DE4133112A1 - De-icing control circuit for air-conditioning unit with heat pump - has automatic cut=out of circulation fan motor for duration of de-icing cycle - Google Patents

Abstract

The de-icing control circuit allows the operation of the motor (M) driving the air circulation fan to be halted, to prevent the cold air delivered by the condenser from being delivered to the air-conditioned room. The de-icing cycle is controlled via a timing device (TM), the condition of which is monitored for operation of a relay (RY1..) for restarting the fan motor (M) and operating the control valve (RV) for the heat pump. Pref. the switch monitoring the condition of the de-icing timing device incorporates a photocoupler (IC1) coupled to a microprocessor control (1). ADVANTAGE - Prevents excessive cooling of air-conditioned room during de-icing.

Description

The present invention relates to ice removal control circuit for an air conditioner with a heat pump, more precisely said a circuit for controlling the drive of a fan ses to create a dish in the interior of a room air flow.

As shown in Fig. 1, a conventionally-formed ice removal control circuit for an air conditioner with heat pump includes an ice removal control timer TM connected between the two terminals of an AC power source (220 V AC), a reversing valve RV connected in series with switches SW1 and SW2 is, a motor M for driving a fan for generating an air flow directed into the interior of a room and switches SW3 and SW4 for switching the motor M. The timing element TM is connected in parallel to the reversing valve RV.

If with this conventionally trained ice removal control circuit the air conditioner acts as a heat pump is the  switch SW2 connected in series with the reversing valve RV turned on, and the switch SW1 of the ice removal control timer TM is stuck to the reversing valve RV tet, so that the refrigerant flows backwards so that he heated airflow is released into the interior of a room. That has a high temperature and a high pressure Refrigerant flows to the condenser, which is inside the rau mes is arranged, the condenser through the air current from the fan located inside the room is generated, heat is supplied. Then it flows Refrigerant to the evaporator, which is outside the room is arranged and receives a low pressure and a low temperature so that by rotating the outside Cold air placed outside the room to be led. These operations are repeated to create a ge wanted to get room temperature.

However, if the outside temperature is too low in winter, the refrigerant keeps the low outside the room Pressure and the low temperature when dispensing the cold air upright so that the outside temperature drops too far and the evaporator freezes. As a result, the refrigerant of the evaporator are not working properly, so the Heat pump efficiency of the air conditioner considerably is discontinued. In this case, the switch SW1 of the Ice removal control timer TM according to a predetermined Time separated from the reversing control valve RV, so that the cold medium outside the room a high pressure and a high Maintains temperature and thus the ice formed in the evaporator melts. When the operation of the ice removal control timing of the TM is finished, the switch SW1 of the iron remover voltage control element TM connected to the reversing valve, so that the air conditioner works as a heat pump. One of the like conventionally trained ice removal control scarf  tion has the disadvantage that when the refrigerant high outside the room in the ice removal operation Receives pressure and a high temperature so cold cold medium can flow into the capacitor by rotating the Blower (hereinafter referred to as an inner blower), which in the Inside the room is arranged a cold air flow in the interior of the room is released and thus the we efficiency of heating is reduced.

The invention has for its object a device with which the rotation of the inner fan in the Ice removal operation of the air conditioner as a heat pump can be stopped to prevent cold air current from the capacitor flows into the room in this way to improve the heating efficiency.

This object is achieved by an ice remover voltage control circuit for an air conditioner with a heat pump that includes the following ingredients: An iron duck Remote control device for stopping the operation of a Motor for driving a fan to generate an in the interior of a room directed airflow, one Switching device for transmitting a signal that the ON or OFF state of an ice removal control timer Switch reproduces to the Eisentferungssteuereinrich device, a relay device for closing or opening the Switch for actuating a reversing valve and Motor for driving the fan according to the initial state the ice removal control device and an equal directional device for actuating the switching device according to the functional state of the ice removal control time limb.

