RU2004886C1 - Air conditioning system with automatic control of temperature and moisture content in incoming air - Google Patents

Abstract

SUMMARY OF THE INVENTION: heat exchangers of the first and second heating are connected in series to the direct and return lines of the heating network. The dual valve is connected to control the return temperature thermostat. The output valve is connected to control successively between the water control valve and the dew point temperature controller. A mixing valve is connected in the heat supply line between the inlet of the first heating exchanger and its outlet after the outlet valve of the return coolant and is connected for control with the supply air temperature regulator. 1 ill.

Description

The invention relates to a technique for air conditioning, in particular, to regulating the heat and moisture content of fresh air.

A known air conditioning system is provided comprising first and second preheater heat exchangers connected to the forward and reverse heat supply lines, an irrigation chamber with a pump and a water circuit control valve connected to control a dew point temperature controller, and a dual forward and bypass air channel valve and an outlet valve for the return coolant of the first preheater heat exchanger, a supply air temperature regulator behind the fan.

The disadvantages of this system include low efficiency due to the use of a direct heating medium for both heating systems.

The closest technical solution is an air conditioning system, containing in parallel connected to the direct and return lines of the heating system of the heat exchanger of the first and second heating, an irrigation chamber with a pump and a control valve of the water circuit, connected to control with a dew point thermostat, dual air valves heat exchangers of the first and second heating and irrigation chambers, control valves of the return heat carrier of heat exchangers, a supply air temperature regulator behind the fan.

This system also has low efficiency due to the use of direct heat transfer medium on both heaters.

The purpose of the invention is to increase the efficiency of the system.

This goal is achieved by the fact that in the system containing the heat exchanger of the first and second heating connected to the direct and return lines of the heat supply system, an irrigation chamber with a pump and a water circuit control valve, connected to control with a dew point temperature regulator, a double direct valve and by-pass air ducts and the outlet valve of the return heat carrier of the heat exchanger of the first heating, the supply air temperature regulator behind the fan, additionally, the temperature control of the return heat transfer heat exchanger is introduced the first heater and the mixing valve, both heat exchangers being connected in series to the direct and return lines of the heat supply network, the dual valve is connected to control the return heat carrier temperature regulator, the outlet valve is connected to control sequentially between the irrigation chamber control valve and the dew point temperature regulator, and the mixing valve is connected between the input of the heat exchanger of the first heating and its output

after the outlet valve of the return coolant and is connected for control with the supply air temperature regulator.

In comparison with the prototype, the inventive object has novelty; its comparison

0 with other technical solutions in this and related fields of technology provides significant differences between the criteria of the invention.

The drawing shows the functional

5 circuit.

The proposed system includes heat exchangers 3 and 4 of the first and second heating connected to the forward and reverse lines 1 and 2 of the heating network, and an irrigation chamber 5 with

0 pump 6 and a regulating, for example, three-way, valve 7 of the water circuit, connected to control the temperature regulator 8 of the dew point, a double valve 9 of the direct and bypass air channels 10 and 11, and

5, the outlet valve 12 of the return heat carrier of the heat exchanger 3 of the first heating, the supply air temperature regulator 13 behind the fan 14, additionally introduced the temperature control 15 of the return heat exchanger of the heat exchanger 3 of the first heating and the mixing valve 16, both heat exchangers 3 and 4 of the first and second heating are connected to forward and reverse lines m 1 and 2 of the heating system in series,

5, a double valve 9 is connected for control with a return temperature thermostat 15, an output valve 12 is connected for control in series between the control valve 7 of the chamber 5 and the dew point temperature regulator 8, and a mixing valve 16 is connected between the input of the first heat exchanger 3 and its the output after the outlet valve 12 of the return coolant and is connected to control

5 with a temperature controller 13 of the supply air. The water circuit of the irrigation chamber 5 includes circuits 17, 18 and 19 of circulation, discharge and make-up, as well as direct and return cooling lines 20 and 21.

