KR20150088702A - Heat exchange coil and air conditioning unit - Google Patents

Abstract

Obtained are a heat exchange coil and an air conditioning unit which are compact and have an energy-saving property and pleasantness together. The heat exchange coil (2) comprises: a plurality of partitioned heat transfer pipe groups (6, 6) having a heat exchange medium flowing therein; and a plurality of partitioned pin groups (7, 7) having the partitioned heat transfer pipe groups (6, 6) inserted and mounted thereon. A control device (4) is installed to individually adjust an amount of the heat exchange medium circulating for each of the plurality of partitioned heat transfer pipe groups (6, 6). An air mixing area (10) is formed between the air entrances of the adjacent partitioned pin groups (7, 7) by separating the plurality of partitioned pin groups (7, 7) in the direction of ventilation. The air conditioning unit includes: a heat exchange coil (2); and an air blower (3) to blow ventilation air for air conditioning from an upstream side of air to the heat exchange coil (2) by pressurization.

Description

HEAT EXCHANGE COIL AND AIR CONDITIONING UNIT

The present invention relates to a heat exchange coil and an air conditioner.

The air conditioner installed in the ceiling is required to be compact in size due to space limitation and has a structure in which ventilation air for air-conditioning which is heat-exchanged in the gas is blown into the heat-exchanging coil from the air side to the press- The air flow unevenness and the heat exchange temperature fluctuation are generated in the portion facing to the heat exchanger and the heat exchanging loss is increased. In order to compensate for this, there has been a problem that the heat transfer area and the size of the heat exchange coil and the air conditioner are increased.

Japanese Patent Application Laid-Open No. 4-327726

In the four-pipe type air conditioner, cooling and heating can be freely switched. However, two cooling heat-exchanging coils for flowing cold water and a heating-only heat-exchanging coil for flowing hot water are required. Air resistance increases due to heat- There is a problem that power is increased and the air of the air conditioner is also increased in size.

In order to solve the above problems, the present invention provides a heat exchange coil for heat exchange between a heat exchange medium and ventilation air for air conditioning through a heat transfer member, wherein the heat transfer member includes a plurality of divided heat transfer tube groups in which the heat exchange medium flows, A control device is provided for individually controlling the flow rate of the heat exchange medium for each of the plurality of divided heat transfer tube groups, and a plurality of the divided pin groups are spaced apart from each other in the ventilation direction, And an air mixing area is formed between the air inlet and outlet of the split pin group so that the heat exchange medium sequentially flows from the split pin group on the windward side (on the wind downstream side) to the split pin group on the windward side And the divided heat transfer tube group is disposed.

According to the invention of claim 1,

(1) The control range of the air conditioning capability (minimum heat exchange amount of the heat exchange coil) is widened, so that energy saving and comfort at the time of low load such as the intermediate stage can be surely guaranteed.

(2) Even if airflow unevenness and heat exchange temperature fluctuation occur due to a bypass or the like in the portion facing the blower outlet of the airplane outlet port on the windward side, airflow in the air mixing area between the lower- Since the air is mixed and diffused and is uniformed and ventilated to the split pin group on the downwind side, the heat exchange loss can be reduced and the heat exchange efficiency is improved.

(3) A divided heat transfer tube group is disposed so that the heat exchange medium flows sequentially from the lower split pin group to the wind side split pin group, and the temperature difference between the heat exchange medium and the ventilation air in the divided heat transfer tube group region of the airfoil- And the temperature difference between the heat exchange medium and the ventilation air in the divided heat transfer pipe group region of the downwind side split pin group can be increased. This makes it possible to maximize the area where the heat exchange efficiency is good due to the air mixing action while minimizing the area where the heat exchange efficiency is poor due to the unevenness of the air volume and the heat exchange temperature. It is possible to save energy considerably.

According to the invention of claim 12,

(1) Even if the ventilation air is blown into the heat exchanger coil from the air side by the blower, the ventilation air is mixed and homogenized in the air mixing area between the lower side split pin group and the The heat exchange loss can be reduced.

(2) Since the heat exchange efficiency is improved because the heat exchanging loss is reduced, the heat exchanging coil and the air conditioner are made compact and can be easily installed into the ceiling with space limitation. Further, the machine room is unnecessary.

(3) It is possible to freely switch between cooling and heating with one heat and cooling coil for cooling and heating, and the blowing power can be reduced as compared with the case of using two heat exchanging coils dedicated to heating and cooling, thereby saving energy and making the air conditioner compact .

According to the invention of claim 2,

(1) By reducing the area of the divided heat transfer pipe group on the windward side from the windward side, it is possible to reduce the heat transfer area ratio of the entire coil by minimizing the area where the heat exchange efficiency is poor due to the uneven air flow rate and heat exchange temperature, This good area can be maximized and further energy saving can be achieved.

