JPH05322370A - Air conditioner - Google Patents

Abstract

PURPOSE:To obtain an air conditioner in which a temperature of the air at an outlet of a dehumidifying-cooling coil can be regulated to a predetermined dew-point without subcooling. CONSTITUTION:An air conditioner comprises dehumidifying-cooling coils 91, 92, 93 for cooling and dehumidifying intake atmosphere, condensers 131, 132, 133 connected to the coils 91, 92, 93, and a preheater 7 for heating the air to regulate temperature and humidity of the air passed through the coils 91, 92, 93. Waste heats of the condensers 131, 132, 133 are used as a heat source of the preheater 7.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner suitable for factories, such as semiconductor manufacturing factories and precision machinery factories, where it is necessary to strictly control the temperature and humidity of air.

[0002]

2. Description of the Related Art Generally, a conventional air conditioner for outside air using a compression type refrigeration cycle is provided with only a dehumidifying / cooling coil for taking in outside air, cooling it to a dew point temperature and dehumidifying it, or dehumidifying / cooling. It has been proposed that a reheater that warms the air that has passed through the dehumidifying / cooling coil to a target temperature is provided on the downstream side of the coil.

This type of air conditioner is designed to send out the air whose humidity and temperature have been adjusted through a dehumidifying / cooling coil and a reheater and further through a duct into the room to be conditioned. In this type, when the air in the conditioned room is circulated, the adjusted outside air is mixed.

According to this, the air taken in is first dehumidified by being cooled to the dew point of the target absolute humidity by the dehumidifying / cooling coil. At this time, a plurality of dehumidifying / cooling coils are used, and the number of operating compression type refrigeration cycles connected to each of them is controlled according to the temperature and humidity of the outside air taken in. The cooling capacity of the dehumidifying / cooling coil is such that it can cool to a temperature slightly below a predetermined dew point in order to obtain a target humidity. When the temperature drops below the dew point,
The reheater is used to heat that much, and the humidifier is used for humidification.

The air after air conditioning is sent out into the room to be conditioned through the duct, but the reheater is operated so that dew condensation does not occur in the duct and a desired temperature is obtained in the room to be conditioned. , Introduced into the duct.

[0006]

By the way, the temperature and humidity of the outside air vary greatly depending on the season and time. When the outside air is taken in to constantly obtain air having a predetermined dew point temperature, the capacity of the cooling device must be capable of being arbitrarily changed.

However, the compression refrigerating machine can only be controlled in steps such as unloader control and number control unless expensive rotation speed control is used. Therefore, when trying to obtain air with a low dew point that cannot be achieved unless the evaporation temperature of the refrigerant is low near the freezing point, delicate control does not work and frost is formed on the fins of the dehumidifying / cooling coil. Therefore, it was not possible to obtain air with a low dew point close to the freezing point, and dehumidification was possible only up to about 10 ° C.

Therefore, an object of the present invention is to control the temperature of the air at the outlet of the dehumidifying / cooling coil to a predetermined dew point without overcooling the dehumidifying / cooling coil, and to reduce power consumption. To provide an air conditioner.

[0009]

In order to achieve the above object, the present invention uses an exhaust heat of a compression refrigeration cycle in an upstream side of a dehumidifying / cooling coil in an air conditioner using a compression refrigeration cycle. Then, a preheater for warming the air flowing into the dehumidifying / cooling coil is provided.

In the air conditioner of the present invention, a control valve is provided in the heat medium path of the preheater, and even if the temperature and humidity of the taken-in air or the cooling capacity of the compression type refrigeration cycle changes, the dehumidifying / cooling coil flows out. It is desirable to provide a controller that controls the opening degree of the heat medium flow rate control valve so that the dew point temperature of the operating air is maintained at a predetermined value.

The cooling water warmed by the condenser of the compression refrigeration cycle can be used as the heating medium for heating the preheater.

