of the road and a blocking lid for closing the upper discharge hole or the lower discharge hole. Solved the problem.

According to the invention of claim 3, in the radiant air conditioner according to claim 1, the heat exchange air passage is used as an upper heat exchange air passage and a lower heat exchange air passage, and has a wind velocity enhancing plate that separates the upper part and the lower part. The wind velocity enhancing plate is provided with a wind velocity enhancing hole as a through hole for connecting the upper heat exchange air passage located on the upper side and the lower heat exchange air passage located on the lower side. The above problem was solved by using a type air conditioner.

The invention of claim 4 is the outer surface of the radiant panel, that is, the outer surface of the radiant air conditioner according to any one of claims 1, 2 or 3, which does not face the air passage. The above problem was solved by using a radiant air conditioner whose surface is covered with a diatomaceous earth cloth member.

The invention of claim 5 is the radiant air-conditioning apparatus according to any one of claims 1, 2, 3, and 4, wherein two or more concave or convex surfaces are formed on the surface of the radiant panel. Alternatively, the above-mentioned problems have been solved by adopting a radiant air-conditioning apparatus characterized in that unevenness is formed.

The invention of claim 6 is the radiant air-conditioning apparatus according to any one of claims 1, 2, 2, 3, and 5, wherein the radiant panel has a central portion and the air is blown. The above-mentioned problems have been solved by adopting a radiant air conditioner characterized in that it bulges toward the outside of the road.

The invention of claim 7 is supplied with the heat medium air in the radiant air conditioner according to any one of claims 1, 2, 2, 3, 4, 5, and 6. The above problem is solved by providing a radiant air conditioner having an air conditioner and a heat insulating duct connected to the air conditioner, and the heat medium air introduction pipe and the heat insulating duct are connected to each other. Settled.

In the configuration according to claim 1, heat medium air discharge holes are provided in the upper and lower portions of a pair of left and right side wall surfaces constituting the air passage of the radiant air conditioner. Since the air release holes are provided on both sides of the radiation panel, which is not a radiation panel facing the person in the room, there is an effect that the air released into the room does not directly hit the person.

Further, in the configuration according to claim 1, since the heat exchange air passage provided with the discharge air passage having the discharge hole and the heat medium air introduction path is separated by the discharge air passage wall, the heat medium There is an effect that the heat medium air introduced from the air introduction path can be prevented from being directly discharged from the discharge hole.

In the configuration according to claim 2, heat medium air discharge holes are provided in the upper part and the lower part on at least one of the left and right side wall surfaces constituting the air passage of the radiant air conditioner. A lid is also provided to close these. When cooling air is introduced into the air passage and cooled, if the discharge hole at the lower part of the side wall surface is closed with a lid, the cooled air is exclusively discharged from the discharge hole at the upper part of the side wall surface. It has the effect that cold air is not released to the feet of a person in the cooling space. Further, when heating by introducing heated air into the air passage, if the discharge hole at the upper part of the side wall surface is closed with a lid, the heated air is exclusively discharged from the discharge hole at the lower part of the side wall surface. Therefore, there is an effect that warm air is released to the feet of the person in the cooling space to realize comfortable heating.

In the configuration according to claim 3, in the heat exchange air passage, the wind velocity doubling plate and the wind velocity enhancing hole provided therein narrow the flow path of the heat medium air, so that the flow velocity of the heat medium air increases, and further. Since turbulent flow is generated in the heat medium air and is sprayed on the inside of the radiation panel, there is an effect that heat exchange is efficiently performed between the heat medium air and the radiation panel. In the invention according to claim 4, even if dew condensation occurs on the indoor surface of the radiant panel, which is the outer surface of the radiant air conditioning unit, the diatomaceous earth cloth covering this surface absorbs moisture, so that the dew condensation water seeps into the room. There is an effect that there is no. The invention according to claim 5 has the effect of increasing the surface area and increasing the radiation efficiency by providing unevenness on the surface of the radiation panel. In the invention according to claim 6, since the central portion of the radiant panel bulges slightly outward, that is, toward the indoor side, there is an effect that the surface area of the radiant panel can be increased. The invention according to claim 7 has an effect that the air conditioner can be freely expanded according to the size of the wall in the room.

