SE514849C2 - Arrangement with air treatment plant - Google Patents

Abstract

The arrangement comprises batteries (2,3). To the batteries are connected at least two circulation circuits, which by control valves (7-10) are selectively connectable to the batteries. The first circulation circuit is connectable to the batteries for heat recovery and the second circulation circuit is connectable to the batteries via a separate cooling circuit containing an evaporator (12) and a condenser (13) for comfort cooling. A unit set is directly connectable to the batteries and incorporates the circulation circuits. The first circulation circuit in its feed conduit to the input air battery incorporates a circulation pump (14) and a regulating valve for adjustment of the actual flow and in its return conduit from the output air battery a three-way valve (22) and a temperature indicator (27) which controls the three-way valve for regulating the circuit temperature.

Description

~ f isf1a4, àk4 <> 2 winter and summer with one and the same system. The unit contains all the necessary components. This entails both a simple dimensioning and installation and - in addition - a lower price overall. By means of the unit according to the invention, two functions have thus been achieved combined in a compact, prefabricated unit, J which results in a very barrel-free installation.

The invention is described in more detail below by means of a preferred exemplary embodiment and with reference to the accompanying drawings, in which Fig. 1 shows a schematic wiring diagram for an air treatment plant, comprising a first embodiment of a unit assembly according to the invention, when the plant is operated for heat recovery, ie: during the winter, Fig. 2 shows the sehemate shown in Fig. 1, when the air treatment plant is operated to provide cooling during the summer, Fig. 3 shows a schematic illustration of how an air treatment plant can see out, when this is connected to a unit assembly according to the invention, and Fig. 4 shows a schematic coupling element for components included in a unit assembly according to an alternative embodiment of the invention.

Figs. 1-3 show an air treatment plant 1 for heat recovery and comfort cooling of indoor air, which comprises a battery 2 for supply air and a battery 3 for exhaust air. A unit assembly 4 is directly connected to these batteries, which has two circulation circuits 5 3 and 6. These circuits 5 and 6 can be optionally connected to control batteries 7, 8, 9 and 10 with respective batteries 2, 3. Fig. 4 shows a modified embodiment of a unit 1 assembly 4 according to the invention, in which its connections 17, 18 and 19, 20 are easily collapsible to the batteries 2 and 3 and associated lines 15, 15 'and 16, 16'. The first circulation circuit 5 is connected by means of the control valves 17-10 to the batteries 2 and 3 during heat reproduction and the second circulation circuit 6 can be connected via the control valves 7-10 to the same batteries 2 and 3 via an evaporator 12 and condenser 13 included in a separate cooling circuit 11 at comfort cooling. ' The first circulation circuit 5 comprises in its supply line 15, 16 to the supply air battery 2 a circulation pump 14 and a control valve 21 for setting the current flow and in its return line 15 ', 16' to the exhaust air battery 3 the three-way valve 22 and a temperature sensor 27 for controlling the valve 22 for regulating the temperature of the circuit 6 by mixing the flows from the line 16 "and a branch line 16 '" from the line 16. In order to control the various components included in the unit there is an internal control computer 23 with inputs 24, 25 and 26 for power supply (400- '3-50), control impulse heat (0-10 V) and control impulse cooling (o-io »v).

Control impulse for heat recovery and comfort control f is given to the internal control computer 23 in the unit 4, In the heat recovery case, which occurs during the winter half of the year, a control signal (0-10 V) is used from external control equipment, which is sent to the unit 4's internal control 23, which controls the unit for controlling water, i.e. the first circulation circuit 5, containing glycol, between the exhaust air battery 2 and the supply air battery 3 for heat recovery. In this case, a control signal from the internal computer 23 influences the three-way valve 22 to open and close, respectively. In case of danger of frost freezing in the exhaust air battery 3, the temperature sensor 27 controls the return temperature to the exhaust air battery 3 to increase. Heat recovery during the winter months takes place in the following way and is shown in more detail in Fig. 1.

The control signal from the external control equipment is given to the unit 4, when there is a need for heat recovery in the air treatment plant 1. When the control signal exceeds 0.1 V, the internal control computer 23 controls the circulation pump 14 to start and opens the control valves 7 and 8 and closes the control valves 9 and 10. of the current first circulation circuit 5, which may contain 30% water / glycol mixture, takes place from the exhaust air battery 3 to the connection 17 on the unit assembly 4 and via the control valve 21 for setting the current flow to the circulation pump 14 and via the connection 19 to the supply air battery 2, where the energy is released. From the supply air battery 2 the water / glycol mixture then flows through the line 16 'via the connection 20 in the unit assembly 4 via the three-way valve 22 to the connection 18 and further to the exhaust air battery 3 through the line 15', where energy is absorbed from the exhaust air. A temperature sensor 27 controls the three-way valve 22 via the control computer 23, so that a set minimum temperature can be maintained on the circuit of the exhaust air battery 3 to prevent the risk of freezing. An external control signal 0-10 V controls the three-way valve 22 to open and close, respectively.

As for the case of comfort cooling of the air treatment plant during the summer, a control signal (0-10 V) is used from external control equipment to the unit control unit 23's internal control computer 23, which controls the unit for circulating water / glycol circuit (refrigerant) between the evaporator 12. and the cooling battery 2 in the supply air and between 349 the condenser 13 and the coolant battery 3 in the exhaust air. The control signal causes the three-way valve 22 to open and close, respectively. The temperature sensor 27 starts and stops a compressor 28 present in the cooling circuit 11 after the set temperature. Furthermore, there is a temperature sensor 29, which controls the valve 9 to keep the set temperature of the outgoing refrigerant from the evaporator 12, and a temperature sensor 31, which controls the valve 10 to maintain the set temperature of the outgoing refrigerant from the condenser 13. The unit assembly 4 operates on the following way in the comfort cooling case and is shown in more detail in Fig. 2.

