JP2010190494A - Exhaust heat utilization energy-saving air conditioning facility, system thereof, exhaust heat utilization energy-saving air conditioning method and exhaust heat utilization energy-saving air conditioning program - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an exhaust heat utilization energy-saving air conditioning facility, an exhaust heat utilization energy-saving air conditioning system, an exhaust heat utilization energy-saving air conditioning method and an exhaust heat utilization energy-saving air conditioning program, reducing waste of operational costs by effectively utilizing energy and having high safety. <P>SOLUTION: This exhaust heat utilization energy-saving air conditioning facility 1 includes an air conditioner 2, a damper 31 for direct circulation, a damper 32 for heating, a damper 33 for indirect circulation, a temperature sensor 41 for temperature-rising air, a temperature sensor 42 for a heating area, an operating part 43 and a control part 5, and exhaust heat from a server 11 is supplied to an office room 15 to be effectively utilized. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an exhaust heat utilization energy saving air conditioning facility, an exhaust heat utilization energy saving air conditioning system, an exhaust heat utilization energy saving air conditioning method, and an exhaust heat utilization energy saving air conditioning program.

In order to prevent global warming, it is necessary to effectively use energy. Of course, it is important for ordinary people to try to save money, but it is expected that engineers working on the front lines will seriously address this issue and establish energy-saving technology.
For example, it is a well-known wisdom to replace the air in the living room that is too warm due to heating with the air in the bedroom instead of replacing it with outside air. Thereby, it is not necessary to heat the bedroom, and energy can be used effectively.
However, it is necessary to solve various technical problems in order to effectively and safely use the exhaust heat of a wide variety of devices and equipment. For this reason, various energy saving technologies have been proposed.

For example, Patent Document 1 discloses that an electronic device of a computer that generates heat by operation is cooled by a chiller unit having a refrigeration cycle including an evaporator, an air-cooled condenser, an expansion valve, and a compressor, and the air is condensed by air The technology of the cooling device of the electronic device which exhausts heat in the air with a vessel is disclosed.
In this electronic apparatus cooling device, an air-cooled condenser is provided with an air supply passage and an air discharge passage communicating with the outside, a fan is provided in one of the passages, and a branch passage communicating with the room is provided in both passages. The present invention is characterized in that passage switching means for switching the passage is provided at the branch point where the branch passage is provided.

Patent Document 2 discloses a technology of an OA equipment exhaust heat utilization device that uses exhaust heat of OA equipment.
This OA equipment exhaust heat utilization device is connected to the exhaust port of the OA equipment and includes an exhaust suction device for sucking exhaust heat from the OA equipment, and sucks exhaust heat without leaking around the OA equipment by the exhaust suction device. Thus, the temperature at the location where the OA equipment is concentrated is prevented from rising locally.

Incidentally, as shown in FIG. 5, a large number of servers 11 and the like are installed in the data center 12, and these servers 11 operate almost all year round without stopping. Also, electronic devices such as the server 11 release a lot of heat. For this reason, in the data center 12, the air conditioner 2 blows out cooled air and circulates this air to cool the server 11, which is a heating element. That is, the air conditioner 2 sucks air heated by the server 11 (for example, air at 30 ° C.), releases heat to the atmosphere from a cooling tower installed outdoors, and cooled air (for example, 20 (Air at ℃). In addition, the above-described operation (cooling operation) of the air conditioner 2 is continuously performed throughout the year.
Since the electronic device such as the server 11 is a precision device, the temperature and humidity of the data center 12 are normally controlled within predetermined standards, and dust in the air is also removed by a filter. Yes.

JP-A-63-298513 JP 2001-015967 A

  However, in the data center air conditioning equipment 100 in the data center 12 described above, the cooling operation of the air conditioner 2 is performed not only in the summer period but also in the spring, autumn, and winter periods. For example, in the office 15 adjacent to the data center 12, even when the heating area air conditioner 6 performs heating operation during the spring, autumn, and winter periods, Air-conditioning operation was carried out. For this reason, there was a problem that waste of operating expenses could not be reduced. Moreover, there was a problem that it did not meet the expectations from the viewpoint of effectively using energy and preventing global warming.

  In the information society, the server 11 installed in the data center 12 is required to have extremely high reliability, and air conditioning equipment that may adversely affect the server 11 has not been accepted. . That is, the air conditioning equipment in the data center 12 is required to have high safety such that the server 11 is not adversely affected.

  The present invention has been proposed in order to solve the above-described problems. By effectively using energy, waste of operating expenses is reduced, and further, energy-saving air-conditioning equipment using waste heat excellent in safety is provided. An object is to provide an exhaust heat energy saving air conditioning system, an exhaust heat energy saving air conditioning method, and an exhaust heat energy saving air conditioning program.

  In order to achieve the above object, the energy saving air conditioning system using exhaust heat of the present invention blows out cooled air, circulates the air to cool the heating element, and the air heated by the heating element. Among these, the direct circulation damper that directly controls the amount of air sucked into the air conditioner, and the amount of air supplied to the area to be heated among the air heated by the heating element are controlled. A heating damper, an indirect circulation damper that controls the amount of air sucked into the air conditioner from the area to be heated, and a temperature sensor for temperature rising air that measures the temperature of the air heated by the heating element A heating area temperature sensor for measuring the temperature of the area to be heated, an operation unit to which a set temperature of the area to be heated is input, the temperature sensor for the heated air, and the heating area A control unit that controls the degree of opening of each of the direct circulation damper, the heating damper, and the indirect circulation damper based on a signal from the degree sensor and the operation unit. When the temperature of the heated area is lower than the set temperature of the heated area and the temperature of the air heated by the heating element is higher than the temperature of the heated area, the indirect circulation The damper is opened by a predetermined opening, the heating damper is opened by a predetermined opening, the direct circulation damper is closed by a predetermined opening, and the temperature of the area to be heated is the value of the area to be heated. When the temperature of the air heated by the heating element is higher than a set temperature and higher than the temperature of the area to be heated, the direct circulation damper is opened by a predetermined opening, and the warm Closed use damper predetermined opening degree, the indirect circulation damper is only as closed configuration predetermined opening.