Is a diagram showing a radiant air conditioner according to the first embodiment of the present invention, (A) is a perspective view of the radiant air conditioner, and (B) is a vertical sectional view. 1 is a view of the radiant air conditioner shown in FIG. 1, FIG. 1A is a cross-sectional view taken along the line X1-X1 of the radiant air conditioner shown in FIG. 1B, and FIG. 1B is the same radiant air conditioner on a wall. The perspective cross-sectional enlarged view which shows the apparatus installation structure, (C) and (D) are the vertical sectional views which show the flow of heat medium air. Is a diagram showing a radiant air conditioner according to a second embodiment of the present invention, (A) is a cross-sectional view in which the surface of the radiant panel is uneven, and (B1) is a view in which the central portion of the radiant panel is slightly outside. A cross-sectional view showing an example of bulging in (B2) is a cross-sectional view showing the bulge of (B1) exaggerated. Is a diagram of a radiant air conditioner according to a third embodiment of the present invention, (A) is a front view of the radiant air conditioner, (B) is a Y1-Y1 arrow view of (A), and (C). ) Is a diagram showing an operation example of the radiant air conditioner mainly during cooling, and (D) is a diagram showing an operation example of the radiant air conditioner mainly during heating.

[First Embodiment]
<Structure of air passage>
A first embodiment according to the radiant air conditioner of the present invention will be described with reference to FIG. FIG. 1A is a perspective view of the radiant air conditioner A, and FIG. 1B is a vertical sectional view. The radiant air conditioner A has a flat, substantially hexahedral shape. The radiant air conditioner A is installed on the wall surface of the room to be air-conditioned. An air passage 3 is formed inside the radiant air conditioner A. The air passage 3 is divided into two left and right discharge air passages 32L and 32R and a heat exchange air passage 31 sandwiched between the two left and right discharge air passages 32 by a pair of left and right discharge air passage walls 62 extending in the vertical direction. Further, the heat exchange air passage 31 is divided into an upper heat exchange air passage 311 and a lower heat exchange air passage 312 by a wind speed enhancing plate 6 described later.

A wind speed enhancing plate 6 for partitioning the heat exchange air passage 31 into the upper heat exchange air passage 311 and the lower heat exchange air passage 312 is provided near the center in the vertical direction. As shown in FIG. 1 (B), the wind speed enhancing plate 6 is provided with wind speed enhancing holes 61a, 61b, 61c and 61d, and communicates the upper heat exchange air passage 311 and the lower heat exchange air passage 312. There is.

In the radiant air conditioner A, the air cooled or heated by the air conditioner 7 (not shown) is first introduced into the upper heat exchange air passage 311 through the heat medium air introduction pipe 15. The introduced heat medium air exchanges heat with the radiation panel 21 described later. That is, when the heat medium air is cooled, the heat medium air cools the radiant panel 21 and the heat medium air itself is warmed by that amount. When the heat medium air is heated, the heat medium air heats the radiant panel 21 and the heat medium air itself is cooled by that amount. After that, the heat medium air moves to the lower heat exchange air passage 312 through the wind speed enhancing holes 61a, 61b, 61c, 61d, and also exchanges heat with the radiation panel 21.

Between the heat exchange air passage 31 and the discharge air passage wall 62 that separates the discharge air passages 32L and 32R, discharge communication ports 33L and 33R through which the heat medium air passes are provided, respectively. The heat medium air that has reached the discharge air passage 32L or the discharge air passage 32R through the discharge communication ports 33L and 33R is discharged into the room through the discharge holes 121a or 121b described later. Then, the air in the room is taken into the air conditioner 7 (not shown) and cooled or heated again.

As shown in FIG. 1 (B), when the heat medium air introduction pipe 15 is introduced into the upper heat exchange air passage 311, the discharge communication ports 33L and 33R are on the lower heat exchange air passage 312 side, in particular. It is provided below. Further, unlike FIG. 1B, when the heat medium air introduction pipe 15 is introduced into the lower heat exchange air passage 312, the discharge communication ports 33L and 33R are on the upper heat exchange air passage 311 side. Especially provided above. With such a configuration, it is possible to prevent the heat medium air introduced from the heat medium air introduction pipe 15 from being directly discharged into the room without patrolling the air passage 3.

The air passage 3 of the radiant air conditioner A includes an upper wall surface 11, a bottom wall surface 13, a pair of left and right side wall surfaces 12, 12, and a wall surface orthogonal to the side wall surface 12, the back wall surface 14, and the interior. The front wall surface 2 facing the surface forms a flat, substantially hexahedron. Of these wall surfaces, the upper wall surface 11, the bottom wall surface 13, the side wall surface 12, and the back wall surface 14 are formed of heat insulating members. These may be formed of, for example, vinyl chloride resin, or may be formed by spray-painting a heat insulating member on the surface after molding with a metal plate.

