CN212408875U

CN212408875U - Heat exchanger and air conditioner

Info

Publication number: CN212408875U
Application number: CN202021134820.7U
Authority: CN
Inventors: 石田贵之; 佐藤英数
Original assignee: Kimura Kohki Co Ltd
Current assignee: Kimura Kohki Co Ltd
Priority date: 2019-07-18
Filing date: 2020-06-18
Publication date: 2021-01-26
Anticipated expiration: 2030-06-18
Also published as: EP3767188A1; AU2020205244A1; CN112240608A; CN112240608B; AU2020205244B2

Abstract

The utility model relates to a heat exchanger and possess heat exchanger's air conditioner. The heat exchanger includes a heat transfer unit configured to exchange heat between air for air conditioning and a heat exchange medium, the heat transfer unit including a flow dividing circuit configured to divide a group of heat transfer pipes through which the heat exchange medium flows into a plurality of groups and to vary a grouping ratio, and a control device configured to increase or decrease a flow rate of the heat exchange medium in a first group having a small grouping ratio among the plurality of groups in a case of a low air conditioning load.

Description

Heat exchanger and air conditioner

Technical Field

The present disclosure relates to a heat exchanger and an air conditioner including the same.

Background

For example, a heat exchanger used in an Air conditioner, such as a Fan coil unit (Fan coil unit) or an Air handling unit (Air handling unit), includes a heat conduction unit that exchanges heat between Air for Air conditioning and a heat exchange medium. For example, the heat exchanger is configured to control the capacity of cooling or heating air-conditioning air by adjusting the amount of heat exchange by increasing or decreasing the flow rate of the heat exchange medium. For example, as disclosed in japanese patent application laid-open No. 2001-280859, a heat conduction unit having a heat conduction pipe group is provided. For example, the heat transfer pipe group of the heat transfer portion is divided into two groups (groups) to lower the lower limit of the flow rate of the heat exchange medium, thereby making it possible to expand the control range of the lower limit of the capacity of the heat exchanger.

SUMMERY OF THE UTILITY MODEL

However, since the heat transfer pipe group is divided into two groups, the lower limit of the flow rate of the heat exchange medium is limited. For example, in the case of a low air conditioning load sufficient for a small amount of heat exchange (through-flow heat), the heat exchanger is excessively cooled or overheated due to its capacity, and there is a problem that the temperature difference of the heat exchange medium before and after heat exchange by heat exchange in the heat conduction unit is not constant. Therefore, there are problems of waste of energy and reduction of comfort. Accordingly, the present disclosure provides a heat exchanger and an air conditioner including the same, which can improve energy saving performance and comfort.

A heat exchanger according to an aspect of the present disclosure includes a heat transfer unit configured to exchange heat between air-conditioning air and a heat exchange medium, the heat transfer unit including a bypass circuit configured to divide a group of heat transfer pipes through which the heat exchange medium flows into a plurality of groups and to change a grouping ratio of the heat transfer pipes, and a control device configured to increase or decrease a flow rate of the heat exchange medium in a first group having a small grouping ratio among the plurality of groups in a case of a low air-conditioning load.

According to the present disclosure, energy saving and comfort can be improved.

Drawings

Fig. 1 is a perspective view showing a heat exchanger according to an embodiment;

fig. 2 is a schematic explanatory view showing one example of a cross section of the heat exchanger seen in the direction of an arrow DA in fig. 1;

fig. 3 is a schematic explanatory view showing one example of a cross section of the heat exchanger viewed in the direction of an arrow DB in fig. 1;

fig. 4 is a bottom perspective view showing an example of the structure of the air conditioner according to the embodiment;

fig. 5 is a bottom view of the air conditioner shown in fig. 4;

FIG. 6 is a sectional view taken along line VI-VI of the air conditioner shown in FIG. 5;

FIG. 7 is a sectional view VII-VII of the air conditioner shown in FIG. 6;

description of the symbols:

1 Heat conduction part

2 control device

4-shunt loop

6 heat conduction pipe group

9a, 9b valve

12 valve controller

100 heat exchanger

200 air conditioner

201 radiation unit

203 Fan

207 through hole

208 heat storage unit

209 heat conducting plate

F non-repeat region

G. Groups G1, G2

S is the conditioned space.

