JPS6029558A - Heat pump type air conditioner - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to measures against overload during heating in a heat pump type air conditioner.

(1) Conventionally, in heat pump air conditioners (hereinafter referred to as heat pumps) in which a compressor is driven by a motor, the discharge pressure of the compressor increases during overload during heating operation, and the compressor drive motor increases accordingly. The current value also increases, and if the current value exceeds the specified current value, the remoter will stop, and there is a risk that the air conditioner will not be able to operate.

Therefore, as a countermeasure, a bypass path is installed between the indoor heat exchanger and the accumulator, and a control valve is installed in this bypass path.The control valve is opened during overload during heating operation when the discharge pressure of the compressor increases. However, a device has been devised in which the discharged gas is bypassed to the suction side.

However, in this case, the apparatus becomes expensive, and since the high-temperature discharge refrigerant is introduced into the low-temperature suction side, the discharge pressure of the compressor is reduced, but the problem arises that the compressor motor overheats.

Therefore, in view of the above points, the present invention reliably prevents the overcurrent increase in the compressor motor due to overload during heating of the heat pump.
Moreover, the aim (2) is to be able to prevent this at low cost.

The present invention will be explained below with reference to embodiments shown in the drawings.

FIG. 1 shows a heat pump cycle diagram of this embodiment,
The compressor 1 is driven by a drive motor, which will be described later, to compress refrigerant. The suction side of the compressor 1 is connected to an accumulator 2 for liquid refrigerant in the event of an abnormality, and the discharge side of the accumulator 2 and the compressor 1 are connected to a four-way valve 3 that switches the flow of refrigerant between cooling operation and heating operation. The four-way valve 3 connects an indoor heat exchanger 4 and an outdoor heat exchanger 5.
Between the heat exchanger 4.5, there is a pressure reducing device for cooling, for example, a capillary tube 6 and a check valve 7 parallel to this, and a pressure reducing device 8 for heating and a non-return device parallel to this. Valve 9 is connected.

Further, the heat exchanger 5.6 is provided with an indoor fan 5 and an outdoor fan 6, respectively, for blowing ambient air.

FIG. 2 shows the electric circuit of the heat pump of this embodiment.

The motor 12 for driving the compressor, the motor 13 for driving the indoor fan (3) 10, the motor 14 for driving the outdoor fan 11, and the four-way valve 3 are driven by drive circuits 16 and 17, respectively.
．． 18 and 19 are connected to the AC power source 2°.

The compressor drive motor 12 is connected to a comparison circuit 22 via a current transformer 21, and the comparison circuit 22 compares the current of the motor 12 with a reference current value, for example 18A, and sends a digital signal to the microcomputer 23. It is designed to be output. Also connected to the microcomputer 23 is a temperature detection circuit 24 that detects the indoor temperature and outputs a digital signal according to the detected temperature. Furthermore, inside the microcomputer 23, a timer circuit 23a for stopping the outdoor fan motor 14 and a defrosting timer circuit 23b are provided.
Built-in. The microcomputer 23 includes the timer circuits 23a and 23b and the comparison circuit 22.
, based on the input signal from the temperature detection circuit 24, sends an output signal to the drive circuits 16, 17, 18, and 19 to drive the compressor motor 12, indoor fan motor 13, and outdoor fan motor 14.
, and controls the four-way valve 3 (4).

Next, the operation of this embodiment with the above configuration will be explained.

First, when performing cooling operation of the heat pump, four-way valve 3
is switched as shown by the solid line in Figure 1, and the gas refrigerant compressed to high temperature and high pressure by the compressor 1 is sent in the direction of the arrow shown by the solid line, cooled by the outdoor fan 11 in the outdoor heat exchanger 5, and becomes high temperature and high pressure. It becomes a liquid refrigerant, is rapidly expanded by the pressure reducing device 6, and is evaporated in the indoor heat exchanger 4. At this time, the air surrounding the indoor heat exchanger 4 is cooled and blown into the room by the indoor fan IO. On the other hand, only gas refrigerant of the evaporated refrigerant is sucked into the compressor 1 by the accumulator 2.

Next, when the heat pump is operated for heating, the four-way valve 3 is switched as shown by the dotted line in the fs1 diagram, and the refrigerant flows as shown by the dotted arrow. Therefore, the refrigerant is condensed in the indoor heat exchanger 5, rapidly expanded in the pressure reducing device 8, and evaporated in the outdoor heat exchanger 5. in this case,
The indoor heat exchanger 4 (5) releases the heat of condensation of the refrigerant to the surrounding air, and the heated air is blown by the outdoor fan 10.