According to the invention of claim 3,

(1) Since the fin pitch on the windward side is made wider than that on the downwind side, the ratio of the heat transfer area of the entire coil can be controlled by minimizing the area where the heat exchange efficiency is poor due to uneven air flow rate and heat exchange temperature, You can maximize this good area. In addition, as the fin pitch of the downward-flow side split pin group is narrowed, the air mixing action by the air resistance is promoted, so that further energy saving can be achieved.

According to the invention of claim 4,

(1) It is possible to freely change the cooling and heating by using one heat-exchanging coil for both cooling and heating, and the blowing power can be reduced as compared with the case of using two heat-exchanging coils dedicated to heating and cooling, saving energy and making the air conditioner compact .

(2) Since the heat source number is divided into a plurality of divided heat transfer pipe groups to reduce the flow rate per divided heat transfer pipe group, the lower limit flow rate of the entire coil can be controlled by using a flow control valve having a lower lower flow rate Heat exchanger coil) can be minimized. As a result, the control range of the air-conditioning capability (minimum heat exchange amount of the heat exchange coil) is widened to prevent unnecessary heat exchange energy consumption at the time of low load such as the intermediate stage, ensuring comfort and energy saving without being too cold or too hot can do.

According to the invention of claim 8,

(1) It is possible to freely change the cooling and heating by using one heat and cooling coil for cooling and heating, and it is possible to reduce the blowing power as compared with the case of using two heat exchange coils dedicated for heating and cooling, saving energy and making the air conditioner compact have.

(2) Since the flow rate per divided heat transfer pipe group is reduced by branching the heat source water into a plurality of divided heat transfer pipe groups, the lower limit flow rate of the entire coil can be controlled by using a flow control valve having a lower lower flow rate Coil) can be minimized. As a result, the control range of the air-conditioning capability (minimum heat exchange amount of the heat exchange coil) is widened to prevent unnecessary heat exchange energy consumption at the time of low load such as the intermediate stage, ensuring comfort and energy saving without being too cold or too hot can do.

According to the invention of claim 13,

(1) It is possible to freely change the cooling and heating by using one heat and cooling coil for cooling and heating, and it is possible to reduce the blowing power as compared with the case of using two heat exchange coils dedicated for heating and cooling, saving energy and making the air conditioner compact have.

According to the invention of claims 5 and 9,

(1) Since the lower limit flow rate for each of the plurality of divided heat transfer pipe groups is set to be different (for example, 6: 4), the lower limit flow control (For example, 4 smaller than 5) can be realized, so that it is possible to reliably guarantee the load and the energy saving in response to the wider fluctuation range of the air conditioning load.

According to the invention of claim 6 and claim 10,

(1) A plurality of flow rate control valves are sequentially opened and closed to perform proportional control of the flow rate with excellent response without deflection, so that stable and comfortable air conditioning without heat exchange unevenness can be performed.

According to the invention of claims 7 and 11,

(1) Since the ventilation resistance is small, the pressure loss is reduced, and the contact area (heat transfer area) with the ventilation air of the coil is increased, so that the energy saving can be improved.

1 is a brief explanatory view showing a state where the present invention is installed on a ceiling.
2 is a perspective view showing a heat exchange coil;
3 is a brief explanatory view showing the entire configuration.
4 is an explanatory view showing an example of flow rate control.
5 is a brief explanatory view showing a state in which another embodiment of the present invention is installed on the floor.
Fig. 6 is a schematic view showing a heat-exchanging coil of the embodiment of Fig. 5;

1 to 3 show an embodiment of an air conditioner according to the present invention. The air conditioner is installed in a ceiling 30 and includes a heat exchanger coil 2, A blower 3 for blowing ventilation air for air conditioning from the windward side to the heat exchange coil 2 and a humidifier (not shown), and the like. The ventilation air for air conditioning heat-exchanged in the heat exchange coil 2 is blown It becomes cool air and is supplied to the air-conditioned space such as the room. On the other hand, white arrows in the drawings indicate the airflow direction of ventilation air for air conditioning.

The heat exchange coil 2 exchanges heat exchange medium with ventilation air through the heat transfer member 5. The heat transfer member 5 includes a plurality of divided heat transfer tube groups 6 ... in which a heat exchange medium flows, , A plurality of split pin groups (7 ...) in which split heat transfer pipe groups (6 ...) are inserted and a plurality of branching heads (7 ...) connected to the heat exchange medium inlets for each of the plurality of divided heat transfer pipe groups (8 ...) and a joining header (9) communicatively connected to the heat exchange medium outlets of all the divided heat transfer tube groups (6). It is preferable that the area of the divided heat transfer tube group 6 inserted into the split pin group 7 on the windward side is smaller than the area of the divided heat transfer tube group 6 inserted into the split pin group 7 on the downhill side , But the present invention is not limited thereto. It is preferable that the divided heat transfer tube group 6 is formed of an elliptical tube, but it may be formed as a circular tube.