Detailed Description

Conventionally, a heat exchanger used in an air conditioner includes a heat conduction unit for exchanging heat between air-conditioning air and a heat exchange medium. For example, the heat exchanger is configured to control the capacity of cooling or heating air-conditioning air by adjusting the amount of heat exchange by increasing or decreasing the flow rate of the heat exchange medium. For example, as disclosed in japanese patent application laid-open No. 2001-280859, the lower limit of the flow rate of the heat exchange medium is reduced by dividing the heat transfer tube group included in the heat exchanger into two groups, and the control range of the lower limit of the capacity of the heat exchange coil of the heat exchanger can be expanded. However, when the heat transfer pipe groups are divided into two, the lower limit of the flow rate of the heat exchange medium is limited to a certain limit. For example, in a low air conditioning load region where only a small amount of heat exchange (through-flow heat) is required, the heat exchanger is excessively strong and thus overcooling or overheating occurs, and there is a problem that a temperature difference of the heat exchange medium before and after heat exchange by heat exchange of the heat exchanger is not constant. Therefore, the present inventors have intended to study a heat exchanger that improves energy saving and comfort.

Further, an air type radiation air conditioner disclosed in japanese patent application laid-open publication No. 2011-: the air conditioner includes an air supply part configured to be an air jet for cooling or heating the heat exchanger, an air inducing part configured to be an air inducing part for inducing air of the air-conditioned space by an inducing action of jet air discharged from the air supply part, and an air mixing part configured to discharge a mixed air of the jet air of the air supply part and the induced air of the air inducing part to the air-conditioned space and radiate heat of the mixed air to the air-conditioned space. The heat radiation effect and the induction reheating effect generated by the structure of the air type radiation air conditioner can realize comfortable air conditioning without air flow (draft) feeling and temperature unevenness, but the structure is complicated and the cost is increased. Accordingly, the present inventors have studied a simple air type radiation air conditioner that improves energy saving and comfort by a heat exchanger while omitting a function of inducing reheating and cooling at a blow-out temperature exceeding a dew point temperature.

Therefore, a heat exchanger according to an aspect of the present disclosure includes a heat transfer unit configured to exchange heat between air-conditioning air and a heat exchange medium, the heat transfer unit including a flow dividing circuit configured to divide a group of heat transfer pipes through which the heat exchange medium flows into a plurality of groups and to make a group ratio different, and a control device configured to increase or decrease a flow rate of the heat exchange medium in a first group having a small group ratio among the plurality of groups in a case of a low air-conditioning load.

According to the above aspect, the heat exchanger can further reduce the lower limit of the flow rate of the heat exchange medium by increasing or decreasing the flow rate of the heat exchange medium in the first group of the branch circuit under a low air conditioning load. Therefore, the control range of the capacity of the heat exchanger can be expanded toward the lower limit, and the capacity of the heat exchanger is not excessively increased even under a low air conditioning load. Therefore, energy waste and supercooling and overheating can be reduced, and energy saving and comfort can be improved.

For example, in the case where the heat exchange medium is water and the air conditioning load is low, the heat exchanger can control the temperature difference of the heat exchange medium between before and after heat exchange to be constant. Therefore, when such a heat exchanger is used in an air conditioner, the air conditioner can be operated with a small amount of water and a large temperature difference. The reduction in water amount can simplify piping and air conditioning equipment of the air conditioner, and the increase in temperature difference can save energy for a heat source device that conveys and receives water as a heat exchange medium to and from a heat exchanger and adjusts the temperature of the water.

In the heat exchanger according to one aspect of the present disclosure, a non-overlap region that does not overlap with the first group may be formed in a second group having a larger grouping ratio than the first group among the plurality of groups, as viewed in an airflow direction of the air-conditioning air passing through the heat conduction unit, and the non-overlap region may be disposed so as to sandwich the first group.

According to the above aspect, when the heat exchange medium is caused to flow through the first group without flowing through the second group during cooling of the heat exchanger, the supercooled dehumidified air passing through the first group and being supercooled and dehumidified can be reheated by the bypass air having a higher temperature than the supercooled dehumidified air passing through the non-overlap area. This makes it possible to obtain dry air without uncomfortable cool feeling. At this time, the supercooled dehumidified air is sandwiched by the bypass air so as not to escape, and mixing with the bypass air is promoted. Therefore, the supercooled dehumidified air can be reliably reheated. Therefore, even in the middle period of high humidity, air conditioning can be performed under dry airflow without cold airflow (cold draft), and the comfort is improved. Further, since a bypass valve (bypass damper) or the like for adjusting the flow rate of the bypass air is not required, it is possible to achieve low cost and compactness.