That is, up to 5 of the 6 surfaces of the radiant air conditioner A have heat insulating properties. The radiant air conditioner A is installed so that the back wall surface 14 is along the wall in the room. In the example of FIG. 1, the heat medium air introduction pipe 15 for introducing cooled or heated air from an air conditioner (not shown) is bent upward at 90 degrees and then provided on the upper wall surface 11.

<Discharge hole>
Further, the left and right side wall surfaces 12 are provided with discharge holes 121 on at least one of the both side surfaces. The discharge holes 121 include an upper discharge hole 121a and a lower discharge hole 121b. The upper discharge hole 121a is provided above the side wall surface 12, and discharges the heat medium air in the air passage 3 upward in the room. On the other hand, the lower discharge hole 121b is provided below the side wall surface 12, and discharges the heat medium air in the air passage 3 to the lower part of the room. In either case, the heat medium air introduced into the air passage 3 through the heat medium air introduction pipe 15 circulates in the upper heat exchange air passage 311 and the lower heat exchange air passage 312, and then is discharged into the room.

Next, the cross-sectional structure of the radiant air conditioner A will be described with reference to FIG. 2 (A). FIG. 2A is a cross-sectional view taken along the line X1-X1 of the radiant air conditioner shown in FIG. 1B. The front wall surface 2 has a two-layer structure including a diatomaceous earth cloth 23 and a radiation panel 21 from the side facing the room. The side wall surfaces 12 and 12 and the back wall surface 14 are formed of a heat insulating member such as vinyl chloride. The upper wall surface 11 and the bottom wall surface 13 are also formed of a heat insulating member such as vinyl chloride. The radiation panel 21 is made of, for example, a metal plate such as aluminum. Further, the side wall surfaces 12 and 12, the back wall surface 14, the upper wall surface 11 and the bottom wall surface 13 may be molded with a metal such as aluminum, and then a heat insulating member may be applied to the surfaces thereof.

The heat medium air introduced into the air passage 3 from the heat medium air introduction pipe 15 circulates in the upper heat exchange air passage 311 and the lower heat exchange air passage 312 to cool or heat the radiation panel 21, that is, the radiation panel. Heat exchange with 21. After that, the heat medium air is discharged into the room from the upper discharge hole 121a or the lower discharge hole 121b facing the discharge air passages 32L and 32R.

As described above, the heat exchange air passage 31 and the discharge air passages 32L and 32R are separated by the discharge air passage wall 62. Since the upper discharge hole 121a and the lower discharge hole 121b are provided on both sides of the radiation panel 21, there is an effect that the air discharged from the upper discharge hole 121a and the lower discharge hole 121b do not directly hit the person. In order to obtain such an effect, as long as the discharge hole is on the side wall surface 12, it is not always necessary that the upper discharge hole 121a and the lower discharge hole 121b are provided separately in the upper and lower parts.

<Release blocking lid>
Further, the upper discharge hole 121a and the lower discharge hole 121b are provided with a discharge blocking lid 5 that alternately opens and closes them. As shown in FIGS. 2C and 2D, the handle 51 is provided on the elongated lid 52 along the side wall surface 12. The handle 51 is an operation unit operated by the user, and the user can slide the handle 51 up and down along the slide groove 122. For example, if it is slid upward, the lid 52 moves upward. Then, the upper part of the lid 52 is closed by covering the upper discharge hole 121a. At the same time, the lower portion of the lid 52 is separated from the lower discharge hole 121b and opened.

On the other hand, if it is slid downward, the lid 52 moves downward to open the upper discharge hole 121a and close the lower discharge hole 121b. In order to stop the lid 52 at a predetermined position, for example, a screw structure may be provided at the connecting portion between the handle 51 and the lid 52. In this way, when the handle 51 is turned clockwise by a predetermined angle, the lid 52 is tightened and fixed at that position, and when the handle 51 is turned counterclockwise by a predetermined angle, the lid 52 is released from tightening. it can.