  Moreover, the energy saving air conditioning system using exhaust heat according to the present invention comprises one or more heating elements, a building having at least a heating element installation area where the heating element is installed and a heated area, and cooled air. An air conditioner that cools the heating element by blowing air and circulating the air, and a damper for direct circulation that controls the amount of air directly drawn into the air conditioner among the air heated by the heating element And a heating damper for controlling the amount of air supplied to the area to be heated among the air heated by the heating element, and the amount of air sucked into the air conditioner from the area to be heated An indirect circulation damper, a temperature sensor for measuring the temperature of the air heated by the heating element, and a temperature sensor for the heating area that measures the temperature of the area to be heated. And an operation unit to which a set temperature of the area to be heated is input, the temperature sensor for the heated air, the temperature sensor for the heating area, and a signal from the operation unit, for the direct circulation A damper, a heating damper, and a control unit for controlling the opening degree of the indirect circulation damper, the temperature of the heated area is lower than the set temperature of the heated area, and When the temperature of the air heated by the heating element is higher than the temperature of the area to be heated, the indirect circulation damper opens by a predetermined opening, and the heating damper opens by a predetermined opening. The direct circulation damper is closed by a predetermined opening, the temperature of the heated area is higher than the set temperature of the heated area, and the temperature of the air heated by the heating element is increased. When the temperature is higher than the temperature of the area to be heated, the direct circulation damper opens by a predetermined opening, the heating damper closes by a predetermined opening, and the indirect circulation damper opens by a predetermined opening. Closed only once.

  Further, the energy saving air-conditioning method using exhaust heat of the present invention includes: an air conditioner that blows out cooled air and circulates the air to cool the heating element; and the air heated by the heating element directly. A damper for direct circulation that controls the amount of air sucked into the air conditioner, and a heating damper that controls the amount of air supplied to the area to be heated among the air heated by the heating element, An indirect circulation damper that controls the amount of air sucked into the air conditioner from the area to be heated, a temperature sensor for temperature rising air that measures the temperature of the air that has been heated by the heating element, and the heating A heating area temperature sensor for measuring the temperature of the heating area, an operation unit to which a set temperature of the area to be heated is input, the temperature rising air temperature sensor, the heating area temperature sensor, and Based on the signal from the operation unit, the direct circulation damper, the heating damper, and the control unit for controlling the opening degree of the indirect circulation damper are used, and the heating area When the temperature is lower than the set temperature of the area to be heated and the temperature of the air heated by the heating element is higher than the temperature of the area to be heated, the indirect circulation damper has a predetermined value. The heating damper is opened by a predetermined opening, the direct circulation damper is closed by a predetermined opening, and the temperature of the heated area is higher than the set temperature of the heated area. And when the temperature of the air heated by the heating element is higher than the temperature of the area to be heated, the direct circulation damper opens by a predetermined opening degree, and the heating damper Close for a constant opening, the indirect circulation damper is only as close method predetermined opening.

  Further, the energy saving air conditioning program using exhaust heat of the present invention is circulated by an air conditioner that cools the heating element and measures the temperature of the air heated by the heating element. Based on the temperature sensor for the heating area that measures the temperature of the heating area and the signal from the operation unit to which the set temperature of the area to be heated is input, the air heated by the heating element directly A damper for direct circulation that controls the amount of air sucked into the air conditioner, a damper for heating that controls the amount of air supplied to the area to be heated among the air heated by the heating element, and The temperature of the area to be heated is controlled by the controller that controls each opening degree of the damper for indirect circulation that controls the amount of air sucked into the air conditioner from the area to be heated. When the temperature of the air raised by the heating element is higher than the temperature of the area to be heated, the indirect circulation damper is opened by a predetermined opening degree, The heating damper is opened by a predetermined opening, the direct circulation damper is closed by a predetermined opening, and the temperature of the heated area is higher than a set temperature of the heated area, and When the temperature of the air heated by the heating element is higher than the temperature of the area to be heated, the direct circulation damper is opened by a predetermined opening degree, and the heating damper is closed by a predetermined opening degree. The indirect circulation damper is configured to execute a procedure for closing the damper by a predetermined opening degree.

  According to the present invention, the waste heat utilization energy saving air conditioning equipment, the waste heat utilization energy saving air conditioning system, the waste heat utilization energy saving air conditioning method, and the waste heat utilization energy saving air conditioning program reduce waste of operating expenses by effectively using energy. In addition, it is possible to achieve a high level of safety that does not adversely affect the server.

FIG. 1: has shown the schematic of the waste heat utilization energy saving air-conditioning equipment concerning 1st embodiment of this invention. FIG. 2: has shown the schematic flowchart figure for demonstrating the waste heat utilization energy saving air-conditioning method concerning 1st embodiment of this invention. FIG. 3: has shown the schematic of the waste heat utilization energy saving air-conditioning equipment concerning 2nd embodiment of this invention. FIG. 4: has shown the schematic flowchart figure for demonstrating the waste-heat utilization energy saving air-conditioning method concerning 2nd embodiment of this invention. FIG. 5 shows a schematic diagram of a data center air conditioning facility relevant to the present invention.

[First embodiment of energy saving air-conditioning equipment using waste heat]
FIG. 1: has shown the schematic of the waste heat utilization energy saving air-conditioning equipment concerning 1st embodiment of this invention.
In FIG. 1, an energy saving air conditioning system 1 using exhaust heat includes an air conditioner 2, a damper 31 for direct circulation, a damper 32 for heating, an indirect circulation damper 33, a temperature sensor 41 for heated air, and a temperature sensor 42 for heating area. The operation unit 43 and the control unit 5 are provided.
Moreover, the waste heat utilization energy-saving air-conditioning equipment 1 is provided in the building 10, and uses the waste heat from the server 11 effectively.

