KR101254935B1 - High efficiency homoiothermic humidistat for clean room utilizing waste heat air conditioner for precision control - Google Patents

Abstract

The present invention relates to an air conditioner for controlling the temperature and humidity of the air supplied to the clean room of the semiconductor manufacturing equipment, and in particular, by recovering the waste heat discharged to the atmosphere from the existing air conditioning system to supply energy as a separate energy of the waste heat Humidity can be controlled without using the waste heat, and the dehumidification load of the evaporator is changed according to the change of the indoor load or the outside load by separating the waste heat reuse coil and the condensation coil in multiple stages. An air conditioner for precise control of a high efficiency clean room thermo-hygrostat.

Description

High efficiency homoiothermic humidistat for clean room utilizing waste heat air conditioner for precision control

The present invention relates to an air conditioner for controlling the temperature and humidity of the air supplied to the clean room of the semiconductor manufacturing equipment, and in particular, by recovering the waste heat discharged to the atmosphere from the existing air conditioning system to supply energy as a separate energy of the waste heat Humidity can be controlled without using the waste heat, and the dehumidification load of the evaporator is changed according to the change of the indoor load or the outside load by separating the waste heat reuse coil and the condensation coil in multiple stages. An air conditioner for precise control of a high efficiency clean room thermo-hygrostat.

In general, manufacturing of articles such as semiconductors and liquid crystal displays is performed in a clean room where high cleanliness is maintained. On the other hand, the outside air conditioner is used to prevent the inflow of dust or pollutants through the air flowing into the clean room, and to adjust the temperature and humidity of the incoming air to the optimum conditions (12 ℃ 90%).

On the other hand, most of the energy required in the manufacturing process of semiconductors and liquid crystal displays (about 90%) is electric power, of which 40% is consumed by air conditioning equipment, and most of the power consumed by air conditioning equipment is configured as described above and is clean. It is used to operate the outside air conditioning system to handle the outside air introduced into the room.

Therefore, it is possible to expect a very large energy saving effect only by reducing the external load and reducing the power used in the external air conditioner.

Accordingly, many studies have been conducted on how to reduce energy by reducing external load by recovering heat from the exhaust discharged from the clean room and using it for preheating or precooling the introduced outside air.

However, in the case of the outdoor air conditioner, there is a problem in that it is not enough to satisfy the demand for energy saving simply by preheating or precooling the introduced outdoor air by recovering the heat of the exhaust as a considerable amount of energy is consumed.

In addition, the clean room has a large cooling energy load and high humidity in the summer outside, so the dehumidification load occupies most of the room. Therefore, most of the clean room is composed of a system of cooling dehumidification and reheating by separate heating. The problem of dehumidification is that the indoor setting temperature and humidity are supercooled to a corresponding dew point temperature and dehumidified, and then reheated to an appropriate temperature, and energy consumption is caused by the opposite action of cooling and heating.

SUMMARY OF THE INVENTION An object of the present invention for solving the above problems relates to an air conditioning apparatus for controlling the filtration and temperature and humidity of air supplied to a clean room of a semiconductor manufacturing facility, in particular to recover the waste heat emitted to the atmosphere from the existing air conditioning system By controlling the humidity without supplying energy as much as the energy of the waste heat, the waste heat reuse coil and the condensation coil are divided into STEP stages and the dehumidification load of the evaporator is changed according to the change of the indoor load or the outside load. Waste heat is used to effectively control change precisely. To provide an air conditioning system for precise control of a high efficiency clean room thermo-hygrostat.

Features of the air conditioner for precise control of the high efficiency clean room constant temperature and humidity chamber using waste heat according to the present invention for achieving the above object, the evaporator for air conditioning the inlet air, on / off to control the cooling capacity of the evaporator A condenser for cycling, a conduit for circulating refrigerant between the evaporator and the condenser, a valve for controlling the flow path of the refrigerant flowing through the conduit, and the conduit, which is generated according to the operation of the evaporator and the condenser An air conditioning system having a heat accumulator and a compressor that accumulate extra thermal energy in heat, wherein the condenser has a plurality of refrigerant condensing means and is equally distributed with the refrigerant flowing therein to condense operation, respectively. Refrigerant is provided by a plurality of valves for turning on and off the refrigerant discharge by a control signal. It is configured to allow fine control efficiency; And a plurality of refrigerant reheating means for reheating the refrigerant to control the expansion of the refrigerant so as to influence the discharge air temperature by a control signal according to the operation of the heat storage and the compressor and the amount of waste heat discharged according to the operation of the evaporator. A reheating heater configured to control finely the refrigerant heating efficiency by providing a plurality of valves for equally distributing the refrigerant to be re-heated and having a plurality of valves on / off of the refrigerant discharge by a control signal in front of each refrigerant reheating means; A plurality of solenoid valves positioned between conduits for supplying the waste heat discharged according to the operation of the heat storage unit and the compressor to the reheating heater side and controlling the amount of refrigerant transferred to the reheating heater side; Three-way valves respectively provided on the refrigerant input / output conduit of the condenser to change the opening and closing direction according to a proportional control signal; A humidifier for distributing fine water droplets in selected portions of the air-conditioned inlet air to affect exhaust air humidity; And a subheater configured to reheat a selected portion of the air-conditioned inlet air so as to affect the exhaust air temperature when the efficiency of the waste heat utilization control is extremely low.