In the heat exchanger according to one aspect of the present disclosure, the first group may be a group having the smallest grouping ratio.

According to the above aspect, the heat exchanger can minimize the lower limit of the flow rate of the heat exchange medium by increasing or decreasing the flow rate of the heat exchange medium in the first group, and can expand the control range of the capacity of the heat exchanger toward the lower limit.

The heat exchanger according to an aspect of the present disclosure may further include a valve provided in each of the groups and configured to adjust a flow rate of the heat exchange medium flowing in, and a valve controller configured to control an operation of each of the valves, wherein the controller may cause the valve controller to control the valve so as to increase or decrease the flow rate of the heat exchange medium in each of the groups.

According to the above aspect, the heat exchanger can control the group through which the heat exchange medium flows and the flow rate of the heat exchange medium in the group by controlling the valve.

In the heat exchanger according to one aspect of the present disclosure, the heat transfer tube group may be formed of a plurality of elliptical tubes.

According to the above aspect, the dead water region of the heat transfer pipe group is reduced. Further, the ventilation resistance of the heat transfer pipe group is reduced, and energy saving is possible. Further, the contact area (through-flow heat) between the heat transfer pipe group and the air-conditioning air is increased, and the heat exchange efficiency is improved. Thus, for example, when the heat exchange medium is water, the air conditioner to which the heat exchanger is applied can be operated with a small amount of water and a large temperature difference without increasing (enlarging) the heat transfer area of the heat exchanger.

An air conditioner according to an aspect of the present disclosure includes: according to one aspect of the present disclosure, there is provided a heat exchanger including a radiation unit configured to radiate heat of air-conditioning air while discharging the air-conditioning air to a space to be air-conditioned, and a fan configured to send the air-conditioning air to the radiation unit.

According to the above aspect, the same effects as those of the heat exchanger according to the first aspect of the present disclosure can be obtained.

In the air conditioner according to one aspect of the present disclosure, the radiation unit may include a group of through holes that discharge the air-conditioning air into the air-conditioned space, and a heat storage unit, the heat storage unit may include a group of heat transfer plates that are arranged with a gap therebetween through which the air-conditioning air passes, and the group of heat transfer plates may be configured as follows: the air conditioning air is discharged from the through hole to the air-conditioned space by being divided, diffused, and passed in a rectified manner, and the heat of the air conditioning air is stored and radiated from the through hole to the air-conditioned space.

According to the above aspect, since the air conditioner in which the heat exchanger, the fan, and the radiation unit are integrated can be obtained, the air conditioner can be manufactured and constructed easily at low cost. The heat storage unit can be used for both heat storage and rectification of air for air conditioning, and can improve heat radiation capability and realize comfortable air conditioning without uneven air volume and uneven temperature.

(embodiment mode)

Embodiments of the present disclosure will be described below with reference to the drawings. The embodiments described below are all general or specific examples. Among the components in the embodiments described below, those not recited in the independent claims representing the uppermost concept can be described as any component. The drawings in the drawings attached to the specification are schematic and not necessarily strictly illustrated. In the drawings, substantially the same components are denoted by the same reference numerals, and description thereof may be omitted or simplified.

[ Heat exchanger ]

The structure of the heat exchanger 100 according to the embodiment will be described. The heat exchanger 100 of the present embodiment is also referred to as an air conditioning heat exchanger. Fig. 1 to 3 show an example of the structure of a heat exchanger 100 according to an embodiment. As shown in fig. 1 to 3, the heat exchanger 100 includes: a heat conduction unit 1 for cooling or heating the air-conditioning air a by exchanging heat between the air-conditioning air a and the heat exchange medium M; and a control device 2 that adjusts the amount of heat exchange between the air for air conditioning a and the heat exchange medium M. The white open arrows in the respective drawings indicate the airflow direction of the air-conditioning air a.

The heat conduction section 1 includes a fin group 3 and a shunt circuit 4. The fin group 3 includes a plurality of Plate fins (plates fin) 5, and the plurality of Plate fins 5 are arranged with gaps therebetween so that the air for air conditioning a passes therethrough. For example, the gaps between the plate fins 5 may extend in the airflow direction of the air-conditioning air a. The bypass circuit 4 is configured to divide the heat transfer tube group 6, which is a group of a plurality of heat transfer tubes through which the heat exchange medium M flows, into a plurality of groups G, and to differentiate the grouping ratio between the plurality of groups G. This makes it possible to make the heat transfer areas (heat exchange amounts) different between some or all of the groups G.

