JPH10185227A - Air conditioner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the non-uniformity of room temperature and perform a temperature adjustment good for the health of a human body by providing on a ceiling a cavity into which a heat exchanging medium is inserted and forming a heat exchanger with fins protruding from a bottom surface. SOLUTION: A temperature converting unit 1 has a hollow casing 2 attached to the ceiling 20 of a room. An opening 4 is provided on a part of a top plate 3 with which the upper part of a casing 2 is covered. A duct 21 for cold air provided behind the ceiling 20 is connected through a branch duct 22 to the opening 4. On the other hand, a plurality of hollow heat exchanging pipes 6 are attached at intervals in parallel to the bottom surface of the casing 2. One or a plurality of heat radiating fins which protrude downward are formed on the bottom surfaces of the heat exchanging pipes 6. Further, films for radiating the hot heat or cold heat of the heat exchanging pipes 6 downward are formed on the bottom surfaces of the heat exchanging pipes 6 and the surfaces of the fins.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to an air conditioning system,
More specifically, the present invention relates to an air conditioner for cooling and heating mounted on a ceiling of a building.

[0002]

2. Description of the Related Art As an air conditioner used for cooling and heating a building, there is a system as shown in FIG. 4 (a) or FIG.
The system shown in FIG. 4A is an air conditioner installed in the air conditioning room 101.
A duct 103 is connected to the cold or hot air outlet 102, and the duct 103 is branched into a plurality of ducts.Branch ducts 105 are arranged on the ceiling of each room 104.
The cool or hot air sent to the room 104 through 105 is blown downward from the blowout unit 107 on the ceiling.

[0003] The blowout unit 107 has, for example, a troffer type as shown in FIG. 4 (b), and a blowout opening 108 for blowing out cold or hot air is provided on the lower surface of the blowout unit 107. In FIG. 4A, reference numeral 109 denotes a room 104 connected to the air conditioner 102 through a duct.
Is shown.

In the system shown in FIG. 5, hot or cold water whose temperature has been adjusted by a water temperature adjuster 111 such as a boiler or a refrigerator is supplied through a pipe 112 to a fan coil unit 113.
It is connected to the heat exchanger 114 inside. The fan coil unit 113 is installed near a wall in the room 110, and heats or cools the surrounding air by the heat exchanger 114 inside the fan coil unit 113. Furthermore, fan coil unit
In 113, the heated or cooled air is blown up to the room 110 through the outlet 116 by blowing air from below onto the heat exchanger 114 by the fan 115.

[0005]

By the way, as shown in FIG. 4 (a), in a structure in which a cool air or a hot air is blown from a blow unit 107 mounted on the ceiling of a room 104, the air blows out of the blow unit 107. Hot or cold air moves into the room 104 by convection. Since the heat transfer by convection has the effect of warming the vicinity of the ceiling, the temperature difference between the vicinity of the floor and the vicinity of the ceiling increases.

For this reason, a temperature difference is likely to occur between the vicinity of the ceiling and the floor of the room 104. As a result, the thermal efficiency for optimizing the temperature near the floor where the person is located is deteriorated. For such a problem, it is conceivable to increase the wind pressure blown out from the outlet 108. However, since the wind hits a person, it is not preferable that the wind pressure is large because it gives a discomfort to the person.

On the other hand, when a fan coil unit 113 as shown in FIG. 5 is used, the warm air or the cold air from the fan coil unit 113 does not directly hit a person, Warm heat (also called warm heat) or cool heat moves in the room 110 by convection, so that the temperature on the floor side tends to decrease. Moreover, room 110
When a partition or the like is present, there is a problem that the cooling and heating temperatures of a plurality of partitioned spaces become uneven.

An object of the present invention is to provide an air conditioner capable of improving the non-uniformity of the temperature in a room and controlling the temperature in a manner that is good for human health.