(air conditioner)
The air conditioner 2 blows out cooled air (for example, air at 20 ° C., and the temperature of this air is set to T ₁ ° C.) to the blowing duct 13, and circulates this air to circulate the server 11 as a heating element. Cool down.
Although not shown, the air conditioner 2 includes a blower, a heat exchanger (including a cooling tower installed outdoors), a humidifier, an air filter, a casing, and various sensors. This air conditioner 2 is normally installed in the air conditioner room 17 and controls the temperature, humidity, air volume, and the like of the air that is blown out.

Moreover, the air blown out from the air conditioner 2 flows through at least the blowout duct 13 provided under the floor, the data center 12, and the return duct 14 provided on the ceiling, and is sucked into the air conditioner 2. At this time, air blown out from the air conditioner 2 is cooled air (for example, air at 20 ° C.), and air flowing through the return duct 14 is air that has been heated by the server 11 or the like (for example, Air at 30 ° C. The temperature of this air is T ₂ ° C.).

Here, in the present embodiment, as described above, the heating element is the server 11. In this way, the exhaust heat from the server 11 can be effectively used as will be described later.
The heating element is not limited to the server 11 and may be a general computer, for example.

Further, as described above, the server 11 is installed in the data center 12, and the air conditioner 2 is an underfloor type air conditioner that blows out cooled air through a blowout duct 13 provided under the floor of the data center 12. It is as. In this way, the server 11 can be efficiently cooled.
The air conditioner 2 is not limited to an underfloor type air conditioner, and may be any air conditioner capable of efficiently circulating air, for example.

(Direct circulation damper)
The direct circulation damper 31 is a damper that controls the amount of air directly drawn into the air conditioner 2 out of the air heated by the server 11.
The direct circulation damper 31 includes a driving unit such as a motor, and the opening degree is automatically controlled by the control unit 5. The direct circulation damper 31 is installed between the return duct 14 and the air conditioner chamber 17.

(Damper for heating)
The heating damper 32 is a damper that controls the amount of air supplied to the office room 15, which is a heated area, of the air heated by the server 11.
The heating damper 32 includes driving means such as a motor, and the opening degree is automatically controlled by the control unit 5. The heating damper 32 is installed between the return duct 14 and the ceiling duct 16.

Preferably, the direct circulation damper 31 may have a blower (not shown). In this way, the air heated by the server 11 can be effectively supplied to the office room 15.
In addition, in this embodiment, although the area heated is the office room 15, it is not limited to this, For example, it can be set as various areas, such as a conference room and a laboratory.
In addition, the air heated by the server 11 is supplied to the office room 15 through the ceiling duct 16, but is not limited to this. For example, the air is directly or predetermined It is good also as a structure supplied to the office room 15 via a flow path.

(Indirect circulation damper)
The indirect circulation damper 33 is a damper that controls the amount of air sucked into the air conditioner 2 from the office room 15.
The indirect circulation damper 33 includes a driving unit such as a motor, and the opening degree is automatically controlled by the control unit 5. The indirect circulation damper 33 is installed between the office room 15 and the air conditioner room 17.
The indirect circulation damper 33 may have a filter (not shown) and the like, and in this way, it is possible to prevent problems such as dust in the office room 15 being sucked into the air conditioner 2. .

(Temperature sensor for temperature rising air)
The temperature rising air temperature sensor 41 is a sensor that measures the temperature of the air heated by the server 11 (T ₂ ° C.).
The temperature rising air temperature sensor 41 is connected to the control unit 5 and outputs a signal related to the measured temperature to the control unit 5. Moreover, the temperature sensor 41 for temperature rising air is attached in the vicinity of the heating damper 32 in the return duct 14.

(Temperature sensor for heating area)
The heating area temperature sensor 42 is a sensor that measures the temperature (t ₁ ° C.) of the office room 15.
The heating area temperature sensor 42 is connected to the control unit 5 and outputs a signal related to the measured temperature to the control unit 5. The heating area temperature sensor 42 is attached in the vicinity of the indirect circulation damper 33 in the office room 15.

(Operation section)
The operation unit 43 includes display means, a setting switch, an on / off switch, and the like, and a set temperature of the office room 15 is input thereto.
The heating area temperature sensor 42 is connected to the control unit 5, and outputs a signal related to the input set temperature (t ° C.) to the control unit 5. The operation unit 43 is attached to a wall or the like in the office room 15.

(Control part)
The control unit 5 is a sequencer, a computer, or the like, and is attached to a wall or the like in the office room 15. The control unit 5 includes a direct circulation damper 31, a heating damper 32, and an indirect control based on signals from the temperature rising air temperature sensor 41, the heating area temperature sensor 42, and the operation unit 43. Each opening degree of the circulation damper 33 is controlled.

That is, the controller 5 determines that the temperature (t ₁ ° C) of the office room 15 measured by the heating area temperature sensor 42 is lower than the set temperature (t ° C) of the office room 15 input to the operation unit 43, and The temperature of the air heated by the server 11 (T ₂ ° C) measured by the temperature sensor 41 for temperature rising air is the temperature of the office room 15 (t ₁ ° C) measured by the temperature sensor 42 for the heating area. When higher, control is performed such that the indirect circulation damper 33 opens by a predetermined opening, the heating damper 32 opens by a predetermined opening, and the direct circulation damper 31 closes by a predetermined opening.

Further, the control unit 5 determines that the temperature (t ₁ ° C) of the office room 15 measured by the heating area temperature sensor 42 is higher than the set temperature (t ° C) of the office room 15 input to the operation unit 43, and The temperature of the air heated by the server 11 (T ₂ ° C) measured by the temperature sensor 41 for temperature rising air is the temperature of the office room 15 (t ₁ ° C) measured by the temperature sensor 42 for the heating area. When higher, control is performed so that the direct circulation damper 31 is opened by a predetermined opening, the heating damper 32 is closed by a predetermined opening, and the indirect circulation damper 33 is closed by a predetermined opening.

If it does in this way, since the heat deprived from the server 11 can be supplied to the office room 15, waste heat can be used effectively and energy saving can be implement | achieved.
In the present embodiment, normally, the temperature of the air heated by the server 11 (T ₂ ° C.) is higher than the temperature of the office room 15 (t ₁ ° C.) measured by the heating area temperature sensor 42. is there.

