SU1668819A1 - Air-conditioning system with automatic thermal and humidity control of supply air - Google Patents

Abstract

The invention allows to reduce energy costs and improve the quality of the heat-moisture composition of the air in the process of adjusting the air conditioning system. In the course of the air, two heat exchangers (TO) 1 and 2 of the first heating are in parallel, communicating with the forward 3 and the return 4 heat network lines. The thermostat 9 "dew point" is connected to the control circuit 10 with the regulating valve 11 at the inlet of the heat carrier (TH) from the heating network in TO 1 and with the valve 12 of the water circuit 6 of the contact apparatus 5. The thermostat of the fresh air 13 is connected to the control circuit 14 the valve 15 at the inlet of the heat pump from the heating system to TO 2. The output of the TN from TO 1 is connected to the input of the TN to TO 2. A control valve 16 is installed at the air inlet to TO 2. The output of the TN from TO 2 communicates with the input of the TH TO 7 second heating, output which is connected to line 4. Valves 15 and 16 at the entrances to TO 2 are connected by chains 14 and 10 s. thermostats 13 and 9. The control of the final temperature of the air supplied by the fan to the room was carried out with the aid of TO 7 by maintaining the temperature of the heat supply to it within 60 - 70 ° C. 1 il.

Description

The invention relates to air conditioning technology and can be used in air conditioning systems for various purposes.

The aim of the invention is to reduce energy costs and improve the quality of the heat-moisture composition of the air during the regulation process.

The drawing shows a schematic diagram of the air conditioning system with automatic regulation of the heat-moisture composition of the supply air.

The air-conditioning system with automatic regulation of the heat-and-moisture composition of the supply air contains heat exchangers 1 and 2 of the first heating in parallel along the air path, communicated with the forward 3 and reverse 4 heat lines, the contact device 5 with the water circuit 6, the heat exchanger 7 of the second heating, the inlet valve torus 8. thermostat 9 dew point, communicated by the control circuit 10 with a control valve 11 at the inlet of the coolant from the heating network to the first heat exchanger 1 of the first heating and with the valve 12 Lines 6 of the contact apparatus 5, supply air teomo-regulator 13 connected by a control circuit 14 with a control valve 15 at the inlet of the coolant from the heating network to the second heat exchanger 2 of the first heating. The output of the coolant from the first heat exchanger 1 of the first heating is connected to the input of the heat transfer medium to the second heat exchanger 2 of the first heating. The system further comprises a control valve 16 mounted at the air inlet to the second heat exchanger 2 of the first heating. The output of the coolant from the second heat exchanger 2 of the first heating is connected to the inlet of the heating medium of the heat exchanger 7 of the second heating, and the output of the latter is connected to the return line 4 of the heating system. The control valves of the heat carrier 15 and air 16 at the inlets to the second heat exchanger 2 of the first heating are connected by control circuits 14 and 10 respectively to the temperature controllers of the supply air 13 and the dew point 9.

The system works as follows.

The external supply air is passed through the heat exchangers 1 and 2 of the first heating, the contact apparatus 5. The heat exchanger 7 of the second heating, and then is supplied by the fan to the serviced room. At low ambient air temperatures, the supply air humidity is controlled by operating the contact device 5 in adiabatic mode.

The valve 12 of the water circuit 6 is open to allow water to pass into the contact apparatus 5. As the temperature drops down behind the contact apparatus 5, the dew point thermostat 9 commands the opening of the control valve 11. As a result, the flow of heat carrier along the direct line 3 of the heat network through heat exchangers 1 and 2 of the first preheating and the air temperature behind the contact apparatus 5 (as well as humidity) increases to the value set by the thermostat 9. When the supply air humidity increases, thermostat 9 gives a command to close the control valve 11.

As the outside air temperature increases and the supply air humidity increases, valve 11 closes and the control valve 16 enters the control process, which also closes when the outside air temperature rises and the supply air humidity decreases, reducing heat from the first heat exchanger 2 by heating the outside air through part of the outside air through disconnected heat exchanger 1. At a certain high ambient temperature, at the command of the thermostat 9, the control valve 16 will also close, resulting in All the air without heating through the heat exchanger 1 enters the contact apparatus 5. With a further increase in the outside air temperature, the temperature and humidity of the supply air is controlled by a valve 12, which regulates the temperature of the water entering the contact apparatus 5 by mixing water from the cold supply system and contact apparatus 5, going to drain. When the outside air temperature decreases at the command of the thermostat 9 of the dew point, the process of regulating the humidity of the supply air is carried out in the reverse order.

Compensation of the entrainment of water from the contact apparatus 5 is carried out along the line from the water supply system.

The control of the final temperature of the air supplied by the fan 8 to the room is carried out by means of the heat exchanger 7 of the second heating by keeping the temperature of the heat transfer medium entering it within 60-70 ° C. This is achieved by the thermostat 13, which commands the opening or closing of the valve 15. In this case, the thermostat 9 and the thermostat 13 are synchronously controlled.

As a result, the quality of the heat-moisture composition of the air is improved, i.e.

fluctuations in the heat and humidity parameters of the supply air are reduced. In addition, the use of the heat exchanger 7 of the second heating makes it possible to reduce the temperature of the coolant discharged into the return line 4 of the heating system, i.e. to increase heat supply per unit mass of the coolant, and this leads to a decrease in energy consumption for the transportation of the coolant.

Claims (1)

The invention The air-conditioning system with automatic regulation of the heat-and-humidity composition of the supply air contains two heat exchangers of the first heating parallel to the air flow, communicated with the direct and return lines of the heat network, the contact unit with a water circuit, the heat exchanger of the second heating, the supply fan, a dew point thermostat provided by a control circuit with a control valve at the inlet of the coolant from the heating network to the first heat exchanger of the first heating and with a valve in d Nogo circuit the contact apparatus and the supply air thermostat connected by a control circuit with a control valve at the inlet of the coolant from the heating network to the second the heat exchanger of the first heating, wherein the heat carrier output from the first heat exchanger of the first heating is connected to the heat carrier input to the second heat exchanger of the first heating, characterized by the fact that, in order to reduce energy costs and improve the quality of the heat-moisture composition of the air during the regulation process, the system additionally contains a control valve mounted on the air inlet to the second heat exchanger of the first heating, while the heat carrier output from the latter is connected to the heat carrier input of the second heat exchanger, the output of which is connected to the return line of the heat network, and the control valves of the heat carrier and air at the inlets to the second heat exchanger of the first heating are connected to the thermostat tori flow air and dew point.