[0009]

[Means for Solving the Problems]

(Means) As described above, as shown in FIGS. 1 to 3, the above-described problem is caused by a heat source which is attached to a ceiling 20, has a cavity through which a heat exchange medium passes, and has a fin 6 a projecting from a bottom surface. The problem is solved by an air conditioner characterized by having an exchanger 6 and a heating / cooling device 32 that heats or cools the heat exchange medium and sends the medium to the heat exchanger 6.

In the above-mentioned air conditioning equipment, the heat exchanger 6a
A film 6b for generating radiant heat is formed on the bottom surface and the surface of the fin 6a. In the air conditioning system, the film 6b is a film that generates far infrared rays by heat. In the above-mentioned air conditioning equipment, the heat exchanger 6 is characterized in that it is disposed in the vicinity of the outlet 12 in the casing 2 having the outlet 12 for blowing cool air.

(Operation) Next, the operation of the present invention will be described. According to the present invention, in an air conditioner that heats and cools on a ceiling, fins are formed on a bottom surface of a heat exchanger that allows a heat exchange medium to pass therethrough, thereby performing heat exchange. For this reason, the radiating area by the fins increases, and the heat exchange effect from the ceiling into the room increases, thereby increasing the thermal efficiency.

Further, by forming a film for generating radiant heat on the bottom surface of the heat exchanger and the surface of the fins, the heat transfer effect by the radiation is enhanced, and the heat is diffused without being deprived of the indoor air by the wall. The entire room can be heated evenly by reflecting it on the floor or the floor, and the rise of heating and cooling is faster than the heat transfer by convection, so reduce the difference between the temperature near the ceiling and the temperature near the floor. And efficient heating or cooling can be achieved.

When the film is made of a material that generates far-infrared rays by heat, the effect of heat transfer by radiation of far-infrared rays between the heat exchanger and room air increases. In particular, when the heated medium flows into the heat exchanger, radiant heat due to far-infrared rays is radiated into the room,
It has the effect of deeply penetrating the skin of the body and warming the body core, which is beneficial for health. Films that emit far-infrared rays include ceramics such as SiO ₂ and Al ₂ O ₃ .

Therefore, there is no need to blow out strong warm air from the ceiling, and there is no discomfort to the human body during heating. Also, because it is heating and cooling from the ceiling,
Eliminates the need for conventional fan coil unit equipment,
The room can be used effectively.

[0015]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of the present invention. 1 and 2 are perspective sectional views showing a temperature conversion unit of an air conditioner according to an embodiment of the present invention. In FIG. 1, the temperature conversion unit 1 has a casing 2 having an internal cavity attached to a ceiling 20 of a room. An opening 4 is provided in a part of the top plate 3 that covers the upper part of the casing 2, and a cool air duct 21 disposed behind a ceiling 20 is connected to the opening 4 via a branch duct 22.

On the other hand, on the bottom plate 5 of the casing 2, a plurality of heat exchange pipes 6 each having a hollow inside are attached in parallel at intervals. The heat exchange pipe 6 is closed at both ends and has a cross-sectional shape as shown by a substantially arrow as shown in FIG. That is, the bottom of the heat exchange pipe 6 has a wide shape curved like a ship bottom, while the top of the heat exchange pipe 6 has a narrow shape protruding upward from the bottom.

On the bottom surface of the heat exchange pipe 6, one or more fins 6a for heat radiation protruding downward are formed. When forming a plurality of fins 6a,
Since the interval between the fins 6a is fan-shaped as it is closer to the tip, hot or cold heat spreads in a fan shape from the fins 6a, and the heat exchange efficiency by the fins 6a increases.

Further, the bottom of the heat exchange pipe 6 and the fin 6
On the surface of a, a film 6b for radiating warm or cold heat in the heat exchange pipe 6 downward is formed. As such a film 6b, for example, there is a film formed by applying and drying a substance capable of radiating far infrared rays, for example, a substance containing alumina or silicon oxide. Such a heat exchange pipe 6
Is fitted into the mounting hole 7 of the bottom plate 5 of the casing 2 from below, so that the bottom surface of the heat exchange pipe 6 and the fins 6 a are located below the bottom plate 5. Thus, the film 6b applied along the bottom surface of the heat exchange pipe 6 and the surface of the fin 6a is exposed from under the bottom plate 5. The narrow upper portion of the heat exchange pipe 6 projects above the bottom plate 5 of the casing 2, and the upper portion thereof
Is fixed to the beam 8 disposed on the upper side, thereby preventing a downward drop.