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As expected effects due to the above-described features of the present invention, the humidity of the outside air is high in summer, and in the process of dehumidification, the temperature is lowered by supercooling to reheat, which consumes a lot of thermal energy. In the present invention, the waste heat of the outdoor unit generated in the process is discharged to the atmosphere, but in the present invention, the waste heat emitted to the atmosphere is recovered to control humidity without supplying energy as much as the energy of the waste heat, and also to recover the waste heat of the outdoor unit. Reheating compensates for overcooled temperatures and expects the additional effect of keeping the proper conditions constant.

Furthermore, by separating the waste heat reuse coil and the condensation coil into multiple stages, the dehumidification load of the evaporator is changed according to the change of the indoor load or the outside load, so that the heat change generated in the condenser can be controlled precisely and precisely.

1 is a detailed configuration and system example of an air conditioning apparatus for precise control of high efficiency clean room constant temperature and humidity using waste heat according to the present invention
2 and 3 is a conceptual diagram for explaining a control method of the air conditioner for precise control of the high efficiency clean room constant temperature and humidity using waste heat according to the present invention

 BRIEF DESCRIPTION OF THE DRAWINGS The above and other objects and advantages of the present invention will become more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings, in which: FIG.

First of all, when looking at the technical concept applied to the present invention, the humidity in the summer outside the high humidity in the process of dehumidification during the dehumidification, the temperature is lowered by the reheating is consumed a lot of heat energy, the existing air conditioner is generated in the process of cooling the air Although the waste heat of the outdoor unit was released into the atmosphere, the present invention is intended to recover the waste heat discharged to the atmosphere to control the humidity without a separate energy supply as energy of the waste heat.

In addition, it is expected that the additional effects of recovering and reheating the outdoor unit's waste heat to correct the supercooled temperature and to keep the proper conditions constant.

Furthermore, in order to more precisely control a series of operations to recover and control the waste heat, the condenser and reheater constitute a condenser and reheater in multiple stages, and the input / output amount of the refrigerant is controlled in the input / output terminals of each component composed of multiple stages. By providing a valve for performing on / off operation by a control signal, fine control is established.

1 is an air conditioner for precise control of a high-efficiency clean room constant temperature and humidity chamber using waste heat according to the present invention. In summer, when humidity is high, relative humidity is required to increase the relative humidity when the outside air is supplied into the clean room. The cooling and dehumidification operation is performed in the air conditioner to lower the room temperature and to heat the temperature to compensate for the temperature.

Therefore, in the cooling and dehumidification operation mode, the heat discarded from the outdoor unit is recycled to the air conditioner, and the temperature coefficient of the condenser is lowered, thereby improving the freezing coefficient of the refrigerator.

An evaporator 230 for air conditioning the inlet air, a condenser 110 for on / off cycling to control the cooling capacity of the evaporator 230, and a refrigerant circulation between the evaporator 230 and the condenser 110 Between the conduit 140, a valve for controlling the flow path of the refrigerant flowing through the conduit 140 (not given), and the conduit 140 and located between the evaporator 230 and the condenser. The heat accumulator 130 and the compressor 120 that accumulate extra thermal energy in heat generated by the operation of the 110 has a basic configuration.

At this time, the condenser 110 is provided with a plurality of refrigerant condensation means and by receiving the equally distributed refrigerant is condensed operation respectively, but having a plurality of valves on and off the refrigerant discharge by a control signal at the rear end of each refrigerant condensing means by It is configured to finely control the refrigerant condensation efficiency.

In addition, the three-way valve (A, B) is provided on each of the refrigerant input and output conduit 140 of the condenser 110 to change the opening and closing direction according to the proportional control signal.

