DE4026868A1 - Room air-conditioner with facility for coolant recovery - has coolant from inner assembly forced back into outer assembly for operation with min. loss - Google Patents

Abstract

The outer assembly (1) incorporates a compressor (1c), a fan motor (1d) and a condenser (1e) with a capillary tube connection (1f) to a flow control solenoid vlave (4) and supply pipe (3a). The return pipe (3b) enters via a similar valve (5). Heat exchangers are provided in the inner assmebly (2). A third valve (6) is opened by a relay in ventilation mode giving access to a branch pipe (3c) to atmos. In coolant recovery mode the compressor (1c) is started and the return valve (5) opened. ADVANTAGE - Users without special skill or experience can choose between normal operation, ventilation and coolant recovery modes.

Description

The invention relates to an air conditioning system with separate Indoor and outdoor assemblies, in particular in addition to the normal operation in ventilation and refrigeration tel recovery plant can work.

Such air conditioning usually leaves the Manufacturer company with an outer assembly that with a large amount of refrigerant is loaded and with a Internal assembly, for corrosion protection reasons only is loaded with a small amount of refrigerant. The interior and external modules are arranged in the appropriate places net and connected with each other via lines.

After setting up the air conditioner, the captured one should Air can be removed from the refrigerant flow paths because the moisture in the trapped air freezes and thereby blocking the flow paths or keeping them even Air conditioning operation prevented.

If the air conditioning continues to be transported in components the refrigerant should be recovered and stored in the Outdoor assembly can be added before the air conditioning  disassembled to prevent excessive Refrigerant flows out, and the trapped air from the To be able to vent the refrigerant more easily in the future.

The recovery of the refrigerant and the ventilation of the trapped air and rebuilding an air conditioner should be done conventionally by a professional. These However, operations can also be performed using a automatic device run in the U.S. Patent 42 85 206 is described, however, the user additionally charged.

The invention is therefore an air conditioning system initially mentioned type are created, which optionally in Ventilation operation, in the refrigerant recovery operation or in normal operation by a user with no particular Experience can be operated.

For this purpose, the air conditioning system according to the invention is equipped with a External assembly, the components such as one Compressor, a condenser and a blower motor has, with an inner assembly with a heat exchanger device and with line devices for refrigerant supply leadership and feedback between the interior and the interior External assembly are arranged by a switch with a variety of connections for ventilation, the Refrigerant recovery operation and normal operation of the Air conditioning, depending on the mode selected by the operator User at least one electrical connection with an energy to connect the power source, refrigerant flow control valve directions in the lines for optional opening and Close the flow paths between the assemblies hen are, the control valve means electrically with the connections are connected, and relay devices featured that are electrically connected to the connectors are chosen to flow the current over at least one Connection to the modules and the associated  Control valve devices to control and thereby operate.

The following is based on the associated drawing particularly preferred embodiment of the invention closer described. Show it

Fig. 1 is a schematic view of the game Ausführungsbei the air conditioning system according to the invention and

Fig. 2 is a schematic view of the electrical circuit of the embodiment of the air conditioning system according to the invention, which operated in addition to normal operation in the ventilation and can work in the refrigerant recovery operation.

As shown in Fig. 1, an outdoor group 1 includes a compressor 1 c, a blower motor 1 d, a condenser 1 e and a capillary tube 1 f and has an inner assembly 2 heat exchanger devices such as se a cooling coil, which is not shown . Lines 3 a, 3 b, which are connected via connecting parts 7 to the outer and inner assemblies 1 , 2 , form a closed-end refrigerant circuit.

Normally, an air conditioner leaves the manufacturer's operation with an outer assembly 1 , which is loaded with most of the refrigerant. It is also known that the liquid refrigerant from the outer assembly 1 via the refrigerant supply line 3 a, the Wärmetauschereinrich lines of the inner assembly 2 is supplied, in which the liquid refrigerant absorbs heat from the ambient air as it evaporates. The resulting cooled air can then be distributed into the room to be cooled. The evaporated refrigerant from the inner assembly 2 returns to the compressor 1 c via the refrigerant line 3 b. In the compressor 1 c, the evaporated refrigerant is further heated by the compression work, and the resulting heated evaporated refrigerant is liquefied in the condenser 1 e by the ambient outside air, which is blown in by the blower. The liquefied refrigerant begins another cooling cycle for the air conditioner.

According to the invention, a first refrigerant flow control valve 4 is provided on the outlet side of the outer assembly 1 in the refrigerant supply line 3 a and there is a second refrigerant flow control valve 5 on the inlet side of the outer assembly 1 in the refrigerant return line 3 b, so that the refrigerant flow between the inner and External modules 1 , 2 can be controlled. In the refrigerant return line 3 b, a branch line 3 c is easily seen, which has an outlet connected to the outside air and is provided with a third flow control valve 6 . The flow control valves 4 , 5 , 6 are preferably solenoid valves.

Fig. 2 shows the electrical circuit of the exemplary embodiment of the air conditioning system according to the invention. The connections A, B and C can optionally be connected via the switch 11 , for example a matrix switch, to select the operating mode of the air conditioning system with one of the poles of the energy supply plug 10 .

The first port A has a relay RL 1 , one contact of which is connected directly to port A and the other contact of which is connected to one end of the compressor 1 c and to the second flow control valve 5 . The second port B is connected to a contact of a relay RL 2 , the other contact of which is connected to the third flow control valve 6 . The third connection C is connected together with one end of the blower motor 1 d and the first flow control valve 4 , at which a contact of the third relay RL 3 is located. The other contact of the relay RL 3 is connected to the other contact of the second relay RL 2 . The relays RL 1 , RL 2 , RL 3 are preferably relays with make contacts.