During the heating operation described above, for example, when the indoor temperature or outdoor temperature is high, or when the air flow rate of the indoor fan 10 is reduced, the condensing pressure of the indoor heat exchanger 4 becomes high, and therefore the discharge pressure of the compressor 1 becomes high, resulting in so-called overload operation. At this time, as shown in FIG. 3, as the discharge pressure of the compressor 1 increases, the power supply value of the compressor drive motor 12 also increases. Note that the curve (a) shows the case when the frequency of the AC power supply 20 is 60 Hz, and the curve (tll) shows the case when the frequency is 50 Hz. As described above, when the current value increases and exceeds a certain limit value, the motor 12 will abnormally stop.

Therefore, in this embodiment, the current value of the compressor drive motor 12 is detected, and when the current value exceeds a reference current value, for example, 18A, the outdoor fan 11 is stopped for a certain period of time, for example, 30 seconds, and the outdoor fan 11 is stopped for an outdoor heat exchanger. The heat exchange coefficient of the compressor 5 is lowered, the discharge pressure of the compressor 1 is lowered (6), and the current value of the compressor drive motor 12 is accordingly lowered.

In addition, the heat pump is equipped with a defrosting timer 23b for defrosting the outdoor heat exchanger every certain period of time, for example, 45 minutes, but defrosting is not required in the event of an overload as described above. Therefore, while the outdoor fan 11 is stopped, the defrost timer 23b is kept in a reset state.

A specific example will be shown below.

First, when the heating operation switch (not shown) of the heat pump is turned on, the microcomputer 23 activates the drive circuit 16.
An output signal is sent to 17.1B and 19, the four-way valve 3 is switched to the heating side, and the motors 12, 13, and 14 start rotating.

This will be explained below with reference to FIG. In the figure, the horizontal axis shows elapsed time, the vertical axis shows the current value of the compressor drive motor 12, A shows the on/off of the timer circuit 23a, B shows the on/off of the outdoor fan motor 14, and C shows the on/off of the timer circuit 23b. .

First, a very large starting current (more than 18 A) flows through the compressor drive motor 12 as shown at point a (7) in FIG. , for example, within 10 seconds, the outdoor fan motor 14 will not stop.

Next, when the heat pump becomes overloaded and the current value of the compressor drive motor 12 becomes, for example, 18A or more (point b in Fig. 4), the timer circuit 23a counts the energization time, and when 10 seconds have elapsed (point b Point) The outdoor fan motor 14 is turned off and the defrost timer 23b is reset. When a certain period of time, for example 30 seconds has passed since the power was turned on, and the current is lower than 18A (point e), the outdoor fan motor 14 is turned on again and the defrost timer circuit 23 is turned on again.
b starts counting again from zero.

However, if the current value is 18 A or more even after 30 seconds have passed, the outdoor fan motor 14 remains off until the current value becomes lower than 18 A (point d), and the defrost timer circuit 2
3b is also in a reset state.

When the defrost timer circuit 23b counts that a certain period of time, for example (8) 45 minutes has passed, the microcomputer 23 outputs to the drive circuit 17, 18, 19,
Switch the four-way valve 3 to cooling operation, and turn the indoor fan motor 13 on.
, and the outdoor fan motor 14 is stopped. Therefore, the outdoor heat exchanger 5 is defrosted because the high-temperature compressed fluid passes therethrough.

Also, when the heat pump is in cooling operation, if the indoor temperature becomes lower than the set value, that is, if the indoor temperature is too cold, the temperature detection circuit 24 sends a signal to the microcomputer 23.
The microcomputer 23 sends a signal to the drive circuit 16 to stop the compressor drive motor 12.

Next, the flow of control of the micro combinator 23 will be explained using the flowchart of FIG. 5.

However, the control in this case shows a flowchart for overload control, and the input signal is only a signal obtained by converting the current value of the compressor drive motor 12 by the comparison circuit 22.