Further, in the present invention, a reheater is provided downstream of the dehumidifying / cooling coil to reheat the air flowing out of the dehumidifying / cooling coil to an arbitrary temperature by utilizing the exhaust heat of the compression refrigeration cycle. You can also

[0013]

According to the present invention, the air taken into the air conditioner is cooled to the target dew point of the absolute humidity by the dehumidifying / cooling coil of the compression type refrigerating cycle, and after dehumidifying there, for example, a duct or the like. Through the air, the conditioned air of which humidity and temperature are adjusted is sent into the room to be conditioned. When the dehumidifying / cooling coils are operated, the number of compressors having a refrigerating capacity capable of keeping the air temperature at the outlet of the dehumidifying / cooling coils below the dew point temperature by operating the dehumidifying / cooling coils is operated. The preheater heats the intake air so that the air temperature at the outlet of the dehumidifying / cooling coil is exactly the dew point temperature, and this causes the air temperature at the outlet of the preheater, that is, the air temperature at the inlet of the dehumidifying / cooling coil. Is controlled. Then, when the heating by the preheater exceeds the cooling capacity of one compressor, the one compressor is stopped and the heating by the preheater is controlled to be reduced accordingly.

In the preheater according to the present invention, the air is warmed by utilizing the exhaust heat of the compression type refrigeration cycle. The energy provided to the refrigeration cycle includes a decrease in air energy in addition to electric power energy. Therefore, during operation of the refrigeration cycle, all of this is eventually exhausted, and the amount of exhaust heat of the condenser exceeds the cooling capacity of the refrigeration cycle operating at that time.

In such a case, the preheater uses a part of the cooling capacity of the refrigeration cycle, that is, a part of the exhaust heat amount of the refrigeration cycle.

The energy required for heating by the preheater is
It is determined by the cooling capacity of the refrigeration cycle operating at that time and the temperature and humidity of the outside air taken in.
Therefore, the cooling capacity, the temperature and humidity of the outside air, etc. are taken into the controller, and the energy required for heating in the preheater is calculated using this controller, and based on this, the refrigeration cycle is turned on and off, and the preheater is added. It is desirable to increase or decrease the amount of exhaust heat required for heating.

Further, for example, when the refrigerant (CFC 22 etc.) of the refrigeration cycle in the condenser is cooled with water and the cooling water heated by the exhaust heat of the condenser is guided to the preheater, the cooling water is introduced. It is desirable to provide a control valve in the path and adjust the valve opening of this control valve to increase or decrease the amount of exhaust heat required to heat the preheater.

The air whose latent heat is lowered by the dehumidifying / cooling coil is
To prevent condensation on the duct when sending it into the room to be conditioned through the duct, and to obtain the desired temperature there when mixing with the air in the room to be conditioned, the temperature should be slightly lower than the dew point temperature around the duct. A reheater for warming the air to the above temperature is provided, and the heat source of this reheater is
It is desirable to utilize the waste heat of the capacitor.

According to these, supercooling in the dehumidifying / cooling coil can be prevented, the temperature of the air at the outlet of the dehumidifying / cooling coil can be made to have a predetermined dew point, and furthermore, the air conditioning of the desired humidity / temperature can be achieved. In addition to being able to do so, effective use of energy is achieved and power consumption is reduced.

[0020]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the accompanying drawings.

In FIG. 1, reference numeral 1 indicates a unit case. The unit case 1 is provided with two dampers 3 for adjusting the amount of outside air introduced, and downstream of the dampers 3,
A filter 5 for removing dust contained in the outside air,
A preheater 7 for warming the outside air and three dehumidifying / cooling coils 9 ₁ , 9 ₂ , 9 ₃ for cooling and dehumidifying the air passing through the preheater 7 are provided.

These three dehumidifying / cooling coils 9 ₁ ,
9 ₂ and 9 ₃ are compressors 11 ₁ and
11 ₂ , 11 ₃ , capacitors 13 ₁ , 13 ₂ , 13 ₃ ,
And capillaries 15 ₁ , 15 ₂ and 15 ₃ are connected via a refrigerant pipe, and each of them constitutes a compression refrigeration cycle.

Dehumidifying / cooling coils 9 ₁ , 9 ₂ , 9 ₃
A reheater 17 and an electric heater 19 for reheating the air cooled by the dehumidifying / cooling coils 9 ₁ , 9 ₂ , and 9 ₃ are provided downstream of the reheater and the electric heater 19. Is provided with a fan 21 for creating an air flow.

Further, according to this embodiment, a cooling water cooling pipe 25 connected to the pump 23 for exchanging heat with the refrigerant flowing through the condensers 13 ₁ , 13 ₂ , 13 ₃ is provided. The pipe 25 is extended and connected to the preheater 7 and the reheater 9 described above. MV is a proportional control valve.