(Air conditioning unit for heating area)
The heating area air conditioner 6 is an air conditioner installed in the office 15. Although not shown, the heating area air conditioner 6 includes a blower, a heat exchanger (including a cooling tower installed outdoors), an air filter, a casing, and various sensors.
Further, the heating area air conditioner 6 normally has the heating set temperature (T ° C.) of the heating area air conditioner 6 lower than the set temperature (t ° C.) input to the operation unit 43 during the heating operation. Is set. If it does in this way, even if it is a case where the heating area air conditioner 6 is heating-operating, the heat taken from the server 11 can be supplied to the office room 15.

Furthermore, the heating area air conditioner 6 may be configured to start the heating operation after the exhaust heat utilization energy-saving air conditioning equipment 1 is operated and a predetermined time has elapsed. Thereby, although the exhaust heat of the server 11 can be effectively used, it is possible to reliably avoid the problem that the heating operation is performed in a state where the exhaust heat is not effectively used.
The heating area air conditioner 6 has a dedicated operation unit (not shown) and the like, and the dedicated operation unit, the operation unit 43 and the control unit 5 described above are provided integrally. It is good.

Next, operation | movement of the exhaust-heat utilization energy saving air-conditioning equipment 1 of the structure mentioned above is demonstrated with reference to drawings.
First, in general, in the exhaust heat utilization energy-saving air conditioning equipment 1, the on / off switch of the operation unit 43 is always turned on during the winter period. Further, in the spring or autumn period, before the heating area air conditioner 6 performs the heating operation, the on / off switch of the operation unit 43 is turned on, or the office room 15 is warmed in consideration of the cooling in the morning. If it is preferable to place the switch, the on / off switch of the operation unit 43 is turned on all night. Further, during the summer period in which the heating area air conditioner 6 performs the cooling operation, the on / off switch of the operation unit 43 is always off.

FIG. 2: has shown the schematic flowchart figure for demonstrating the waste heat utilization energy saving air-conditioning method concerning 1st embodiment of this invention.
In FIG. 2, during the winter, spring and autumn periods, the exhaust heat-use energy-saving air-conditioning facility 1 first inputs a set temperature (t ° C. (for example, t ° C. = 23 ° C.)) to the operation unit 43 and turns on / off the switch. The operation unit 43 is turned on and outputs these signals to the control unit 5 (step S1).
Although not shown, a changed set temperature (t.degree. C. (for example, t.degree. C. = 22.degree. C.)) is input to the operation unit 43 during operation of the exhaust heat utilization energy saving air conditioning equipment 1, or an on / off switch. When is turned off, the operation unit 43 outputs these signals to the control unit 5.

Next, the control part 5 memorize | stores the information of preset temperature (t (degreeC) (for example, tdegreeC = 23 degreeC)), and judges whether the on-off switch is turned on (step S2).
When the determination is Yes (when the on / off switch is on), the process proceeds to step S3. When the result is No (when the on / off switch is off), the process proceeds to step S8, where the control unit 5 fully opens the direct circulation damper 31 and fully closes the heating damper 32, thereby indirectly circulating the damper. 33 is fully closed.

In step S3, the temperature sensor 41 for the heated air measures the temperature of the heated air (T ₂ ° C.), outputs a signal related to the measured temperature to the control unit 5, and the temperature sensor for the heating area 42 measures the temperature (t ₁ ° C.) of the office room 15 and outputs a signal related to the measured temperature to the control unit 5.

Next, the control unit 5 has the temperature (t ₁ ° C.) of the office room 15 measured by the heating area temperature sensor 42 lower than the set temperature (t ° C.) of the office room 15 input to the operation unit 43. Further, the temperature of the air heated by the server 11 (T ₂ ° C.) measured by the temperature sensor 41 for temperature rising air is the temperature (t ₁ ° C.) of the office room 15 measured by the temperature sensor 42 for the heating area. ) Is determined (step S4).
When the determination is Yes, the controller 5 determines that the indirect circulation damper 33 is opened by a predetermined opening, the heating damper 32 is opened by a predetermined opening, and the direct circulation damper 31 is opened by a predetermined opening. Control is performed to close only (step S5). Then, it progresses to step S2 mentioned above.
Moreover, when it is No, it progresses to step S6.

In step S <b> 6, the control unit 5 determines that the temperature (t ₁ ° C.) of the office room 15 measured by the heating area temperature sensor 42 is higher than the set temperature (t ° C.) of the office room 15 input to the operation unit 43. The temperature of the air heated by the server 11 (T ₂ ° C) measured by the temperature sensor 41 for temperature rising air is the temperature (t ₁ ) of the office room 15 measured by the temperature sensor 42 for the heating area. Judge whether the temperature is higher than ° C.
When the determination is Yes, the control unit 5 determines that the direct circulation damper 31 is opened by a predetermined opening degree, the heating damper 32 is closed by a predetermined opening degree, and the indirect circulation damper 33 is opened by a predetermined opening degree. Control is performed so as to close only (step S7). Then, it progresses to step S2 mentioned above.
If No, the process proceeds to step S2 described above. That is, when the temperature (t ₁ ° C) of the office room 15 measured by the heating area temperature sensor 42 is the same as the set temperature (t ° C) of the office room 15 input to the operation unit 43, the direct circulation damper 31, proceeding to the above-described step S <b> 2 while maintaining the respective opening states of the heating damper 32 and the indirect circulation damper 33.

In steps S5 and S7 described above, the direct circulation damper 31, the heating damper 32, and the indirect circulation damper 33 operate in the order described above, and suppress fluctuations in air pressure. However, it is not limited to this, For example, it is good also as a structure which act | operates substantially simultaneously.
Furthermore, normally, in steps S5 and S7, each predetermined opening of the direct circulation damper 31, the heating damper 32, and the indirect circulation damper 33 is an opening corresponding to the fluctuating air flow rate. That is, for example, when the heating damper 32 opens by a predetermined opening and the opening area increases by Δm ² , the indirect circulation damper 33 opens by a predetermined opening that increases the opening area by Δm ² , The direct circulation damper 31 is closed by a predetermined opening that reduces the opening area by Δm ² . As a result, the air flow rate can be accurately controlled, and fluctuations in air pressure can be suppressed.