Such fins 6a and heat exchange pipes 6
Is made of a material having good heat conductivity, for example, aluminum, iron or other metals. When it is made of aluminum, it is formed by extrusion. The insides of the heat exchange pipes 6 mounted on the bottom plate 5 of the casing 2 in this way are connected in series with each other through the coil pipes 9 so that the heat exchange medium can pass through each heat exchange pipe 6 continuously. ing. Also, of the portions corresponding to both ends of the heat exchange pipes 6 connected in series, one end thereof is connected to a liquid supply pipe 10 and the other end thereof is connected to a drain pipe 11, whereby the liquid supply pipe Hot water or cold water supplied through 10 flows through each heat exchange pipe 6 in order, and is finally discharged from a drain pipe 11.

In the area of the bottom plate 5 of the casing 2 which is sandwiched between the heat exchange pipes 6, a plurality of outlets 1 are further provided.
2 is opened, and the cool air duct 21 and the branch duct 2
The wind sent through 2 is blown downward. As shown in FIG. 3, the cool air duct 21 connected to the casing 2 of the temperature conversion unit 1 passes through the back side of the ceiling 20 and the air conditioner 30 outside the room 23 as shown in FIG.
Are connected to the blower 31.

As shown in FIG. 3, the supply pipe 10 and the drain pipe 11 connected to the heat exchange pipe 6 in the temperature conversion unit 1 are connected to a heating / cooling machine 32 such as a boiler or a refrigerator, respectively. The water is circulated by a liquid supply pipe 10 and a drain pipe 11.
Therefore, the hot or cold water heated or cooled by the heating / cooling device 32 is supplied to the supply pipe 10, and the water that has passed through the heat exchange pipe 6 is collected and the water is recovered.
2 will again heat or cool. It should be noted that providing a heating mechanism using electricity in the heating / cooling device 32 and sending hot water to the heat exchange pipe 6 using the late-night power during a low-priced time zone to heat the inside of the room 23 is also effective for effective use of resources. It is valid.

Heating or cooling of each room 23 by the air-conditioning system having the above-described configuration will be described. First, when heating the room 23, the blowing of the cool air from the air conditioner 30 is stopped. Then, when the water heated by the heater / cooler 32 is sent to the heat exchange pipe 6 in the temperature conversion unit 1 through the liquid supply pipe 10, the heat exchange pipe 6 generates heat from the bottom surface and the surface of the fin 6a.
The heat transfer to the room 23 in this case is radiant heat generated by the bottom surface of the heat exchange pipe 6 and the film 6b on the surface of the fin 6a, and is transmitted below the temperature conversion unit 1.
According to the radiant heat, the temperature is directly transmitted to a person under the temperature conversion unit 1, so that the time for warming the floor of the room 23 after the hot water passes through the heat exchange pipe 6 is faster than in the case of convection. Moreover, according to the radiant heat, the temperature difference between the vicinity of the ceiling and the vicinity of the floor in the room 23 is small, and heating with high thermal efficiency can be performed. In particular, when the film is made of a material that emits a large amount of far-infrared rays by heat, a wavelength of 4 μm
Since far infrared rays of 1000 μm are radiated, there is an effect of warming up to the core of the human body.