The plurality of split pin groups 7 ... are spaced in the ventilation direction to form the air mixing area 10 between the air inlet and outlet of the adjoining divided pin groups 7 and 7 and the heat exchange medium is divided The divided heat transfer pipe groups 6 are arranged so as to flow sequentially from the pin group 7 to the split pin group 7 on the windward side. A plurality of plate pins 11 are juxtaposed parallel to each other at a predetermined interval and are arranged orthogonal to the plane portions of the plate pins 11 .... The divided heat transfer pipe group 6, ... are inserted and mounted in a plurality of stages or a plurality of rows. The pin pitch P of the split pin group 7 on the windward side is preferably wider than the pin pitch P of the split pin group 7 on the downwind side. Changes are possible.

The heat exchange medium is a heat source water and is connected through a pair of cold water circulation paths 12 and hot water circulation paths 13 through which heat exchange medium flows and three branching directional valves 14 ... and branching headers 8 ... A control device 4 is provided to allow cold water and hot water to flow in the divided heat transfer pipe groups 6 ... in a switchable manner and individually regulate the heat exchange medium circulation amount for each of the plurality of divided heat transfer pipe groups 6 ... . It is preferable that the lower limit flow rates of the plurality of divided heat transfer tube groups 6 are different from each other. However, some or all of the divided heat transfer tube groups 6 may be equal. The number of heat sources is controlled by a heat source such as a chiller or a boiler (not shown) to be cold water or hot water, and circulates a pair of cold water circulation paths 12 and hot water circulation paths 13 and a heat source.

3, the control device 4 includes proportional control flow control valves 15 (15a and 15b) provided correspondingly to the divided heat transfer tube groups 6, and flow control valves 15 (15a and 15b) And a controller 16 for controlling the controller 16. The control when the flow rate is adjusted by opening and closing the flow control valves 15 (15a, 15b) one by one by the controller 16 on the basis of Fig. 4 will be described. At the time of increasing the quantity of water, the second flow rate control valve 15b, which temporarily opens and closes the minimum flow rate at the time of proportionally increasing the flow rate from the first flow rate control valve 15a to the upper flow rate, And the second flow rate control valve 15, which is flown at a lower flow rate at a time point when the first flow rate control valve 15a, which temporarily suspends the minimum flow rate, And performs control to start the proportional increase. On the other hand, at the time of controlling the quantity of water reduction, at the point when the flow rate control is performed from one second flow rate control valve 15b to the lower flow rate, the first flow rate control valve 15a, which is closed next, The first flow rate regulating valve 15a is started to increase the water flow rate to the upper limit water flow rate at the time when the water flow rate is controlled by the second flow rate control valve 15b which is lowered to the lower flow rate, Control is performed. Although the case of two flow control valves 15 is described in the example of the drawings, even if three or more flow control valves 15 are provided, proportional control of a smooth quantity with excellent response can be performed.

5 and 6 illustrate an air conditioner provided on the floor of each of the above embodiments and are provided with a heat exchange coil 20 and a blower 21 for blowing ventilation air for air conditioning from the downwind side to the heat exchange coil 20 . The heat exchanging coil 20 is configured such that the heat transfer member 22 is divided into a plurality of divided heat transfer tube groups 23 ... through which the heat exchange medium flows, Pin groups 24 are provided. Other configurations are the same as those of the above-described embodiment, and a description thereof will be omitted.

On the other hand, the present invention is not limited to the above-described embodiment, and design modifications are possible without departing from the gist of the present invention. Although not shown, it is possible to increase and decrease the number of the divided air heat exchanger tube groups 6 and 23 and the split pin group 7 and the number of the air mixing areas 10 formed thereby, and the heat transfer medium is made of water, In addition to the number of heat sources, it is also possible to use refrigerants such as Freon or various other media. It is also possible to use a two-tube type in which the heat source circuit is circulated by switching between cold water and hot water.