0 The air conditioning system operates as follows.

Outside air is sequentially passed through the heat exchanger 3 of the first heating (or bypassing it), the chamber 5 orifice 5, the heat exchanger 4 of the second heating. And the fan 14 is fed into the serviced room (not indicated).

In the cold season, the humidity of the supply air is controlled by the dew point temperature regulator 8 by influencing the return heat carrier outlet valve 12: when the dew point temperature decreases, the outlet valve 12 opens, increasing the flow rate of the heat carrier from the direct heat supply line 1 through the first heat exchanger 3, and closes when elevated. In this case, the irrigation chamber 5 operates in adiabatic mode. The three-way valve 7 is open to the passage of water from the circulation pipe 17 to the pump b, which feeds it through the discharge pipe 18 for spraying into the irrigation chamber 5. Compensation of the entrainment of water into the processed air is carried out via a recharge pipe 19, for example from a water pipe through a ball valve (not specified).

The temperature control of the return coolant at the outlet of the heat exchanger 3 of the first heating is carried out by the temperature regulator 15 at a certain minimum guaranteed against freezing (20-30 ° C) by acting on the double valve 9; when the return temperature decreases, the double valve 9 opens toward the bypass air channel 11 and closes towards the direct air channel 10, reducing heat removal on the heat exchanger by reducing the amount of air passing through it; and when rising, the double valve 9, on the contrary, closes towards the bypass channel 11 and opens towards the straight channel 10, increasing the heat removal on the heat exchanger 3.

A slight change in the temperature of the dew point due to the action of the double valve 9 is automatically restored by changing the position of the outlet valve 12, which opens and closes in phase with the change in the position of the double valve 9 upon the command of the temperature controller 8 of the dew point.

Supply air temperature is controlled by thermostat 13 by acting on the valve 16

admixture: when supply air temperature drops, valve 16 opens, adding the necessary amount of direct heat carrier from line 1 to the input of heat exchanger 4 of the second heating, and closes when it increases.

As the outside temperature rises, valve 9 opens toward the bypass channel 11, and valve 12 closes

0 Finally, at a certain temperature, when the outside air is not required to be heated, the outlet valve 12 will close completely, excluding the coolant on the first heating, and the valve 16 will ensure that the necessary amount of coolant is let out of the direct heat supply line 1 to maintain the set supply air temperature.

In the warm season, when the outlet valve 12 is completely closed, for example, through its limit switches (not specified), the dew point thermostat 8 is switched to control the three-way valve 7. When the dew point temperature rises

5, valve 7 opens toward the direct cooling line 20, and closes with an increase. Surplus water from the influx of cold water from the direct line 20 of the system is cold-condensed and moisture condensation from

0 of the treated air in the irrigation chamber 5 is returned by gravity through the return line 2 I to the cooling system.

Supply air temperature control is carried out as in cold

5, the period of the year by the temperature controller 13 acting on the valve 16.

Thus, the proposed air conditioning system has high quality and economic performance and can operate stably at different temperature schedules of the heating system in a wide range of outdoor temperatures.

5 (56) Copyright certificate of the USSR No. 1529018, cl. F24 F 11/00.

Claims (1)

The claims AUTOMATIC CONTROL SYSTEM OF HEAT AND HEAT CONTAINER OF PRINT AIR, containing heat exchangers of the first and second heating connected to the direct and return lines of the heating system, an irrigation chamber with a pump and a water control valve a circuit connected to control with a dew point thermostat, a double valve of the direct and bypass air channels and an outlet valve of the return heat carrier of the heat exchanger of the first heating, a supply air temperature regulator behind the fan, characterized in that the system further comprises a temperature regulator of the return heat exchanger of the heat exchanger first heater and valve a mixture, while the heat exchangers of the first and second heating are connected to the direct and return lines of the heating system in series, the double valve is connected for control with the temperature regulator of the return coolant, the outlet valve is connected for control in series between the control valve of the water circuit and the dew point thermostat, and the mixing valve is connected to the heat supply line between the inlet of the first heating exchanger and its outlet after the outlet valve of the return coolant and is connected to control the supply air thermostat,