A control signal (0-10 V) from the external control equipment is given to the unit 23 of the unit unit 4, when there is a need for comfort cooling in the ventilation system 1. When the control signal exceeds 0.1 V, the computer 23 controls the circulation pump 14 to start and close the control valves 7 and 8 and open the control valves 9 and 10 to the set value (approx. 20% open). The circulation of the sub-circuit 40 acting as a refrigerant side 6 takes place via the pump 14 to the connection 19 and further to the supply air battery 2 and from the supply air battery 2 to the connection 20 on the unit assembly 4 and via the three-way valve 22 to the evaporator 12, where the circuit is cooled. The temperature sensor 27 controls via the control computer 23 the compressor 28 to start and stop after the set temperature. A temperature sensor 29 opens the control valve 9 for increased flow (more than 20%) to maintain the set temperature and, when the compressor 28 is given a starting pulse, starts a circulation pump 30 and circulates the circuit 6 acting as a coolant side sub-circuit 41 via the connection 18 to the exhaust air battery 3 and from the exhaust air battery 3 via the connection 17 to the condenser 13, where heat energy is given off to the circuit.

As can be seen in more detail from the embodiment of the unit assembly 4 shown in Fig. 4, a temperature sensor 31 opens the control valve 10 to increase the flow of the coolant emanating from the condenser 13 (more than 20%) to keep set temperature and an external control signal, 0-10 V, controls the three-way valve 22 so that it opens and closes the flow in the subcircuit 40 of the circulation circuit 6. The compressor 28 circulates the refrigerant present in the cooling circuit 11 via the condenser 13 to a drying filter 32 and further to an expansion valve 33. and the evaporator 12 and back to the compressor 28. The refrigerant system, ie the cooling circuit 11, is protected against too low and too high pressure, respectively, by a low-pressure pressure switch 34 and a high-pressure pressure switch 35. The circuit 6 acting as refrigerant-side sub-circuit 40 is protected via a safety valve and an expansion vessel 36. The circuit 6 as refrigerant-side sub-circuit 41 valve and an expansion vessel 37. For filling the circuit with a glycol mixture of 30% with water, a glycol vessel 38 and a glycol pump 39 are mounted in the unit assembly 4.

As already mentioned above, the battery 2 in the supply air is used both for heat recovery and as a cooling battery and the battery 3 in the exhaust air both for heat recovery and as a coolant battery. The unit assembly thus has two functions, as shown in Figs. 1 and 2, which functions are combined in a compact, prefabricated assembly 4 for easy installation / design.

The refrigerant system, i.e. cooling circuit 11, comprises a hermetic compressor 28, liquid-evaporated evaporators 12 and condensers 13, which circuit requires minimal refrigerant filling of environmentally friendly refrigerant, HFC R-4070. The filling quantity below 3.0 kg means that the unit unit 4 meets the requirements for a minimum filling quantity of environmentally friendly refrigerant in accordance with current regulations.

Claims (3)

tested _ 7 Patent claims 1. Device 'at. an air treatment plant for heat recovery and comfort cooling, which plant (1) comprises batteries (2,3) placed in supply air and exhaust air, respectively, to which at least two circulation circuits are connected, which are selectable by means of control valves (7,8,9,10) connectable to respective batteries (2,3), of which the first circulation circuit (5) is connectable to the batteries (2,3) for heat recovery and the second circulation circuit (6) is connectable to the batteries (2,3) via a separate cooling circuit (11) included evaporator (12) and condenser (13) at. comfort cooling, characterized by a unit assembly (4) directly connectable to the batteries (2, 3), comprising said circulation circuits (5,6), wherein. the first circulation circuit (5): in its supply line (l5, l6) to the supply air battery (2) comprises a circulation pump (14) and a control valve (21) for setting the current flow and in its return line (15 ', l6') to the exhaust air battery (3) a three-way valve (22) and a temperature sensor (27) for controlling the three-way valve (22) for regulating the temperature of the circuit (5) by mixing the flows from the return line (16 ') and a branch line (16 ") from the supply line (16) and wherein the second circulation circuit (6) can be connected to the batteries (2,3) via the control valves (7-10) at the same time as at least two of these control valves (7, 8) are usable for switching off the first the circulation circuit (5), which second circulation circuit (6), through the separate cooling circuit (11) for circulating a refrigerant by means of a compressor (28) between the evaporator (12) and the condenser (13), is divided into a sub-circuit (40). ) for circulation of a cooling medium, eg a glycol mixture, between the front the condenser (12) and the cooling battery (2) in the supply air and a sub-circuit (41) for circulating a coolant, eg a glycol mixture, between the condenser (13) and the coolant battery (3) in the exhaust air and which unit (4) has a control computer (23) with its own control program, which is intended to perform the entire internal control of the components included in the unit. S ' Device according to claim 1, characterized in that the sub-circuits (40, 41) of the second circulation circuit (6) comprise temperature sensors (29, 31) for controlling the control valves (9, 10) to open to increase the flow in the respective circuit for holding set temperature 'on' outgoing refrigerant from an evaporator (12) and outgoing refrigerant from the condenser (13). Device according to claim 1, characterized in that the sub-circuit (40) of the second circulation circuit (6) acting as coolant side has and is protected by a safety valve and an expansion vessel (36) at the same time as the sub-circuit (41) acting as coolant side (41) exhibits and is protected by a safety valve and an expansion vessel (37).