  The control by the control unit 5 described above has various application examples. That is, in the temperature control technique, various techniques such as a control method for suppressing overshoot and a control method for changing a predetermined opening degree based on a temperature difference have been developed. As an application example of the present embodiment, the above temperature control technique can be applied.

  As explained above, according to the energy saving air conditioning system 1 using exhaust heat of the present embodiment, the heat taken from the server 11 of the data center 12 can be supplied to the office room 15, so that exhaust heat is effectively used. Energy saving. That is, by supplying the heat exhausted from the server of the data center 12 to the office 15, the heating cost of the office 15 can be reduced. Moreover, the air cooled by flowing through the office room 15 is recirculated to the air conditioner 2, thereby reducing the load on the air conditioner 2 and realizing energy saving operation.

[First embodiment of energy saving air-conditioning system using waste heat]
The present invention is also effective as an invention of an energy saving air conditioning system using exhaust heat.
As described above, the waste heat-use energy-saving air-conditioning system of the present embodiment includes a plurality of servers 11, a data center 12 in which the servers 11 are installed, and a building 10 having at least an office room 15 as an area to be heated, and The configuration includes an energy-saving air-conditioning facility 1 that uses exhaust heat.

  Thus, the waste heat utilization energy saving air conditioning system of this embodiment is the entire building 10 including the server 11, the waste heat utilization energy saving air conditioning equipment 1, the heating area air conditioner 6, and the like, and the server 11 of the data center 12. Since the heat taken away from the office can be supplied to the office room 15, exhaust heat can be used effectively, and energy saving can be realized.

[First embodiment of energy-saving air-conditioning method using exhaust heat]
The present invention is also effective as an invention of an energy saving air conditioning method using exhaust heat.
This embodiment is a waste heat utilization energy saving air conditioning method in the above-described waste heat utilization energy saving air conditioning equipment 1. That is, as described above, the temperature (t ₁ ° C) of the office room 15 measured by the heating area temperature sensor 42 is lower than the set temperature (t ° C) of the office room 15 input to the operation unit 43, and The temperature of the air heated by the server 11 (T ₂ ° C) measured by the temperature sensor 41 for temperature rising air is the temperature of the office room 15 (t ₁ ° C) measured by the temperature sensor 42 for the heating area. When higher, the indirect circulation damper 33 opens by a predetermined opening, the heating damper 32 opens by a predetermined opening, and the direct circulation damper 31 closes by a predetermined opening (FIG. 2). (See steps S4 and S5).

Further, the temperature (t ₁ ° C.) of the office room 15 measured by the heating area temperature sensor 42 is higher than the set temperature (t ° C.) of the office room 15 input to the operation unit 43, and for the heated air. When the temperature of the air heated by the server 11 (T ₂ ° C) measured by the temperature sensor 41 is higher than the temperature of the office room 15 (t ₁ ° C) measured by the heating area temperature sensor 42, it is directly In this method, the dynamic circulation damper 31 is opened by a predetermined opening, the heating damper 32 is closed by a predetermined opening, and the indirect circulation damper 33 is closed by a predetermined opening (see steps S6 and S7 in FIG. 2). ).

  Thus, as described above, the heat-saving energy-saving air-conditioning method of the present embodiment can supply the heat taken from the server 11 of the data center 12 to the office room 15, so that the exhaust heat is effectively used. Energy saving.

[First embodiment of exhaust heat energy-saving air conditioning program]
The present invention is also effective as an invention of an exhaust heat utilization energy saving air conditioning program.
The waste heat utilization energy-saving air-conditioning system 1 and the waste heat utilization energy-saving air conditioning system in the embodiment described above are configured by the waste heat utilization energy-saving air conditioning program stored in the storage means (for example, ROM) of the control unit 5. Realized.
For example, the waste heat utilization energy saving air conditioning program is read by the control means (CPU or the like) of the control unit 5 to send a command to each component of the exhaust heat utilization energy saving air conditioning equipment 1 to perform predetermined processing.
As a result, the waste heat utilization energy saving function is realized by the cooperation of each component means of the waste heat utilization energy saving air conditioning equipment 1 which is a hardware resource and the waste heat utilization energy saving air conditioning program which is software.

In the present embodiment, the temperature (t ₁ ° C.) of the office room 15 measured by the heating area temperature sensor 42 is input to the operation unit 43 in the control unit 5 of the above-described exhaust heat utilization energy-saving air conditioning equipment 1. The temperature of the air heated by the server 11 (T ₂ ° C.) that is lower than the set temperature (t ° C.) of the chamber 15 and measured by the temperature sensor 41 for the heated air is measured by the heating area temperature sensor 42. When the measured temperature of the office room 15 (t ₁ ° C.) is higher, the indirect circulation damper 33 opens by a predetermined opening, the heating damper 32 opens by a predetermined opening, and the direct circulation damper 31 opens. A procedure for closing only a predetermined opening is executed (see steps S4 and S5 in FIG. 2).

Further, the temperature (t ₁ ° C.) of the office room 15 measured by the heating area temperature sensor 42 is higher than the set temperature (t ° C.) of the office room 15 input to the operation unit 43, and for the heated air. When the temperature of the air heated by the server 11 (T ₂ ° C) measured by the temperature sensor 41 is higher than the temperature of the office room 15 (t ₁ ° C) measured by the heating area temperature sensor 42, it is directly The procedure is such that the general circulation damper 31 is opened by a predetermined opening, the heating damper 32 is closed by a predetermined opening, and the indirect circulation damper 33 is closed by a predetermined opening (steps S6 and S7 in FIG. 2). reference).

  Thus, according to the waste heat utilization energy saving air conditioning program of the present embodiment, the heat taken from the server 11 of the data center 12 can be supplied to the office room 15 as described above. It can be used and energy saving can be realized.