The invention will now be described with reference to an embodiment game in connection with the drawing in detail tert. Show it:

Figure 1 is a schematic representation of a conventional ice removal control circuit of an air conditioner as a heat pump.

Fig. 2 is a schematic representation of an inventively trained Eisentfer voltage control circuit of an air conditioner as a heat pump; and

Fig. 3 is a flowchart relating to the operation of a microcomputer used in the fiction, trained according to the circuit.

As shown in FIG. 2, a reversing valve RV and the contact switch 1 a of a relay coil RY1 are connected in series between two terminals of an alternating current source (alternating current 220 V). An ice removal control timer TM is connected in parallel to the reversing valve RV. The motor for driving an inner blower for generating an air flow directed into the interior of a room is connected via the series-connected contact switches 2 a and 3 a from relay coils RY2 and RY3 to the AC power source.

Via a resistor R1, a diode D1 and a capacitor C1, the light-emitting element of a photocoupler IC1, a resistor R2 and the switch SW1 of the ice removal control timer TM are switched to the AC power source. The light receiving element of the photocoupler IC1 and the input I _{0 of} a microcomputer 1 are connected via a resistor R3 to a direct current source V _cc . The outputs O ₀ , O ₁ and O _{2 of} the microcomputer 1 are connected to the relay coils RY1, RY2 and RY3 via buffers B1, B2 and B3.

If in operation a signal with a high level from the output O _{0 of} the microcomputer 1 to the relay coil RY1 is applied and thus the contact switch 1 a is switched on, the reversing valve RV is connected to the AC source (220 V) to operate the heat pump.

While the air conditioner works as a heat pump and the outside temperature is kept below a certain value, the evaporator freezes, whereby the switch W1 of the ice removal control timer TM is closed, so that the alternating current (220 V) through the resistor R1, the diode D1 and the capacitor C1, which are applied to the photocoupler IC1, is rectified. Thus, the inner transistor of the photocoupler IC1 is turned on, and it is the input I _{0 of} the microcomputer I leads to a low level signal.

As shown in Fig. 3, the microcomputer 1 then outputs the low level signal via the outputs O ₀ , O ₁ , and O ₂ , so that no current through the buffers B1, B2, B3 to the relay coils RY1, RY2, RY3 flows to open the corresponding contact switches 1 a, 2 a, 3 a. Thus, the motor M for driving the inner fan is stopped together with the control valve. After that, the air conditioner changes its operating state to refrigeration, whereby the ice formed in the condenser is melted.

When the ice removal control timer TM is stopped after a predetermined time and the switch SW1 for stopping the photocoupler IC1 is opened, the microcomputer 1 receives a high level signal through the input I ₀ , and a high level signal is output through the outputs O ₀ , O ₁ , O ₂ delivered so that the current flows through the buffers B1, B2, B3 to the relay coils RY1, RY2, RY3 and closes the corresponding contact switches 1 a, 2 a, 3 a. As a result, the motor M drives the inner blower. Simultaneously with this, the reversing valve RV is driven, so that the air conditioner performs the normal heating operation.

If, as explained above, the air conditioner switches with Heat pump is in ice removal mode, controls the circuit according to the invention the inner blower such that this is stopped to prevent the cold air current flows from the capacitor into the room, so that on this Way the heating efficiency is improved.

Claims (2)

1. Ice removal control circuit for an air conditioner with a heat pump, characterized by :

• a) an ice removal control device for stopping the operation of a motor (M) for driving a fan for generating an air stream directed into the interior of a room;
• b) switch means for transmitting a signal embodying the ON or OFF state of an ice removal control timer switch to the ice removal control device;
• c) a relay device for closing or opening the switch for actuating a reversing control valve (RV) and the motor (M) for driving the fan in accordance with the initial state of the ice removal control device; and
• d) a rectification device for actuating the switching device according to the functional state of the Eisent distance control timer (TM).

2. ice removal control switch according to claim 1, there characterized in that the switch direction includes a photocoupler (IC1).