KR19990081059A - Low temperature cold wind air conditioning system of building - Google Patents

Abstract

The present invention relates to a cooling air conditioning system of a building, and to increase the cooling efficiency compared to the conventional cooling system to make the cooling air at low cost.

In a conventional building cooling system, the cooling water generated from the freezer, which is a low temperature heat source generator, is passed through a heat exchanger to raise the temperature to a certain level, and then passes through an air conditioner that raises the temperature to a temperature that can be supplied to the room. In the present invention, the cold heat is directly generated from the cooling water from the low temperature heat source generator, and then the temperature is appropriately adjusted through the air mixing unit installed on the ceiling of the room. The present invention relates to a low-temperature cold air conditioning system that is capable of supplying a room to a room, and has an excellent cooling efficiency compared to the prior art, and to perform an air conditioner and other facilities that create cold air on a small scale.

Description

Low temperature cold wind air conditioning system of building

The present invention relates to a low temperature cold wind air conditioning system of a building, and more particularly, to a low temperature cold wind air conditioning system using ice heat storage.

The present invention is installed in the ceiling air mixing unit for supplying cool air to the interior of the building, the air conditioning unit is installed in the machine room to create a part of the cold air to be supplied to the room, and the air mixing unit installed on the ceiling of the room The present invention relates to a low-temperature cold air conditioning system that partially connects an air discharge pipe for discharging indoor air to an air conditioner installed in a machine room to increase cooling thermal efficiency and to partially cool each room of a building.

In a conventional building cooling system, a conventional refrigerator using a refrigerant and a refrigeration apparatus associated with it are equipped with a low temperature heat source generator, a heat exchanger for absorbing cold heat from the cooling water supplied from the refrigerator, and a cooling water passing through the heat exchanger. An air conditioner is installed to create cold air to be supplied from the room to the room.

In addition, from the cooling water supplied from the low temperature heat source generator inside the building, the hot air in the room is provided with a heat exchanger that partially replaces the cool air in each room inside the building, or the air supply duct connected to the air outlet supplying the outside air of the building. Connected to the air conditioner to remove foreign substances such as dust through the air conditioner's filter, and then mix cold air heat-exchanged on the coil surface of the air conditioner, and then blow it through the air supply duct It operates a centralized cooling system to supply air outlets.

In this conventional centralized cooling system, each room of the building starts cooling at the same time or stops cooling at the same time.

Therefore, the conventional centralized cooling system causes a lot of energy waste because it cools the whole building regardless of whether there is a person in the room, and it is necessary to cool or partially cool a part of each room arbitrarily.

As shown in FIG. 2, the conventional cooling system does not use the cooling water supplied from the low temperature heat source generator 101, but raises the temperature of the cooling water to a predetermined level through the heat exchanger 102, and then adjusts the air. Since it has a structure that makes the cold air of the temperature to be supplied to the room by passing through the coil installed in the machine, the heat loss is excessively generated, a large-capacity air conditioner 103 is required, excessive cost was required.

That is, the temperature of the cooling water generated from the ordinary low temperature heat source device 101 has a low temperature of 0-3 ° C., but the cooling water of such a low temperature passes through the heat exchanger 102 and the cooling water of 7-10 ° C. Then, it is raised to a temperature of 13-15˚C which can supply the indoor air introduced into the air conditioner 103 through the heat exchange coil of the air conditioner 103 to supply it to the room.

Therefore, when passing the air conditioner 103 directly without passing the low cooling water of 0-3 ° C generated from the low temperature heat source generator 101 to the heat exchanger 102, heat of 2-7 ° C is not lost. Therefore, it becomes possible to configure a cooling system that can increase the thermal efficiency.

The present invention removes the heat exchanger that is always installed in the conventional low temperature cold air conditioning system, installs a separate air mixing unit on the ceiling of the building to increase the heat exchange efficiency, while allowing the building to be partially cooled in each room or each floor. .

The present invention adopts a cooling method that allows the cooling water supplied from the low temperature heat source generator to pass through the air conditioner directly without passing through a heat exchanger to be supplied to the room through an air mixing unit that creates low temperature air and creates air in the conditions required for the room. The air mixing unit is installed on the ceiling of the room where the air conditioner is installed in the machine room to make low-temperature air by mixing coolant of 0-3˚C from the low temperature heat source device with the air. It is possible to control the air to the required amount and temperature, the air mixing unit and the air conditioning unit of the machine room is to increase the energy saving efficiency by mixing the air in the room through the air mixing unit installed on the ceiling.

In addition, by directly using low-temperature cold water can reduce the size of the pump and pipes, and because the use of low-temperature air can also increase the amount of air that passes through the same area can greatly reduce the size of the duct. Therefore, the initial investment costs can be significantly reduced.

1-Configuration diagram of the present invention.

2 is a block diagram of a conventional cold air conditioning system of a building.