[Second embodiment of energy saving air-conditioning equipment using waste heat]
FIG. 3: has shown the schematic of the waste heat utilization energy saving air-conditioning equipment concerning 2nd embodiment of this invention.
In FIG. 3, the exhaust heat energy-saving air-conditioning equipment 1 a according to the present embodiment measures the temperature (t ₂ ° C) of the air sucked by the air conditioner 2 as compared with the exhaust heat energy-saving air-conditioning equipment 1 according to the first embodiment. An air temperature sensor 44 is provided, and the control unit 5a sets the temperature of the air that the air conditioner 2 sucks (t ₂ ° C) to be equal to or higher than the temperature of the cooled air that the air conditioner 2 blows (T ₁ ° C). The point of priority control is different. In addition, the other structure of this embodiment is as substantially the same as the waste heat utilization energy saving air-conditioning equipment 1. FIG.
Therefore, in FIG. 3, the same components as those in FIG. 1 are denoted by the same reference numerals, and detailed description thereof is omitted.

(Temperature sensor for intake air)
The intake air temperature sensor 44 is a sensor that measures the temperature (t ₂ ° C) of the air that the air conditioner 2 sucks.
The intake air temperature sensor 44 is connected to the control unit 5 and outputs a signal related to the measured temperature to the control unit 5. The intake air temperature sensor 44 is attached in the vicinity of an intake port (not shown) of the air conditioner 2.

(Control part)
The control unit 5a has substantially the same configuration as the control unit 5 of the first embodiment, and the control unit 5a is cooled by the air conditioner 2 blowing out the temperature of the air (t ₂ ° C) that the air conditioner ₂ sucks. The air is preferentially controlled so that the temperature is higher than the air temperature (T ₁ ° C).
That is, the control unit 5a determines that the temperature (t ₁ ° C) of the office room 15 measured by the heating area temperature sensor 42 is lower than the set temperature (t ° C) of the office room 15 input to the operation unit 43, and The temperature of the air heated by the server 11 (T ₂ ° C) measured by the temperature sensor 41 for temperature rising air is the temperature of the office room 15 (t ₁ ° C) measured by the temperature sensor 42 for the heating area. When it is higher, it is further determined whether or not the temperature of the air that the air conditioner ₂ sucks (t ₂ ° C) is equal to or higher than the temperature of the cooled air that the air conditioner 2 blows out (T ₁ ° C). When this determination is Yes, the controller 5a determines that the indirect circulation damper 33 is opened by a predetermined opening, the heating damper 32 is opened by a predetermined opening, and the direct circulation damper 31 is opened by a predetermined opening. Control to close only. Moreover, when the said determination is No, each opening degree state of the damper 31 for direct circulation, the damper 32 for heating, and the damper 33 for indirect circulation is maintained.

Next, operation | movement of the exhaust-heat utilization energy saving air-conditioning equipment 1a of the structure mentioned above is demonstrated with reference to drawings.
FIG. 4: has shown the schematic flowchart figure for demonstrating the waste-heat utilization energy saving air-conditioning method concerning 2nd embodiment of this invention.
4, when compared with the steps S1~S8 of the first embodiment shown in FIG. 2, the control portion 5a, the temperature of the air conditioning unit 2 is sucked (t ₂ ° C.) were cooled air conditioner 2 is blown It is determined whether or not the air temperature (T ₁ ° C) or higher. If this determination is No, the opening states of the direct circulation damper 31, the heating damper 32, and the indirect circulation damper 33 are determined. The difference is that step S4a to be maintained is added. In addition, the other step of this embodiment is as substantially the same as the step of the waste heat utilization energy saving air-conditioning equipment 1.
Therefore, in FIG. 4, the same steps as those in FIG. 2 are denoted by the same reference numerals, and detailed description thereof is omitted.

In step S <b> 4, the control unit 5 a has the office room 15 in which the temperature (t ₁ ° C.) of the office room 15 measured by the heating area temperature sensor 42 is input to the operation unit 43 in substantially the same manner as in the first embodiment. The temperature of the air heated by the server 11 (T ₂ ° C.) that is lower than the preset temperature (t ° C.) and measured by the temperature rising air temperature sensor 41 is measured by the heating area temperature sensor 42. It is determined whether the temperature is higher than the temperature of the office room 15 (t ₁ ° C.).
When the determination is Yes, the control unit 5a proceeds to step S4a. If No, the process proceeds to step S6 in substantially the same manner as in the first embodiment.

In step S4a, the control unit 5a determines whether or not the temperature of the air sucked by the air conditioner ₂ (t ₂ ° C) is equal to or higher than the temperature of the cooled air blown out by the air conditioner 2 (T ₁ ° C).
With this determination, when the result is Yes, the controller 5a directly opens the indirect circulation damper 33 by a predetermined opening degree, and the heating damper 32 opens by a predetermined opening degree, almost as in the first embodiment. Control is performed so that the circulation damper 31 is closed by a predetermined opening degree (step S5). Then, it progresses to step S2 mentioned above.

If No, the process proceeds to step S2 described above. That is, when the temperature of the air sucked by the air conditioner 2 (t ₂ ° C) is lower than the temperature of the cooled air blown out by the air conditioner 2 (T ₁ ° C), the direct circulation damper 31, the heating damper 32, and the indirect While maintaining the respective opening states of the general circulation damper 33, the process proceeds to step S2.
In the present embodiment, taking into account that the temperature (t ₁ ° C.) of the office room 15 is rising, each opening state of the direct circulation damper 31, the heating damper 32, and the indirect circulation damper 33. However, the present invention is not limited to this. For example, although not shown, instead of proceeding to step S2, the configuration may proceed to step S7. Even in this case, the control unit 5a preferentially sets the temperature of the air sucked by the air conditioner ₂ (t ₂ ° C) to be equal to or higher than the temperature of the cooled air blown out by the air conditioner 2 (T ₁ ° C). Can be controlled.