First, in step 25, the input current value is read, and the process proceeds to step 26. In step 26, (9) determines whether the flag is set. If the flag is set, the process proceeds to step 32; if not, the process proceeds to step 27. Step 2
In step 7, if the current value is 18 A or more, the process proceeds to step 2, where the timer circuit 23a is activated and starts counting. On the other hand, when the current value is lower than 18A, the process proceeds to step 31, resets the timer circuit 23a, and then proceeds to step 37.
Proceed to. After counting in step 28, the process proceeds to step 29, where it is determined whether or not the counted value has elapsed for 10 seconds or more.If it is 10 seconds or more, the process proceeds to step 30 to set a flag, and the process proceeds to step 37. If IO has not elapsed, the process directly proceeds to step 37. In step 37, the outdoor fan motor 14 is turned on, and the defrost timer 23 is turned on.
Set b to the set state and count the time until defrosting.

After step 37, the process advances to step 38, returns to step 25 again, and performs processing according to the input value at that time.

On the other hand, if it is determined in step 26 that the flag is set (lO), the process proceeds to step 32 to turn off the outdoor fan motor 14 and reset the defrost timer circuit 23b, and then proceeds to step 33 to turn off the outdoor fan motor 14. 1
4 is counted, and the process proceeds to step 34. In step 34, if 40 seconds have not elapsed from the start of counting, the process returns to step 32, and if 40 seconds have elapsed, the process proceeds to step 35. In step 35, if the current value at this time is 18A or more, step 32 is performed again.
Returning to , if it is lower than 18A, the process proceeds to step 36 to reset the flag, and then proceeds to step 37 to turn on the outdoor fan motor 14, set the defrost timer circuit 23b, and perform a count.

In the above embodiment, since the microcomputer 23 is used to perform overload control during heat pump heating operation, the CPU (Central Control Processing Unit) circuit of the microcomputer used for other controls of the conventional heat pump It is only necessary to slightly change the configuration, and it can be realized at low cost.

However, the present invention is not limited to the above embodiments, and for example,
A comparison circuit that compares the current of the compressor drive motor 12 with a reference value without using the microcomputer 23 together, a timer circuit that operates according to the signal of this comparison circuit, and an operation that operates in response to the signals of this timer circuit and the comparison circuit. The outdoor fan motor 14 may be rotated by a drive circuit.

Further, in the above embodiment, the current of the compressor motor 12 is directly detected by the current transformer 21, but in short, it is only necessary to determine whether the current value of the compressor motor 12 is larger than a reference value. When the current of the machine motor 12 changes, the current value on the power source side of the electric circuit also changes, so the current value on the power source side may be detected.

As described above, in the present invention, when the current value of the compressor drive motor exceeds a certain reference value and continues for a certain period of time during heating operation of the heat pump, an overload state is determined by an electrical signal, and the outdoor fan motor is activated at a certain level. By stopping the compressor for a certain period of time, the discharge pressure of the compressor is lowered, and therefore the current value of the compressor drive motor is lowered, making it possible to prevent current flow during overload more reliably than before, improving product reliability. It has the effect of

Furthermore, since the present invention performs overload control using electrical signals, it has the advantage that it can be implemented at low cost by only slightly modifying the existing electrical circuit of a conventional heat pump.

[Brief explanation of drawings]

The drawings all show embodiments of the present invention. Fig. 1 is a cycle diagram of a heat pump, Fig. 2 is an electric circuit diagram of the invention, and Fig. 3 is a diagram showing the discharge pressure of the compressor and the compressor drive motor. A characteristic diagram showing the relationship between current values, Figure 4 is a characteristic diagram showing the operation of the outdoor fan motor and defrost timer in response to changes in the current of the compressor drive motor, and Figure 5 is a flowchart showing the flow of control by the microcomputer. It is. 1... Compressor, 3... Four-way valve, 4... Indoor heat exchanger. 5...Outdoor heat exchanger, ll...Outdoor fan, 12.
...Compressor drive motor, 14...Indoor fan motor,
18... Drive circuit, 22... Comparison circuit, 23...
Computer, 23a... timer circuit. (13) −furnace≦ku■0

Claims (1)

[Scope of Claims] A heat pump type air conditioner in which the flow of refrigerant compressed by a compressor is switched by a four-way valve, and the refrigerant is heat exchanged by an indoor heat exchanger and an outdoor heat exchanger to perform cooling or heating. In the machine, a compressor drive motor receives electricity to drive the compressor, an outdoor fan provided to forcefully blow ambient air to the outdoor heat exchanger, and an outdoor fan provided to drive the compressor drive motor. A heat pump type air conditioner comprising: a fan motor; and a control circuit that stops the outdoor fan motor for a certain period of time when a current value of the compressor drive motor exceeds a certain reference current value.