As described above, according to the heating from the ceiling by the radiant heat, the blowing may be omitted, and the wind does not cause discomfort to humans. On the other hand, when cooling the room 23,
Cool air is sent from the air conditioner 30 through the duct 21 and the outlet 12 into the room 23. At the same time, when the water cooled by the heating / cooling device 32 is sent to the heat exchange pipe 6 in the temperature conversion unit 1 through the liquid supply pipe 10,
The heat exchange pipe 6 is connected to its bottom surface via a membrane 6b and fins 6a.
Absorbs heat from the surface. In this case, the heat transfer to the room 23 is performed by the bottom surface of the heat exchange pipe 6 and the film 6b on the surface of the fin 6a.
The radiant heat generated by the heat is transmitted to the lower part of the temperature conversion unit 1.

In the case of cooling, since the heat exchange pipe 6 is cooled by cold air without sending cold water to the heat exchange pipe 6, the inside of the room 23 is cooled by the bottom surface of the cooled heat exchange pipe 6 and the surface of the fins 6b. Since heat exchange is performed with the air, the heat conversion efficiency is increased. In the above description, the case where hot or cold water is passed through the heat exchange pipe 6 has been described. However, air, Freon gas, inert gas, and other heat exchange media may be passed.

[0025]

As described above, according to the present invention, a fin is formed on the bottom surface of a heat exchanger through which a heat exchange medium passes, in an air conditioner for heating and cooling on a ceiling, thereby providing heat exchange. Therefore, the heat dissipating area by the fins is increased, and the heat exchange effect from the ceiling to the room is increased, so that the thermal efficiency can be increased.

In addition, since a film for generating radiant heat is formed on the bottom surface of the heat exchanger and the surface of the fin,
The heat transfer effect by radiation is increased, the heat is diffused without depriving the indoor air of heat, it is reflected on the wall or floor, and the entire room can be heated evenly, heating and cooling start up quickly, ceiling The difference between the temperature near the floor and the temperature near the floor can be reduced, and efficient heating or cooling can be achieved.

When the film is formed of a material that easily generates far infrared rays, the effect of heat transfer by the radiation of far infrared rays between the heat exchanger and room air can be increased. In particular, if the heated medium is flowed into a heat exchanger,
Since the radiant heat due to the far-infrared rays is radiated into the room, it has an effect of deeply penetrating into the skin of the body and warming the core of the body, which is beneficial to health.

Therefore, there is no need to blow out strong warm air from the ceiling, and there is no discomfort to the human body during heating. Moreover, since the heating is performed from the ceiling, the conventional fan coil unit equipment is not required, and the room can be effectively utilized.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a temperature conversion unit applied to an air conditioner according to an embodiment of the present invention in a partial cross-sectional state.

FIG. 2 is a perspective cross-sectional view and a front cross-sectional view showing a part of a heat exchange pipe (heat exchanger) applied to the air conditioner of one embodiment of the present invention.

FIG. 3 is a configuration diagram illustrating an entire air conditioning system according to an embodiment of the present invention.

FIG. 4 is a configuration diagram showing a first example of a conventional air conditioner.

FIG. 5 is a configuration diagram showing a second example of a conventional air conditioner.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Temperature conversion unit 2 Casing 3 Top plate 4 Opening 5 Bottom plate 6 Heat exchange pipe (heat exchanger) 6a Fin 6b Membrane 7 Mounting hole 8 Beam 10 Liquid supply pipe 11 Drainage pipe 12 Outlet 21 Cold air duct 22 Branch duct 23 Room 30 air conditioner 31 blower 32 heating / cooling machine

Claims (4)

[Claims] 1. A heat exchanger which is mounted on a ceiling, has a cavity through which a heat exchange medium passes, and is formed by projecting fins from a bottom surface, and said heat exchange medium is heated or cooled by heating or cooling said heat exchange medium. An air conditioner comprising a heating / cooling device for sending to a heat exchanger. 2. The air conditioner according to claim 1, wherein a film that generates radiant heat is formed on the bottom surface of the heat exchanger and the surface of the fin. 3. The air conditioner according to claim 1, wherein the film is a film that generates far infrared rays by heat. 4. An air conditioner according to claim 1, wherein said heat exchanger is mounted in a casing having an outlet for blowing cold air.