Thereby, after the air conditioner 2 warms inhaled air (for example, air having a temperature of 19 ° C. or lower) (for example, after warming to 20 ° C.), it is possible to avoid such a problem that it blows out. In addition, it is possible to more reliably avoid the problem of blowing too cold air (for example, air having a temperature of 10 ° C. or lower) to the server 11.
The other steps are almost the same as in the first embodiment.

As explained above, according to the waste heat utilization energy saving air-conditioning equipment 1a of this embodiment, there can exist an effect substantially the same as the waste heat utilization energy saving air conditioning equipment 1 of 1st embodiment.
Furthermore, the problem that the air conditioner 2 warms the sucked air and blows it out can be avoided, and the problem that the air that is too cold is blown onto the server 11 can be avoided more reliably. Therefore, it is possible to achieve high safety such that the server 11 is not adversely affected.

[Second Embodiment of Energy Saving Air Conditioning System Using Waste Heat]
As described above, the waste heat-use energy-saving air-conditioning system of the present embodiment includes a plurality of servers 11, a data center 12 in which the servers 11 are installed, and a building 10 having at least an office room 15 as an area to be heated, and The configuration includes a waste heat utilization energy-saving air conditioning facility 1a and the like.
In this way, it is possible to achieve substantially the same effect as that of the first embodiment, and to realize high safety such that the server 11 is not adversely affected.

[Second embodiment of energy saving air-conditioning method using exhaust heat]
In the present embodiment, as compared with the energy saving air conditioning method using exhaust heat according to the first embodiment described above, the control unit 5a determines the temperature (t ₂ ° C) of the air that the air conditioner ₂ sucks in the air conditioner 2. This is a method for preferential control so that the temperature of the cooled air blown out (T ₁ ° C.) or higher.
In this way, it is possible to achieve substantially the same effect as that of the first embodiment, and to realize high safety such that the server 11 is not adversely affected.

[Second Embodiment of Waste Heat Utilization Energy Saving Air Conditioning Program]
Compared with the exhaust heat utilization energy-saving air conditioning program of the first embodiment described above, the present embodiment sets the temperature (t ₂ ° C) of the air that the air conditioner ₂ sucks into the control unit 5a as described above. A procedure for preferential control is performed so that the temperature of the cooled air blown out is equal to or higher than the temperature (T ₁ ° C).
In this way, it is possible to achieve substantially the same effect as that of the first embodiment, and to realize high safety such that the server 11 is not adversely affected.

As mentioned above, although the waste heat utilization energy saving air conditioning system, the waste heat utilization energy saving air conditioning system, the waste heat utilization energy saving air conditioning method, and the waste heat utilization energy saving air conditioning program of the present invention were shown and explained, preferred embodiments are concerned. The waste heat utilization energy saving air conditioning equipment, the waste heat utilization energy saving air conditioning system, the waste heat utilization energy saving air conditioning method, and the waste heat utilization energy saving air conditioning program are not limited to the above-described embodiments, and various within the scope of the present invention. Needless to say, it is possible to implement this change.
For example, the waste heat utilization energy saving air conditioning program for realizing the waste heat utilization energy saving function is stored in the ROM, hard disk, etc. of the control units 5 and 5a, as well as a computer-readable recording medium such as an external storage device and It can be stored in a portable recording medium or the like.
The external storage device refers to a memory expansion device that incorporates a storage medium such as a CD-ROM and is externally connected to the control units 5 and 5a. On the other hand, the portable recording medium is a recording medium that can be mounted on a recording medium driving device (drive device) and is portable, and refers to, for example, a flexible disk, a memory card, a magneto-optical disk, and the like.

The program recorded on the recording medium is loaded into the RAM of the control units 5 and 5a and executed by the CPU (control means). By this execution, the exhaust heat utilization energy saving air conditioning system 1, 1a and the exhaust heat utilization energy saving air conditioning system of the embodiment described above are realized.
Furthermore, when loading an exhaust heat energy saving air conditioning program, the exhaust heat energy saving air conditioning program held in another computer can be downloaded to a RAM or an external storage device using a communication line. The downloaded exhaust heat utilization energy saving air conditioning program is also executed by the CPU, and realizes the exhaust heat utilization energy saving function of the exhaust heat utilization energy saving air conditioning equipment 1, 1 a and the exhaust heat utilization energy saving air conditioning system of the above embodiment.

DESCRIPTION OF SYMBOLS 1, 1a Waste heat utilization energy saving air conditioner 2 Air conditioner 5, 5a Control part 6 Heating area air conditioner 10 Building 11 Server 12 Data center 13 Outlet duct 14 Return duct 15 Office room 16 Ceiling duct 17 Air conditioner room 31 Directly Circulation damper 32 Heating damper 33 Indirect circulation damper 41 Temperature sensor 42 for temperature rising air Temperature sensor 43 for heating area Operation unit 44 Temperature sensor for intake air

Claims (12)