<Wind speed booster>
The wind speed enhancing plate 6 that partitions the air passage 3 into the upper heat exchange air passage 311 and the lower heat exchange air passage 312 is provided with, for example, circular wind speed enhancing holes 61a, 61b, 61c, 61d. The wind speed enhancing holes 61a, 61b, 61c, 61d connect the upper heat exchange air passage 311 and the lower heat exchange air passage 312 as air passages, and increase the air velocity of the heat medium air by narrowing the air passages. By this action, the radiant panel 21 is efficiently cooled or heated. The wind speed enhancing plate 6 may be a member having good thermal conductivity such as aluminum, or a member having good heat insulating property such as vinyl chloride.

<Installation on the wall surface>
Next, an example of installing the radiant air conditioner A on the indoor wall will be described with reference to FIG. 2 (B). First, the two fixtures 41 are fixed to the interior wall W with anchor bolts 43 with appropriate widths. Next, the radiant air conditioner A is installed on the fixed fixture 41 with a duct bolt 42. For example, the side wall surface 12 is provided with a large bolt hole 123 having a size that allows the duct bolt 42 to easily pass through. Through this large hole, the side wall surface 12 and the fixture 41 are tightened by the duct bolt 42.

Further, the indoor surface of the radiation panel 21 is covered with a diatomaceous earth cloth 23. The diatomaceous earth cloth is a member that absorbs moisture. With this configuration, even if dew condensation occurs on the indoor surface of the radiation panel 21, the diatomaceous earth cloth absorbs moisture, so that the dew condensation water does not seep into the room. Diatomaceous earth cloth is a wallpaper made of diatomaceous earth.

<When cooling>
Here, the cooling function of the radiant air conditioner A will be described with reference to FIG. 2 (C). When cooling the room, the handle 51 is slid downward to open the upper discharge hole 121a in advance and close the lower discharge hole 121b. Then, the air cooled by the air conditioner 7 (not shown) is sent into the heat exchange air passage 31 of the radiant air conditioner A through the heat medium air introduction pipe 15. Then, the cooled air exchanges heat with the aluminum radiant panel 21 while patrolling the upper heat exchange air passage 311 and the lower heat exchange air passage 312. That is, the cooled air is gradually warmed, while the radiant panel 21 is cooled.

The cooled radiation panel 21 is installed on the wall of the indoor wall, and absorbs far infrared rays emitted by the indoor wall or a person in the room. By this action, far-infrared rays coming from the walls of the room can be significantly reduced, and the heat can be prevented from being felt. People are constantly emitting far infrared rays in all directions, and also toward the walls in the room. In such a situation, if you receive heat radiation from the wall side by far infrared rays, or if the heat radiation emitted by you is reflected by the wall and radiated toward you again, you will feel the heat. However, if the wall is cooled by the radiation panel 21, heat radiation from the wall is not received and the heat is not felt.

Further, the radiant air conditioner A according to the present invention is provided with an upper discharge hole 121a and a lower discharge hole 121b on at least one of a pair of left and right side wall surfaces 12, 12. And as mentioned above, the lower discharge hole 121b is closed. Then, the heat medium air is discharged into the room from the open upper discharge hole 121a. The air released into the room is cooled by an air conditioner, but is somewhat warmed by heat exchange in the heat exchange air passage 31. This brings quiet air fluctuations to the room. Since people are constantly dissipating heat, they are in a state of wearing the air heated by their own heat dissipation. Since this is removed by the above-mentioned quiet air fluctuation, comfortable cooling can be realized.

If the radiant air conditioner unit described in Patent Document 1 is provided on the wall, the radiant air conditioner also cools the wall and the cooled air is released into the room. However, in the device of Patent Document 1, a large number of emission holes (slits 125) are formed in the radiation panel itself. In this configuration, the cold air from the air conditioner is discharged to the lower part of the room as it is, and there is a possibility that the cold air stays near the floor. On the other hand, in the radiant air conditioner A of the present invention, by closing the lower discharge hole 121b, the air whose cooling degree is moderately loosened in the air passage 3 is discharged from the upper discharge hole 121a, so that cold air is released near the floor. It has the effect of solving the problem of convection.

<Heating function>
Next, the heating function of the radiant air conditioner A according to the first embodiment of the present invention will be described with reference to FIG. 2 (D). When heating the room, the handle 51 is slid upward to close the upper discharge hole 121a in advance, and the lower discharge hole 121b is opened. Then, the air heated by the air conditioner 7 (not shown) is sent into the heat exchange air passage 31 of the radiant air conditioner A. Then, the heated air exchanges heat with the aluminum radiant panel 21 while patrolling the upper heat exchange air passage 311 and the lower heat exchange air passage 312.