For example, as shown in fig. 2 and 3, the bypass circuit 4 divides the heat transfer pipe group 6 into groups G as follows: a first group G1 indicated by a thicker one-dot chain line; and a second group G2 which is composed of the heat conductive pipe group 6 except for the first group G1 and is indicated by a thin one-dot chain line. In the present embodiment, the bypass circuit 4 divides the heat transfer tube group 6 into 2 groups.

The first group G1 is a group with a smaller grouping ratio. The group having a smaller grouping ratio may be a group having a smaller grouping ratio than a certain group among the plurality of groups. For example, the first group G1 may be the group with the least proportion of groups. Such a group whose grouping ratio is the smallest may be single among a plurality of groups. The number of groups having the smallest grouping ratio may be only one or two or more among the plurality of groups. The second group G2 is a group with a larger proportion of groups, for example, a group with a larger proportion of groups than the first group G1. The number of such groups more than the first group G1 may be two or more in the plurality of groups.

The heat conduction pipe group 6 is formed to traverse the airflow direction of the air-conditioning air a, for example, to zigzag, and is thermally conductively connected to the plate fins 5 of the fin group 3. The straight tube portions of the heat transfer tubes constituting the heat transfer tube group 6 are preferably formed of elliptical tubes, but may be formed of circular tubes.

In addition, the above grouping ratio may be a ratio of the heat pipes. The proportion of the heat conduction pipe may be: the ratio of the total amount of the limit flow rate of the heat transfer tubes of each group to the total amount of the limit flow rate of all the heat transfer tubes, the ratio of the number of the groups to the total number of the heat transfer tubes, the ratio of the flow passage cross-sectional area of each group to the total flow passage cross-sectional area of the heat transfer tubes, the ratio of the total length of the heat transfer tubes of each group to the total length of the heat transfer tubes, the ratio of the heat transfer area of each group to the total heat transfer area such as the total surface area of the heat transfer tubes, and the ratio of the volume of each group to the total volume of the heat-exchangeable. The limit flow rate of the heat transfer pipe may be an upper limit of the flow rate of the heat exchange medium M that can flow in the heat transfer pipe.

The inlets of the heat exchange medium M of the first group G1 are connected to the first branch headers 7a in the branch headers (headers) 7. The inlet of the heat exchange medium M of the second group G2 is connected to the second branch header 7 b. Both the outlet of the heat exchange medium M of the first group G1 and the outlet of the heat exchange medium M of the second group G2 are connected to the merge header 8. Therefore, each group G of the first group G1 and the second group G2 is constituted by a group of heat transfer tubes that form continuous tubes communicating with each other through the

branch headers

7a, 7b, and the like.

The

branch headers

7a and 7b are connected to a delivery pipe 10 via

valves

9a and 9b, respectively. The merge header 8 is connected to a return pipe 11. Thus, the inlet of the heat exchange medium M of each of the first group G1 and the second group G2 communicates with the delivery pipe 10, and the outlet of the heat exchange medium M of each of the first group G1 and the second group G2 communicates with the return pipe 11. For example, heat exchange water as the heat exchange medium M flows through the supply pipe 10 and the return pipe 11, and the temperature of the heat exchange water is adjusted by a heat source such as a water chiller and a boiler, which are not shown. For example, the heat exchange water after temperature adjustment sent from the heat source unit may be circulated through the supply pipe 10, and the heat exchange water after heat exchange sent from the heat exchanger 100 to the heat source unit may be circulated through the return pipe 11.

The control device 2 includes

valves

9a and 9b that adjust the flow rate of the heat exchange medium M, and a valve controller 12 that controls the operations of the

valves

9a and 9 b. The

valves

9a and 9b may be proportional control valves capable of steplessly adjusting the flow rate (e.g., valve opening degree) and are provided on the group G of each of the branch circuits 4. The valve controller 12 controls the temperature difference before and after heat exchange of the heat exchange medium M by heat exchange in the heat conduction unit 1 to be constant by increasing or decreasing the flow rate of the heat exchange medium M in the first group G1 of the branch circuit 4 by controlling the operation of the valve 9a under a low air conditioning load.