A humidity sensor S and temperature sensors T ¹ and T ² are provided at the entrance and the exit of the preheater 7 for dehumidification and
Cooling coils 9 _1, 9 _2, 9 ₃ of the temperature sensor T ₃ at the outlet
Are provided and each sensor is connected to the controller 27. The controller 27 turns on the _three compressors 11 ₁ , 11 ₂ , and 11 ₃ according to the detection value of each sensor,
While turning off, the valve opening of the proportional control valve MV is controlled.

Next, the operation of this embodiment will be described.

The outside air introduced into the unit case 1 through the damper 3 is cooled by the dehumidifying / cooling coils 9 ₁ , 9 ₂ , 9 ₃ to the dew point of the target absolute humidity, and is dehumidified by the preheater 7 in advance. Be heated. The outlet temperature of the dehumidifying / cooling coils 9 ₁ , 9 ₂ and 9 ₃ is controlled to about 7 ° C.
After that, it is heated by the reheater 17 and the electric heater 19, heated to 12 ° C., and sent out to the room to be conditioned. That is, according to this, the conditioned air controlled to the appropriate humidity and temperature is sent out into the to-be-conditioned room.

According to this, the hot water (cooling water) used as the heat source of the preheater 7 is the condenser 13 ₁ ,
Since it is warmed by the heat radiated from 13 ₂ and 13 ₃ (exhaust heat from the refrigeration cycle), energy can be effectively used and power consumption can be reduced.

FIG. 2 shows a processing flow in the controller 27.

First, when the outside temperature is detected by the temperature sensor T ₁ and the outside temperature is 19 ° C. or higher, three compressors are turned on (S ₁ ), and at 13 to 19 ° C., two compressors are compressed. The compressor is turned on (S ₂ ), and if it is 7 to 13 ° C., one compressor is turned on (S ₃ ). However, if the outside air temperature is 7 ° C. or lower, all the compressors are turned off (S ₄ ).

When the operation is continued in this state and about 60 seconds have passed (S ₅ ), the dehumidifying / cooling coils 9 ₁ , 9
₂ , 9 ₃ outlet temperature (value detected by temperature sensor T ₃ ) is 7 ° C
Whether the following is determined (S _6).

The outlet temperature of the dehumidifying / cooling coil is controlled with a target of about 7 ° C., and if it exceeds this, in order to lower the outlet temperature by using the dehumidifying / cooling coil,
The number of operating compressor increases one (S _7). However, if the number of operating compressors is increased by one, the outlet temperature of the dehumidifying / cooling coil becomes too low. Therefore, in order to compensate for that, the valve opening of the proportional control valve MV is expanded by a predetermined percentage (S ₈ ). ..

When it is determined in S ₆ that the detection value of the temperature sensor T ₃ is 7 ° C. or lower, whether the inlet / outlet temperature difference (T ₁ -T ₂ ) of the preheater 7 is 22 ° C. or lower. Is determined (S ₉ ).

The inlet / outlet temperature difference is 22 ° C. or more (22 ° C.
If it is determined that (not below), it means that the preheater 7 has overheated and the dehumidification / cooling coil has overcooled, so the number of operating compressors is first decreased by one (S ₁₀ ). At the same time, the valve opening degree of the proportional control valve MV is closed by a predetermined percentage (S ₁₁ ).

At S ₉ , the inlet / outlet temperature difference of the preheater 7 (T
₁₋ T ₂ ) is determined to be 22 ° C. or lower, in order to bring the inlet temperature of the dehumidifying / cooling coil (detection value of the temperature sensor T ₂ ) to the optimum temperature (target temperature T), the valve opening of the proportional control valve MV proportional control (S ₁₂ ~S _13).

However, the target temperature T at the inlet of the dehumidifying / cooling coil differs depending on the humidity of the outside air (detection value of the humidity sensor S) and the number of operating compressors.

That is, the dehumidifying / cooling coil cools the air,
Since it is for dehumidifying, for example, when the humidity of the outside air is high, in order to increase the dehumidifying amount (cooling amount) in the dehumidifying / cooling coil, the target temperature T is increased and the number of operating compressors increases. If there are many, 7 at the outlet of the dehumidifying / cooling coil
In order to obtain the air of ° C, the target temperature T is increased by that amount.

Therefore, when proportionally controlling the valve opening of the proportional control valve MV, in S ₁₂ , the target temperature T determined according to the number of operating compressors, the humidity of the outside air, etc. and the temperature sensor T _2. comparing the sensed actual outlet temperature of the preheater 7, in S _13, in accordance with the result of the comparison, so as to approximate the actual outlet temperature of the preheater 7 to the target temperature T, the proportional control valve MV valve Properly control the opening.