The refrigerant is controlled to control the expansion of the refrigerant to influence the exhaust air temperature by a control signal according to the operation of the heat storage 130 and the compressor 120 and the degree of waste heat discharged according to the operation of the evaporator 230. A reheat heater 210A configured to reheat is provided. The reheat heater 210A also includes a plurality of refrigerant reheating means and is equally distributed to the refrigerant to be reheated, respectively, by a control signal at the front end of each refrigerant reheating means. By providing a plurality of valves for turning on and off the refrigerant discharge is configured to enable fine control of the refrigerant heating efficiency.

At this time, it is located between the conduit 140 for supplying the waste heat discharged according to the operation of the regenerator 130 and the compressor 120 to the reheating heater 210A side and the amount of refrigerant delivered to the reheating heater 210A side. A plurality of solenoid valves 220 for controlling are provided and include a humidifier 240 for distributing fine water droplets in selected portions of the air-conditioned inlet air to affect the exhaust air humidity.

Compressor 120 of the configuration is used for the compression of the refrigerant gas to be supplemented to the refrigerant cycle to compensate for the lack of refrigerant constituting the reverse circulation cycle or when the compression pressure of the refrigerant is loosened.

In addition, there was further provided a subheater 210B configured to reheat a selected portion of the air-conditioned inlet air to affect the exhaust air temperature, which corresponds to a heater core of the prior art and uses waste heat control according to the invention. It is used when the efficiency of is extremely reduced.

As shown in FIG. 2 and FIG. 3, the control method of the air conditioner for precise control of the high efficiency clean room constant temperature and humidity controller using waste heat according to the present invention having the configuration and characteristics as described above is illustrated in FIG. 1. It is controlled by the temperature sensor of (1) or the temperature and humidity sensor of (3), the reheater 210A of Figure 1 is controlled by the temperature sensor of (2) of Figure 2, the sub-heater ( In the temperature control by the air temperature (FAN Part) or the temperature-humidity sensor of FIG. 2 after passing through 210B), this is controlled by a PLC (Program Logic Controller) or a DDC (Direct Digital Controller).

In addition, as shown in FIG. 3, the heat source control of the reheater 210A of FIG. 1 by the temperature sensor No. 2 in FIG. 2 is controlled by the valve (A) or (B) of FIG. 1. It is implemented as a method for proportionally controlling the flow rate of the refrigerant flowing into the condenser 110 and the flow rate of the discharged refrigerant, and the multi-step STEP valve control of the solenoid valve 220 of Figure 1, in connection with the above two methods You can also control it.

Therefore, even without the heater core configured to reheat the selected part of the air-conditioned inlet air in order to affect the exhaust air temperature in the conventional method, the reheater 210A alone can perform the function of the conventional heater core and reheat. The degree of condensation can be finely adjusted to increase efficiency.

In addition, by separately providing a humidifier to control the humidity.

While the invention has been shown and described with respect to the specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims. Anyone with it will know easily.

Claims (4)

An evaporator for air conditioning the inlet air, a condenser for cycling on / off to control the cooling capacity of the evaporator, a conduit for refrigerant circulation between the evaporator and the condenser, and a flow path of the refrigerant flowing through the conduit In an air conditioning system having a valve for controlling and a regenerator and a compressor located between the conduits and accumulating extra thermal energy in heat generated by the operation of the evaporator and condenser:
The condenser is provided with a plurality of refrigerant condensing means and the equally distributed refrigerant is condensed operation respectively, but a plurality of valves on the rear end of each refrigerant condensing means by the control signal on and off the refrigerant discharge condensation efficiency Configured for fine control;
And a plurality of refrigerant reheating means for reheating the refrigerant to control the expansion of the refrigerant so as to influence the discharge air temperature by a control signal according to the operation of the heat storage and the compressor and the amount of waste heat discharged according to the operation of the evaporator. A reheating heater configured to control finely the refrigerant heating efficiency by providing a plurality of valves for equally distributing the refrigerant to be re-heated and having a plurality of valves on / off of the refrigerant discharge by a control signal in front of each refrigerant reheating means;
A plurality of solenoid valves positioned between conduits for supplying the waste heat discharged according to the operation of the heat storage unit and the compressor to the reheating heater side and controlling the amount of refrigerant transferred to the reheating heater side;
Three-way valves respectively provided on the refrigerant input / output conduit of the condenser to change the opening and closing direction according to a proportional control signal;
A humidifier for distributing fine water droplets in selected portions of the air-conditioned inlet air to affect exhaust air humidity; And a sub-heater configured to reheat selected portions of the air-conditioned inlet air so as to affect the exhaust air temperature when the efficiency of waste heat utilization control is extremely low. Air conditioner for precision control of humidifier. delete delete delete

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