2: Heat exchange coil
3: blower
4: Control device
5: Heat transfer member
6: split tube group
7: Split pin group
10: air mixing area
12: Cold water circulation route
13: Hot water circulation path
15: Flow control valve
16:
20: heat exchange coil
21: blower
22: heat transfer member
23: split tube group
24: Pin Group
30: Ceiling

Claims (13)

A heat exchange coil for exchanging heat exchange medium with ventilation air for air conditioning through a heat transfer member,
Wherein the heat transfer member includes a plurality of divided heat transfer tube groups through which the heat exchange medium flows and a plurality of divided pin groups into which the divided heat transfer tube groups are inserted,
A control device for individually adjusting the heat exchange medium flow rate for each of the plurality of divided heat transfer tube groups is provided,
A plurality of the divided pin groups are spaced in the ventilation direction to form air mixing areas between the air inlet and outlet of the adjacent divided pin group,
And the divided heat transfer tube group is disposed such that the heat exchange medium sequentially flows from the split pin group on the downwind side to the split pin group on the windward side.
The method according to claim 1,
Wherein an area of the divided heat transfer tube group inserted and mounted in the split pin group on the windward side is made smaller than an area of the divided heat transfer tube group inserted and mounted in the split pin group on the windward side.
3. The method according to claim 1 or 2,
Wherein the fin pitch of the split pin group on the windward side is wider than the fin pitch of the split pin group on the windward side.
3. The method according to claim 1 or 2,
There is provided a control device for individually controlling the flow rate of heat exchange medium for each of a plurality of the divided heat transfer tube groups while switching cold water and hot water to be able to be switched to a divided heat transfer tube group connected to a pair of cold water circulation paths and hot water circulation paths through which a heat exchange medium flows Wherein the heat exchange coil is a heat exchanger.
3. The method according to claim 1 or 2,
Wherein a lower limit flow rate of each of the plurality of divided heat transfer tube groups is different.
3. The method according to claim 1 or 2,
The heat exchange medium is used as the heat source water,
Wherein the control device includes a proportional control flow rate control valve provided corresponding to each divided heat transfer pipe group and a controller for controlling the flow rate control valve,
In the case where the flow rate control valves are sequentially opened and closed one by one to control the flow rate,
At the time of increasing the quantity of water, the minimum flow rate is temporarily reduced at the time of proportionally increasing the flow rate to the upper flow rate by one of the first flow rate control valves, the second flow rate control valve is opened next, The control is performed to start the proportional increase in the second flow rate control valve passing the lower flow rate at a time point when the first flow rate control valve temporarily decreasing the minimum flow rate is proportionally increased to the upper flow rate,
At the time of decreasing the quantity of water, the first flow rate control valve, which is closed at the next time when proportional to the lower limit quantity, is proportional to the minimum flow rate, And controls the first flow rate regulating valve to increase the flow rate to the upper flow rate at a time point exponentiated by the second flow rate regulating valve that is regulated down to the lower flow rate.
3. The method according to claim 1 or 2,
And the divided heat transfer tube group is formed of an elliptical tube.
A heat exchange coil for exchanging heat exchange medium with ventilation air for air conditioning through a heat transfer member,
Wherein the heat transfer member comprises a plurality of divided heat transfer tube groups into which the heat exchange medium flows and a pin group into which the divided heat transfer tube groups are inserted,
A controller for individually controlling the flow rate of the heat exchange medium for each of the plurality of divided heat transfer tube groups while switchingably transmitting cold water and hot water to the divided heat transfer tube groups connected to the pair of cold water circulation paths and hot water circulation paths through which the heat exchange medium flows Wherein the heat exchanger comprises a heat exchanger.
9. The method of claim 8,
Wherein a lower limit flow rate of each of the plurality of divided heat transfer tube groups is different.
10. The method according to claim 8 or 9,
The heat exchange medium is used as the heat source water,
Wherein the control device includes a proportional control flow rate control valve provided corresponding to each divided heat transfer pipe group and a controller for controlling the flow rate control valve,
In the case where the flow rate control valves are sequentially opened and closed one by one to control the flow rate,
At the time of increasing the quantity of water, the minimum flow rate is temporarily reduced at the time of proportionally increasing the flow rate to the upper flow rate by one of the first flow rate control valves, the second flow rate control valve is opened next, The control is performed to start the proportional increase in the second flow rate control valve passing the lower flow rate at a time point when the first flow rate control valve temporarily decreasing the minimum flow rate is proportionally increased to the upper flow rate,
At the time of decreasing the quantity of water, the first flow rate control valve, which is closed at the next time when proportional to the lower limit quantity, is proportional to the minimum flow rate, And controls the first flow rate regulating valve to increase the flow rate to the upper flow rate at a time point exponentiated by the second flow rate regulating valve that is regulated down to the lower flow rate.
10. The method according to claim 8 or 9,
And the divided heat transfer tube group is formed of an elliptical tube.
An air conditioner installed on a ceiling, comprising: a heat exchanger coil according to any one of claims 1 to 3; and a blower for blowing ventilation air for air conditioning from the air side to the heat exchanger coil .
An air conditioner installed on a floor, comprising: a heat exchanger coil according to claim 8 or 9; and an air blower for blowing ventilation air for air conditioning to the heat exchanger coil .

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