According to this, the controller 27 having the above-mentioned configuration is used to proportionally control the valve opening of the proportional control valve MV, so that the outlet temperature of the preheater 7 can be controlled by the number of operating compressors and the humidity of the outside air. Target temperature T required according to
Since it is possible to obtain a dehumidifying / cooling coil outlet, dehumidified air of approximately 7 ° C can be obtained at the outlet of the dehumidifying / cooling coil. Air can be forced into the conditioned room.

Next, specific examples will be given.

Temperature: 33 ° C., humidity: 60%, air volume: 50 m ³ /
Introduce a minimum of outside air, and set the temperature to 7 ° C and the humidity to 100.
Suppose that it is% air. Here, in terms of air ^{volume, 50m 3 /min×1.20Kg/m 3 × 60min /} hr = 3675Kg / hr ... (1) The temperature 33 ° C., a humidity of 60% air, temperature 7 ° C., a humidity of 100 The energy required to make the air of 1% is 14.5 Kcal / Kg (2) Therefore, from the equations (1) and (2), the temperature is 33 ° C. and the humidity is 60.
%, Outside air with an air volume of 50 m ³ / min, temperature 7 ° C, humidity 1
The energy required to make the air of 00% is 14.5 Kcal / Kg × 3675 Kg / hr = 53287 Kcal / hr (3) That is, the energy of 53287 Kcal / hr is required. To apply, 18000Kcal / hr (54000Kca in total) to each of the _three dehumidifying / cooling coils 9 ₁ , 9 ₂ and 9 _3.
Select one with a capacity of 1 / hr).

Here, as an example, when the outside air having a temperature of 20 ° C., a humidity of 80% and an air volume of 50 m ³ / min is introduced, first, three dehumidifying / cooling coils 9 ₁ , 9 ₂ , 9 ₃ are installed. It works, and the preheater 7 is worked by that much.

When the temperature difference before and after the preheater 7 exceeds 22 ° C., one dehumidifying / cooling coil is stopped and the valve opening of the proportional control valve MV is closed by 25%.

In this case, the target temperature T after the preheater 7 is
Is 32 ° C, the preheater 7 is controlled by the above control.
When the subsequent temperature reaches 36 ° C., the valve opening degree of the proportional control valve MV is controlled to be closed according to the difference between 32 ° C. and 36 ° C.

[0045]

As is apparent from the above description, according to the present invention, the temperature of the air at the outlet of the dehumidifying / cooling coil can be controlled to a predetermined dew point, there is no supercooling, and the desired air conditioning is achieved. As a result, the energy can be effectively used and the power consumption can be reduced.

[Brief description of drawings]

FIG. 1 is a system diagram showing an embodiment of an air conditioner according to the present invention.

FIG. 2 is a flowchart showing an example of a processing flow of a controller.

[Explanation of symbols]

7 Preheater 9 ₁ , 9 ₂ , 9 ₃ Dehumidifying / cooling coil 11 ₁ , 11 ₂ , 11 ₃ Compressor 13 ₁ , 13 ₂ , 13 ₃ Capacitor 15 ₁ , 15 ₂ , 15 ₃ Capillary 25 Cooling pipe MV Proportional control valve

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[Procedure amendment]

[Submission date] February 19, 1993

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be corrected] Figure 3

[Correction method] Added

[Correction content]

FIG. 3 is a flow chart showing an example of a processing flow of the controller as well.

Claims (3)

[Claims] 1. An air conditioner using a compression refrigeration cycle, for warming the air flowing into the dehumidification / cooling coil upstream of the dehumidification / cooling coil by utilizing exhaust heat of the compression refrigeration cycle. An air conditioner characterized by being provided with a preheater. 2. A dehumidification / cooling coil is provided with a control valve in a heat medium path, and the dehumidification / cooling is performed even if the temperature / humidity of the taken-in air or the cooling capacity of the compression type refrigeration cycle changes.
The air conditioner according to claim 1, further comprising a controller that controls a valve opening degree of the heat medium flow rate control valve so that the dew point temperature of the air flowing out from the cooling coil is maintained at a predetermined value. 3. A reheater is provided downstream of the dehumidification / cooling coil to reheat the air flowing out from the dehumidification / cooling coil to an arbitrary temperature by utilizing exhaust heat of the compression refrigeration cycle. The air conditioner according to claim 1, which is characterized in that.