The following are the different ways of working  Air conditioning system described in more detail.

In the refrigerant recovery operation of the air conditioning system, the selector switch 11 connects the first connection A of the electrical circuit via the plug 10 to an electrical energy source. The coil of the relay RL 1 is then energized so that their contacts close to operate the compressor ter 1 c and open the second flow control valve 5 . Thus, the refrigerant present in the inner assembly 2 and in the line 3 a will forcibly flow into the outer assembly 1 via the return line 3 b, so that the air conditioning system can be disassembled into parts with a minimal loss of refrigerant by the connection parts 7 being separated will.

After the reconstruction of the air conditioning system disassembled into individual parts, the air in the lines 3 a, 3 b and in the internal assembly 2 must be removed. For this purpose, the selector switch 11 is switched to the ventilation mode of the air conditioning system and the second connection B is thus connected to the energy source.

In ventilation mode, the coil of the relay RL 2 is energized, so that the relay contacts are closed and the third flow control valve 6 is open, and on the other hand, the coil of the relay RL 3 is energized, so that the relay contacts are closed and the blower motor 1 d works and the first flow control valve 4 is open. The refrigerant retained in the outer module 1 under pressure flows through its pressure through the control valve 4, the pipe 3a and the inner assembly 2 for the pipe 3 b, wherein the trapped air is forcibly introduced b in this line. 3 The b in this manner in the pipe 3 is introduced air through the outlet of the branch pipe 3 c vented to the outside air.

When ventilation is complete, it begins Vent the evaporated refrigerant. At this time  can change from ventilation operation to normal operation through the Users can be switched. The ventilation can also be through a typical sensor can be perceived and it can automatically switch to normal operation.

When the selector switch 11 is switched to the normal operation position, the first and third connections A and C are connected to the energy source. The flow control valves 4 and 5 are therefore open, so that the compressor 1 c and the blower motor 1 d work and the refrigerant circulates normally.

When the air conditioner is turned off, then connects the selector switch has no connection to the energy source, so that the air conditioning remains switched off.

In an air conditioning system with the structure according to the invention can disassemble the air conditioner in individual parts and the reconstruction of the air conditioning system by a user without any particular experience can be undertaken, with none additional ventilation or cooling devices tel recovery are needed.

Claims (6)

1. Air conditioning system with an outer assembly, the components such as a compressor, a condenser and a blower motor, a separate inner assembly group with heat exchanger devices and line devices for the refrigerant supply and recirculation, which are arranged between the inner and outer assembly , known is characterized by a switch ( 11 ) with a plurality of connections (A, B, C) for the ventilation operation, the refrigerant recovery operation and the normal operation of the air conditioning system, to electrically at least one connection (A, B, C) with an energy source ( 10 ) each to select the operating mode by the user to connect, refrigerant flow control valve devices ( 4 , 5 ,, 6 ), which are provided in the lines ( 3 a, b, c) to selectively open the flow paths between the modules ( 1 , 2 ) and close, the control valve means ( 4 , 5 , 6 ) being electrically connected to the connections (A, B, C) v are connected, and relay devices (RL 1 , 2 , 3 ) which are electrically connected to the connections (A, B, C) and the current flow via at least one selected connection (A, B, C) to the components ( 1 c, 1 d and 1 e) and the valve devices ( 4 , 5 , 6 ) that are connected to operate them. 2. Air conditioning system according to claim 1, characterized in that the refrigerant flow control valve means ( 4 , 5 , 6 ) a first control valve ( 4 ) which is provided on the outlet side of the outer assembly ( 1 ) in the refrigerant supply line ( 3 a), a second control valve ( 5 ), which is provided on the inlet side of the outer assembly ( 1 ) in the refrigerant return line ( 3 d), and comprise a third control valve ( 6 ) which is provided in a branch line ( 3 c) which is from the refrigerant return line ( 3 b ) branches and has an outlet that communicates with the outside air to vent the air trapped in the refrigerant flow paths of the air conditioner. 3. Air conditioning system according to claim 1 or 2, characterized in that the connections (A, B, C) of the electrical circuit a first connection (A) with which the compressor ( 1 c) and the second control valve ( 5 ) in parallel to each other are connected, a second connection (B) with which the blower motor ( 1 d), the first control valve ( 4 ) and the third control valve ( 6 ) are connected in parallel, and a third connection (C) with which the blower motor ( 1 d) and the first control valve ( 4 ) are also connected in parallel to each other. 4. Air conditioning system according to claim 3, characterized in that the relay devices (RL 1 , RL 2 , RL 3 ) a first relay (RL 1 ), one contact directly with the first connection (A) and the other contact together with the compressor ( 1 c) and the second control valve ( 5 ) are connected, a second relay (RL 2 ), one contact of which is connected directly to the second connection (B) and the other of which is connected to the third control valve ( 6 ), and a third Include relay (RL 3 ), one contact of which is connected to the other contact of the second relay (RL 2 ) and the other contact of which is connected to the fan motor ( 1 d) and the first control valve ( 4 ), the relay (RL 1 , RL 2 , RL 3 ) are relays with make contacts, the coils of which are energized to close the contacts when they are powered. 5. Air conditioning system according to claim 2, characterized in that the refrigerant flow control valves ( 4 , 5 , 6 ) are solenoid valves each. 6. Air conditioning system according to claim 4, characterized in that the selector switch ( 11 ) has a position for the refrigerant recovery operation, in which the first connection (A) is connected to the energy source, a position for the ventilation operation, in which the second connection ( B) is connected to the energy source, a position for normal operation in which the first and third connections (A) and (C) are connected to the energy source and has a switch-off position in which none of the connections (A, B , C) is connected to the energy source.