That is, the heated air is gradually cooled, while the radiant panel 21 is heated. Then, warm air is quietly discharged into the room through the lower discharge hole 121b. The heated radiant panel 21 emits far infrared rays to warm a person in the room. At the same time, the quiet fluctuation created by the released air realizes comfortable heating.

<Number of discharge holes and opening area>
As described above, the heat medium air is sent from the air conditioner 7 to the air passage 3 of the radiant air conditioner A through the heat medium air introduction pipe 15. Then, the amount sent is discharged into the room from the upper discharge hole 121a or the lower discharge hole 121b. At this time, either the upper discharge hole 121a or the lower discharge hole 121b is closed with a lid. Therefore, the number and openings of the upper discharge holes 121a and the lower discharge holes 121b, respectively, so as to secure a sufficient opening for discharging the heat medium air introduced from the heat medium air introduction pipe 15 by themselves. It is necessary to secure an area.

In the radiant air conditioner, it is possible to prevent the air conditioner air from directly hitting a person in the room. Further, there is an effect that the radiant air conditioner A can be constructed only by introducing the air of the air conditioner into the radiant air conditioner installed on the wall through the heat medium air introduction pipe. Further, since the heat medium air discharge holes are provided on the left and right side wall surfaces of the radiant air conditioner A, cold and hot air can be discharged into the room while the air passage is composed of ducts. There is an effect.

Further, the upper discharge hole 121a can be closed so that the warmed air can be discharged from the lower discharge hole 121b. By doing so, the warmed air having a light specific gravity can move upward to generate a quiet convection in the room. Further, during cooling, by closing the lower discharge hole 121b, there is an effect that cold air can be prevented from staying in the vicinity of the floor.

[Second Embodiment]
The radiant air conditioner according to the second embodiment will be described with reference to FIG. The radiant air conditioner is a radiant air conditioner in which two or more concaves, convexes or irregularities are formed on the surface of the radiant panel 21 of the radiant air conditioner according to the first embodiment as the radiant panel 21B. (Fig. 3 (A)). By performing so-called embossing on the surface as in the radiation panel 21B, the surface area is increased and the radiation efficiency of the radiation panel is improved.

Separately from this, as shown in FIG. 3 (B1), the central portion of the radiation panel 21C can be formed by slightly inflating downward. This can be seen by comparing with the horizon H. In FIG. 3 (B2), this bulge is exaggerated. With such a configuration, the radiation line 8 such as far infrared rays is diffused radially, and there is an effect of widening the range on the receiving side. As described above, the radiation panel 12B having an uneven surface and the radiation panel 21C having a slightly bulging lower center portion may be implemented separately, or both may be implemented in combination.

[Third Embodiment]
Next, a third embodiment according to the radiant air conditioner of the present invention will be described with reference to FIG. FIG. 4A is a front view of the radiant air conditioner, and FIG. 4B is an arrow view of Y1-Y1. In the radiant air conditioner, a plurality of radiant air conditioners A according to the first embodiment or the second embodiment are installed side by side on the wall surface of the room. However, it is not the release blocking lid 5 by the handle 51 and the lid 52 that can open and close the upper discharge hole 121a and the lower discharge hole 121b alternately, but the upper blocking lid that opens and closes each discharge hole individually. 5a and the lower blocking lid 5b. The upper discharge hole 121a is opened and closed by the upper blocking lid 5a, and the lower discharge hole 121b is opened and closed by the lower blocking lid 5b.

FIG. 4C is a diagram showing a state in which the upper discharge hole 121a is opened and the lower discharge hole 121b is closed by the lower blocking lid 5b. Since the heat medium air is discharged from the upper part of the room, it is in a state suitable for cooling as described above. FIG. 4D is a diagram showing a state in which the upper discharge hole 121a is closed by the upper blocking lid 5a and the lower discharge hole 121b is opened. Since the heat medium air is discharged from the lower part of the room, it is in a state suitable for heating as described above.

Heat medium air whose temperature has been adjusted by being cooled or heated by the air conditioner 7 is sent to each radiation type air conditioner A through a heat insulating duct 71 and a heat medium air introduction pipe 15. The sent heat medium air cools or heats the radiant panel 21 of the radiant air conditioner A when patrolling the upper heat exchange air passage 311 and the lower heat exchange air passage 312. After that, the heat medium air is discharged into the room through the upper discharge hole 121a or the lower discharge hole 121b. When the heat medium air released into the room cools or heats the above-mentioned radiant panel 21, the cold air or warm air is relaxed.