In addition, when the load is adjusted high, the valve controller 12 controls the operation of the

valves

9a and 9b to increase and decrease the flow rate of the heat exchange medium M in all the groups G, thereby controlling the temperature difference of the heat exchange medium M before and after the heat exchange in the heat conduction unit 1 to be constant. In the case of a normal air conditioning load between the high air conditioning load and the low air conditioning load range, the valve controller 12 controls the operation of the control valve 9b to increase or decrease the flow rate of the heat exchange medium M in the second group G2, thereby controlling the temperature difference of the heat exchange medium M before and after heat exchange in the heat conduction unit 1 to be constant. Accordingly, the heat exchanger 100 can widely cope with the low water and large temperature difference operation of the air conditioner using the heat exchanger 100 from a high air conditioning load requiring the maximum heat exchange amount such as in midsummer and winter to a low air conditioning load requiring only a small heat exchange amount to be sufficient such as in middle period.

For example, a part or all of the functions of the control device 2 may be realized by a computer system (not shown) including a processor such as a CPU (Central Processing Unit), a volatile Memory such as a RAM (Random Access Memory), and a non-volatile Memory such as a ROM (Read-Only Memory). Such a function can be realized by the CPU using the RAM as a work area and executing a program stored in the ROM. Alternatively, a part or all of the functions of the control device 2 may be realized by a dedicated hardware circuit such as an electronic circuit or an integrated circuit, or may be realized by a combination of the computer system and the hardware circuit. Part or all of the functions of the valve controller 12 may be realized by a dedicated hardware circuit, or may be realized by a combination of a computer system and a hardware circuit.

As shown in fig. 2, the flow dividing circuit 4 has a plurality of non-overlapping regions F, which are regions not overlapping with the first group G1, formed in the second group G2 when viewed from the direction of the air flow of the air-conditioning air a passing through the heat conduction unit 1 (the direction of white open arrows in fig. 2). The plurality of non-overlapping regions F are arranged so as to sandwich the first group G1.

[ air-conditioner ]

The structure of the air conditioner 200 of the embodiment will be described. Fig. 4 is a bottom perspective view showing an example of the structure of the air conditioner 200 according to the embodiment. Fig. 5 is a bottom view of the air conditioner 200 shown in fig. 4. Fig. 6 is a sectional view VI-VI of the air conditioner 200 shown in fig. 5. Fig. 7 is a VII-VII sectional view of the air conditioner 200 shown in fig. 6. In the present embodiment, the air conditioner 200 is an air-type radiation air conditioner including the heat exchanger 100 of the embodiment, and is described below.

As shown in fig. 4 to 7, the air conditioner 200 includes: a radiation unit 201 that radiates heat of the air-conditioning air while discharging the air-conditioning air to the air-conditioned space S; a heat exchanger 100 for exchanging heat between the outside air, the return air, or a mixture thereof as air for air conditioning and a heat exchange medium; and a fan 203 that sends air for air conditioning to the radiation unit 201. The air conditioner 200 includes a drain pan 204, a casing 205, and the control device 2. The case 205 accommodates the radiation unit 201, the heat exchanger 100, the fan 203, and the drain pan 204. The air conditioner 200 is provided on a ceiling CB or the like of the air-conditioned space S in a state where the bottom surface of the radiation unit 201 is exposed to the air-conditioned space S. The arrows of the thick broken lines in fig. 4 to 7 indicate the flow direction of the air-conditioning air.

The radiation unit 201 includes a chamber 212 through which air for air conditioning flows, a group of through holes 207 formed in the bottom of the chamber 212, and a heat storage unit 208 provided in the chamber 212. The heat storage unit 208 includes a group of heat transfer plates 209 that can store heat of the air-conditioning air that comes into contact therewith and radiate the heat from the through-holes 207 to the air-conditioned space S. The group of heat transfer plates 209 is disposed with a gap for air-conditioning air to pass through. The group of heat transfer plates 209 is configured to allow air-conditioning air to flow separately, diffuse, and flow in a rectified manner, and to be discharged from the through-holes 207 to the air-conditioned space S. The heat of the air-conditioning air is thermally conducted to the group of heat-conducting plates 209, and the conducted heat is radiated from the group of heat-conducting plates 209 to the air-conditioned space S through the group of through-holes 207.

The housing 205 has a return air inlet 210 and an outer air inlet 211. The return air inlet portion 210 is configured to suck air (return air) in the conditioned space S through a ceiling cavity T formed by a ceiling partition and an unillustrated duct or the like. The outside air inlet 211 is configured to take in outside air, and is connected to the outside through a duct 223.