An air conditioner that blows out cooled air and circulates the air to cool the heating element;
Among the air heated by the heating element, a direct circulation damper that controls the amount of air directly sucked into the air conditioner;
Among the air heated by the heating element, a heating damper that controls the amount of air supplied to the area to be heated,
An indirect circulation damper that controls the amount of air drawn into the air conditioner from the heated area;
A temperature sensor for temperature rising air for measuring the temperature of the air heated by the heating element;
A heating area temperature sensor for measuring the temperature of the heated area;
An operation unit for inputting a set temperature of the area to be heated;
Based on signals from the temperature-increasing air temperature sensor, the heating area temperature sensor, and the operation unit, the direct circulation damper, the heating damper, and the indirect circulation damper are opened. And a control unit for controlling the degree,
When the temperature of the heated area is lower than the set temperature of the heated area and the temperature of the air heated by the heating element is higher than the temperature of the heated area, the indirect The circulation damper is opened by a predetermined opening, the heating damper is opened by a predetermined opening, and the direct circulation damper is closed by a predetermined opening,
When the temperature of the heated area is higher than the set temperature of the heated area, and the temperature of the air heated by the heating element is higher than the temperature of the heated area, the direct An exhaust heat-use energy-saving air conditioning system, wherein the circulation damper is opened by a predetermined opening, the heating damper is closed by a predetermined opening, and the indirect circulation damper is closed by a predetermined opening.   A temperature sensor for intake air that measures a temperature of the air sucked by the air conditioner, and the control unit has a temperature of the air sucked by the air conditioner equal to or higher than a temperature of the cooled air blown out by the air conditioner; The exhaust heat-use energy-saving air-conditioning equipment according to claim 1, wherein control is performed with priority.   The air conditioner for heating area installed in the area to be heated is provided, and the set temperature input to the operation unit is higher than the set temperature for heating of the air conditioner for heating area. Or the waste heat utilization energy saving air-conditioning equipment of 2.   The exhaust heat-use energy-saving air-conditioning equipment according to any one of claims 1 to 3, wherein the heating element is a server.   The waste heat utilization energy-saving air conditioning system according to claim 4, wherein the server is installed in a data center, and the air conditioner is an underfloor type air conditioner.   The waste heat utilization energy-saving air conditioning system according to any one of claims 1 to 5, wherein the heating damper has a blower. One or more heating elements;
A building having at least a heating element installation area and a heating area where the heating element is installed;
An air conditioner that blows out cooled air and circulates the air to cool the heating element;
Among the air heated by the heating element, a direct circulation damper that controls the amount of air directly sucked into the air conditioner;
Among the air heated by the heating element, a heating damper that controls the amount of air supplied to the area to be heated,
An indirect circulation damper that controls the amount of air drawn into the air conditioner from the heated area;
A temperature sensor for temperature rising air for measuring the temperature of the air heated by the heating element;
A heating area temperature sensor for measuring the temperature of the heated area;
An operation unit for inputting a set temperature of the area to be heated;
Based on signals from the temperature-increasing air temperature sensor, the heating area temperature sensor, and the operation unit, the direct circulation damper, the heating damper, and the indirect circulation damper are opened. And a control unit for controlling the degree,
When the temperature of the heated area is lower than the set temperature of the heated area and the temperature of the air heated by the heating element is higher than the temperature of the heated area, the indirect The circulation damper is opened by a predetermined opening, the heating damper is opened by a predetermined opening, and the direct circulation damper is closed by a predetermined opening,
When the temperature of the heated area is higher than the set temperature of the heated area, and the temperature of the air heated by the heating element is higher than the temperature of the heated area, the direct An exhaust heat-use energy-saving air-conditioning system, wherein the circulation damper is opened by a predetermined opening, the heating damper is closed by a predetermined opening, and the indirect circulation damper is closed by a predetermined opening.   A temperature sensor for intake air that measures a temperature of the air sucked by the air conditioner, and the control unit has a temperature of the air sucked by the air conditioner equal to or higher than a temperature of the cooled air blown out by the air conditioner; The exhaust heat utilization energy-saving air conditioning system according to claim 7, wherein the control is performed with priority. An air conditioner that blows out cooled air and circulates the air to cool the heating element;
Among the air heated by the heating element, a direct circulation damper that controls the amount of air directly sucked into the air conditioner;
Among the air heated by the heating element, a heating damper that controls the amount of air supplied to the area to be heated,
An indirect circulation damper that controls the amount of air drawn into the air conditioner from the heated area;
A temperature sensor for temperature rising air for measuring the temperature of the air heated by the heating element;
A heating area temperature sensor for measuring the temperature of the heated area;
An operation unit for inputting a set temperature of the area to be heated;
Based on signals from the temperature-increasing air temperature sensor, the heating area temperature sensor, and the operation unit, the direct circulation damper, the heating damper, and the indirect circulation damper are opened. And a control unit for controlling the degree, and
When the temperature of the heated area is lower than the set temperature of the heated area and the temperature of the air heated by the heating element is higher than the temperature of the heated area, the indirect The circulation damper is opened by a predetermined opening, the heating damper is opened by a predetermined opening, and the direct circulation damper is closed by a predetermined opening,
When the temperature of the heated area is higher than the set temperature of the heated area, and the temperature of the air heated by the heating element is higher than the temperature of the heated area, the direct An exhaust-heat-use energy-saving air-conditioning method, wherein the circulation damper is opened by a predetermined opening, the heating damper is closed by a predetermined opening, and the indirect circulation damper is closed by a predetermined opening.   A temperature sensor for intake air that measures the temperature of the air sucked by the air conditioner is used, and the control unit has a temperature of the air sucked by the air conditioner equal to or higher than the temperature of the cooled air blown out by the air conditioner. The exhaust heat utilization energy-saving air conditioning method according to claim 9, wherein the preferential control is performed. A temperature sensor for temperature rising air that is circulated by an air conditioner that cools the heating element and that is heated by the heating element, a temperature sensor for heating area that measures the temperature of the area to be heated, and Directly controlling the amount of air directly drawn into the air conditioner out of the air heated by the heating element based on a signal from the operation unit to which the set temperature of the area to be heated is input A circulation damper, a heating damper for controlling the amount of air supplied to the area to be heated among the air heated by the heating element, and air sucked into the air conditioner from the area to be heated In the control unit that controls each opening degree of the indirect circulation damper that controls the amount,
When the temperature of the heated area is lower than the set temperature of the heated area and the temperature of the air heated by the heating element is higher than the temperature of the heated area, the indirect A procedure in which the circulation damper is opened by a predetermined opening, the heating damper is opened by a predetermined opening, and the direct circulation damper is closed by a predetermined opening; and
When the temperature of the heated area is higher than the set temperature of the heated area, and the temperature of the air heated by the heating element is higher than the temperature of the heated area, the direct A waste heat-utilizing energy-saving air conditioner characterized in that the circulation damper opens by a predetermined opening, the heating damper closes by a predetermined opening, and the indirect circulation damper closes by a predetermined opening. program.   Based on a signal from a temperature sensor for intake air that measures the temperature of the air that the air conditioner sucks into the control unit, the cooled air that the air conditioner blows out the temperature of the air that the air conditioner sucks The waste heat utilization energy-saving air-conditioning program according to claim 11, wherein a preferential control procedure is executed so that the temperature is equal to or higher than a predetermined temperature.

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