The coolant made from the low temperature heat source generator 11 is supplied to the heat exchange coil 13 of the air conditioner 12, and the air conditioner 12 discharges the fresh air supply pipe 14 into which the outdoor air is introduced and the indoor air. It is connected to the exhaust air pipe 15, the cooling air made through the air conditioner 12 is connected to the air mixing unit 31 installed in the ceiling 21 of each room through the duct 17, Inside the air mixing unit 31 has a damper 32 and a blower 33 for adjusting the air volume by the temperature of the room and the amount of cooling air to be supplied, the air mixing unit 31 has a plurality of supply pipes (34) After supplying the mixed air to the room 22 through the air, the air in the room 22 flows into the ceiling 21 through the exhaust pipe 24, and part of the filter 35 to the air mixing unit 31 Is supplied through, part is to be supplied to the air conditioner 12 through the air discharge pipe (15) will be.

In the above, the low temperature heat source generator 11 may be configured as a refrigerator using a normal refrigerant, but a low temperature generator using ice storage heat that freezes water using low-cost late-night power and obtains cold air or cooling water during the day. .

In the figure, reference numeral 18 is a blower, 19 is a filter, and 20 is a pump.

The present invention configured as described above will act as follows. Cooling water of 0-3 ° C generated from the low temperature heat source generator 11 is introduced into the outdoor air and the indoor air discharge pipe 15, the heat exchange coil 13 of the air conditioner 12 is supplied to the outside air supply pipe (14). Cooling air is reduced to 7-10 ° C by the discharged air, which is the air mixing unit 31 installed in the ceiling 21 above the room 22 through the blowing fan 18 and the duct 17 Will be transferred to.

The cooling air introduced into the air mixing unit 31 is mixed with the high temperature indoor air introduced through the filter 35 to be introduced into the room 22 through the blower 33 and the plurality of air supply pipes 34. Turn The dam wave 32 is installed inside the air mixing unit 31, and blocks the cooling air introduced into the air mixing unit 31 by the dam wave 32, or arbitrarily adjusts the amount thereof.

The temperature of the discharged air and the cooling air in the room introduced into the air mixing unit 31 through the filter 35 is 13-15 ° C., and the mixture is supplied to the room 22 through the blower 33. will be. The discharged air that has not been introduced again into the air mixing unit 31 is partially discharged to the outside through the air discharge pipe 15, and part of the discharged air is introduced into the air conditioner 12 again.

In the present invention, since the damper 32 of the air mixing unit 31 installed indoors or on the ceiling can be opened and closed, it can be operated when necessary and can be stopped when it is not necessary. Energy savings can be achieved.

It is possible to operate the cooling system at a lower cost when using the cold storage heat in the low temperature heat source generator than the low temperature heat source generator 11 using a refrigerator using a general refrigerant. Ice storage heat is used to cool the water in the daytime by using the idle power of the night to cool the water, so when used in this way it is possible to obtain a cold air cheaper than the general heat source equipment.

According to the present invention, since the indoor air is directly cooled by using the low temperature air generated from the low temperature cooling water, the difference in the room temperature and the exit temperature of the coil has a difference of up to 2 times compared to the conventional air conditioning system.

That is, from the thermal formula Q = GCΔTΔt = t ₂ -t ₁ (G = mass, Q = energy, C = specific heat, t = temperature), the indoor air (t ₂ ) and the air conditioner of the conventional air conditioning system temperature difference t ₂ -t of the outlet temperature (t ₁₎ of the coil temperature t ₁ = △ t is obtained from the directly obtained from the cooling water outlet of the coil and the cooling water temperature t ₁ of the air conditioner in the present invention, if having a difference 10˚C _0, that _{is, t 1 -t 0 = △ t} 1 is exhibits a temperature difference between the end △ t ₁ + △ t = 20˚C therefore have a 10˚C difference it is possible to obtain a high cooling efficiency with little or no heat loss .

Since the air conditioner 12 passing 0-3 ° C. low temperature coolant has a very low moisture content as compared to the conventional air conditioning system, the room can be made more comfortable. In the summer, the hot air in the air conditioner's coil is not comfortable due to high humidity, and in order to lower the humidity, a dehumidifier is used in a conventional cooling system. However, in the present invention, a dry cold air is directly supplied to a room. This allows the effect of not requiring a dehumidifier.

According to the present invention, since the blower of the air conditioner that supplies air to the room has a low specific heat of air, it is possible to operate at a low static pressure, so that a blower having a small size and low energy consumption can be selected. In addition, since the same cooling efficiency can be obtained even if the diameter of the duct is made smaller than before, the building construction cost and maintenance cost can be lowered.

Claims (2)

The low temperature cooling water produced from the low temperature heat source generator 11 is supplied to the heat exchange coil 13 of the air conditioner 12, and the air conditioner 12 supplies fresh air supply pipe 14 and indoor air into which outdoor air is introduced. It is connected to the discharge air pipe 15 for discharging, the cooling air made through the air conditioner 12 is connected to the air mixing unit 31 installed in the ceiling of each room through the duct 17, the air Inside the mixing unit 31 has a damper 32 and a blower 33 for adjusting the air volume by the temperature of the room, the cooling air temperature to be supplied and the supply amount, the air mixing unit 31 has a plurality of supply pipes (34) ) To supply the mixed air to the room 22 through the air, and the air in the room 22 flows into the ceiling 21 through the exhaust pipe 24, and then passes through the filter 35 to the air mixing unit 31. Part is supplied to the air conditioner 12 through the air discharge pipe 15. Low-temperature cold air ventilation system of a building, characterized in that to. The low temperature cold air conditioning system of claim 1, wherein the low temperature heat source generator uses ice heat storage.