The fan 203 blows the return air sucked from the return air inlet portion 210 and the outside air sucked from the outside air inlet portion 211, passes the return air and the outside air through the heat exchanger 100, and reaches the radiation unit 201.

The heat exchanger 100 may have: a structure for exchanging heat between cold water or warm water as a heat exchange medium and air for air conditioning; a structure for exchanging heat between a refrigerant such as freon as a heat exchange medium and air for air conditioning; alternatively, the air conditioning system may be configured to exchange heat between another heat exchange medium and the air for air conditioning. The heat exchanger 100 cools or heats the air-conditioning air by exchanging heat between the air-conditioning air and the heat exchange medium.

The control device 2 includes:

valves

9a and 9b that regulate the flow rate of the heat exchange medium flowing into the heat exchanger 100; a valve controller 12 for controlling the operations of the

valves

9a and 9 b; and a temperature difference detection unit (not shown). The temperature difference detection unit detects a temperature difference before and after heat exchange of the heat exchange medium generated by heat exchange with the air-conditioning air in the heat exchanger 100, based on the temperature of the heat exchange medium flowing into the

branch headers

7a and 7b of the heat exchanger 100 and the temperature of the heat exchange medium flowing out from the merging header 8. The controller 2 controls the

valves

9a and 9b by the valve controller 12 based on the detected temperature difference before and after heat exchange of the heat exchange medium, and increases or decreases the flow rate of the heat exchange medium in each group G of the heat transfer pipe group 6 in each air conditioning load in the same manner as the above control.

(other embodiment)

The embodiments of the present disclosure have been described above, but the present disclosure is not limited to the above embodiments. That is, various modifications and improvements can be made within the scope of the present disclosure. For example, various modifications can be applied to the embodiments and configurations in which the components in different embodiments are combined are included in the scope of the present disclosure.

For example, in the embodiment, as illustrated in the attached drawings, the heat transfer pipe group 6 is divided into two groups G1 and G2 as a plurality of groups G in the bypass circuit 4 of the heat exchanger 100. In addition, the grouping ratio of one of the groups G is at least free. The heat exchanger 100 may be freely configured to use a refrigerant such as an aqueous solution or freon, and other heat exchange media, in addition to water as the heat exchange medium. The heat exchange medium may be either a gas or a liquid.

Claims

1. A heat exchanger, characterized in that,

the air conditioner is provided with a heat conduction part for exchanging heat between air for air conditioning and a heat exchange medium and a control device for adjusting the heat exchange amount between the air for air conditioning and the heat exchange medium;

the heat transfer unit includes a bypass circuit configured to divide a group of heat transfer pipes through which the heat exchange medium flows into a plurality of groups and to change a grouping ratio;

the controller is configured to increase or decrease the flow rate of the heat exchange medium in a first group having a small grouping ratio among the plurality of groups in the case of a low air conditioning load.

2. The heat exchanger of claim 1,

in the second group, the grouping ratio is greater than that of the first group, and non-overlapping regions that do not overlap with the first group are formed in the plurality of groups, as viewed in the air flow direction of the air-conditioning air passing through the heat conduction unit, and the non-overlapping regions are arranged so as to sandwich the first group.

3. The heat exchanger of claim 1,

the first group is the group with the least grouping proportion.

4. The heat exchanger of claim 1,

further provided with: a valve provided in each of the groups and adjusting a flow rate of the heat exchange medium flowing in; and

a valve controller for controlling the operation of each of the valves;

the control device causes the valve controller to control the valves to increase or decrease the flow rate of the heat exchange medium in each of the groups.

5. The heat exchanger of claim 1,

the heat conduction pipe group is composed of a plurality of elliptical pipes.

6. An air conditioner is characterized in that,

the disclosed device is provided with: the heat exchanger of any one of claims 1 to 5;

a radiation unit that radiates heat of the air-conditioning air while discharging the air-conditioning air to an air-conditioned space; and

and a fan for sending the air for air conditioning to the radiation unit.

7. The air conditioner according to claim 6,

the radiation unit includes a group of through holes for discharging the air-conditioning air to the air-conditioned space, and a heat storage unit;

the heat storage unit includes a group of heat transfer plates arranged with a gap therebetween through which the air-conditioning air passes;

the group of heat-conducting plates is composed of: the air conditioning air is discharged from the through hole to the air-conditioned space by being divided, diffused, and passed in a rectified manner, and the heat of the air conditioning air is stored and radiated from the through hole to the air-conditioned space.