In this way, the air in which the cold air or the warm air is relaxed is quietly released into the room, so that the cooling and heating that is comfortable for the person in the room is realized. Combined with this, the absorption or radiation of far infrared rays by the radiation panel 21 realizes effective heating and cooling. The heat medium air released into the room is sucked into the air conditioner 7 from the air conditioner suction port 72, and is cooled or heated again. With the above configuration, the radiant air conditioner can appropriately expand the heating / cooling area according to the wall area of the room.

A ... Radiant air conditioner, W ... Interior wall, 11 ... Upper wall surface, 12 ... Side wall surface, 121 ... Discharge hole,
121a ... upper discharge hole, 121b ... lower discharge hole, 122 ... slide groove,
123 ... Large hole for bolt, 13 ... Bottom wall surface, 14 ... Back wall surface, 15 ... Heat medium air introduction pipe,
2 ... front wall surface, 21 ... radiation panel, 23 ... diatomaceous earth cloth, 3 ... air passage,
31 ... Heat exchange air passage, 311 ... Upper heat exchange air passage, 312 ... Lower heat exchange air passage,
32L, 32R ... Discharge air passage, 33L, 33R ... Discharge communication port, 41 ... Fixture,
42 ... Duct bolt, 43 ... Anchor bolt, 5 ... Discharge blocking lid, 51 ... Handle,
52 ... lid body, 5a ... upper blocking lid, 5b ... lower blocking lid, 6 ... wind speed enhancing plate,
61a, 61b, 61c, 61d ... Wind speed enhancement hole, 62 ... Blower wall for discharge, 7 ... Air conditioner,
71 ... Insulation duct, 72 ... Air conditioner inlet, 8 ... Radiation line.

Claims (7)

A radiant panel formed of a heat insulating upper wall surface and a bottom wall surface, a pair of left and right side wall surfaces having a heat insulating property, a back wall surface having a heat insulating property, and a metal plate constituting the front wall surface, and the radiant panel. A pair of left and right side wall surfaces and a pair of left and right side wall surfaces and a heat medium air introduction pipe for introducing heat medium air into an air passage composed of the upper wall surface and the bottom wall surface. A discharge hole for discharging the heat medium air is provided on at least one of the side wall surfaces.
Although the air passage is divided into a discharge air passage which is a space connected to the heat medium air discharge hole and a heat exchange air passage which is a space connected to the heat medium air introduction pipe, a communication hole is partially provided. When the heat medium air introduction pipe has a pair of left and right exhaust air passage walls provided above the vertical central portion of the air passage, the communication hole is the vertical central portion of the air passage. If the heat medium air introduction pipe is below the vertical center of the air passage, the communication hole is provided above the vertical center of the air passage. A radiant air conditioner characterized by this. In the radiant air conditioner according to claim 1, as the heat medium air discharge holes, an upper discharge hole provided above the vertical center portion of the air passage and a vertical center portion of the air passage. A radiant air conditioner having a lower discharge hole provided at the lower portion and a blocking lid for closing the upper discharge hole or the lower discharge hole. In radiant air-conditioning apparatus according to claim 1, comprising a wind speed enhancement plate that partitions the upper and lower the heat exchange air flow passage as the upper heat exchange air passage and the lower heat exchange air flow passage, the該風speed enhancement plate, the upper A radiant air conditioner characterized in that a wind velocity enhancing hole is provided as a through hole for connecting the upper heat exchange air passage located in the above and the lower heat exchange air passage located below. In the radiant air conditioner according to any one of claims 1, 2, or 3, the outer surface of the radiant panel, that is, the outer surface not facing the air passage is covered with a diatomaceous earth cloth member. A radiant air conditioner characterized by being damaged. In the radiant air conditioner according to any one of claims 1, 2, 3, and 4, two or more concaves, convexes, or irregularities are formed on the surface of the radiant panel. A radiant air conditioner characterized by this. In the radiant air-conditioning apparatus according to any one of claims 1, 2, 3, 3, 4, and 5, the central portion of the radiant panel bulges toward the outside of the air passage. A radiant air conditioner characterized by being in the air. In the radiant air conditioner according to any one of claims 1, 2, 3, 3, 4, 5, and 6, the air conditioner that supplies the heat medium air and the air conditioner. A radiant air conditioner having a connected heat insulating duct, wherein the heat medium air introduction pipe and the heat insulating duct are connected to each other.

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