JPS6315714Y2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an air conditioner, and more particularly to an air conditioner that is time-controlled to ensure defrosting of an evaporator in the air conditioner.

Conventionally, a defrost circuit for an indoor evaporator of an air conditioner has been configured as shown in FIG.
In FIG. 1, reference numeral 1 denotes a temperature sensor serving as frost detection means, 2 a control section, 3 an evaporator, 4 a compressor, 5 a condenser, and 6 a capillary tube. The temperature sensor 1 is attached to the evaporator 3 as shown in FIG.

In such a conventional defrost circuit, while the air conditioner is operating, frost begins to form on the evaporator 3, and the frost grows and contacts the temperature sensor 1, causing the temperature sensor 1 to drop below the set temperature. Once cooled, the controller 2 stops the compressor 4. After the compressor is stopped, the compressor starts operating again when the temperature of the temperature sensor becomes higher than the set temperature after defrosting.

However, in conventional defrost circuits for air conditioners, the time it takes to detect frost changes greatly due to variations in the mounting position of the temperature sensor, especially variations in the gap between the sensor and the evaporator, and furthermore, variations in the set temperature occur. In addition, it was difficult to achieve complete defrost under all frost conditions. That is, if defrost is not completed and the defrost cycle is repeated, residual ice will form from the bottom of the evaporator, and if this residual ice grows, it may become impossible to recover the drain water from the evaporator. In particular, in the case of an indoor evaporator, if drain water cannot be recovered, the drain water will drip into the room from the air conditioner, which poses a big problem. For this reason, the management of the gap between the sensor and the evaporator and the set temperature have become very strict in the production process.Furthermore, the set temperature has also been set high for safety, and operation during frost has been severely regulated from the start. It had become something that had been done.

Therefore, in view of the problems with the defrost circuit in conventional air conditioners, it is an object of the present invention to provide an air conditioner that secures the operating time of the compressor and completely defrosts the evaporator. .

Hereinafter, the air conditioner of the present invention will be described in detail with reference to preferred embodiments shown in the accompanying drawings. FIG. 3 shows a defrost circuit for an air conditioner according to an embodiment of the present invention, and in FIG. are given the same reference numerals and their explanation will be omitted.

In the defrost circuit in the air conditioner of this embodiment, a room temperature sensor 7, which is a room temperature detection means, is electrically connected to the control section 8. This control section 8 is equipped with a compressor operation stop time determining means, and when the compressor 4 is in operation, frost begins to form on the evaporator 3, this frost grows, and the temperature sensor 1 detects the frost, the compressor At the same time as the compressor 4 is stopped, the maximum continuous operation time and stop time of the compressor 4 are set from this point.

Setting the maximum continuous operation time and stop time like this means that if the compressor continues to operate continuously for the optimal set time, it will be forcibly stopped for the optimal set time, and then restarted. It means time control to start. This time control and the conventional control using the temperature sensor 1 are used together, and the compressor 4 is stopped by whichever control occurs first.

At this time, the optimum time is set according to the room temperature obtained by the room temperature sensor 7, that is, according to the room temperature at that time, in order to make the operation time more reliable. The optimal time is the combination of continuous compressor operation time and stop time that does not produce residual ice even after repeated defrost cycles under all possible conditions at a given room temperature. be.

The control of the compressor 4 by the control unit 8 will be explained in more detail with reference to the flowchart of FIG. Temperature sensor 1 detects frost formation, sets compressor continuous operation time _t1 and stop time _t2 as in step 11, and resets the continuous operation time count at the same time as compressor 4 is stopped (step 12). 13, and the stop time is counted 14. When the compressor stops for the set time _t2 (step 15), the stopping operation is canceled (step 16), and at the same time the compressor 4 resumes operation, a count is started to operate for the previously set operating time (step 17). ) to be done.

During operation for the predetermined time _t1 , even if there is no frost, the compressor is stopped at that predetermined time as shown in steps 18 and 19. It is controlled in this way because it appears that frost formation occurs during operation.

In this way, if the operation of the compressor 4 is stopped due to frost formation on the evaporator under a certain environment, the compressor is automatically operated from then on under the time control set by the control unit 8. .

With such a defrost circuit, the main function of the temperature sensor 1 is to determine whether to enter operation time control when the operating conditions are such that frost formation occurs, and if the defrost cycle is repeated, Since time control takes priority, there is no need for variations in the mounting position of temperature sensors or for managing set temperatures as in the past. Furthermore, precise time control ensures complete defrosting, and drainage during frosting can be recovered without any problems. In addition, since it is possible to delay the operation of the temperature sensor compared to conventional methods, the operation time from start until the temperature sensor activates becomes longer, and the indoor load at the time of start is high and the cooling capacity is required the most. This makes it possible to maintain long operating hours.

As described above, according to the present invention, by adding control of the operating time according to the room temperature during defrosting using a temperature sensor, it is easier to manage than before, and the operating time at the start is ensured. An air conditioner having a protection circuit can be provided.

[Brief explanation of drawings]

Figure 1 is a configuration diagram showing the defrost circuit of a conventional air conditioner, Figure 2 is a fragmentary cross-sectional view showing how the temperature sensor is attached to the evaporator in a conventional air conditioner, and Figure 3 is the present invention. FIG. 4 is a block diagram showing a defrost circuit in an air conditioner, and FIG. 4 is a flowchart illustrating the operation of the compressor by the control section. 1...Room temperature sensor, 3...Evaporator, 4...Compressor, 7...Room temperature sensor, 8...Control unit. Note that the same reference numerals in the figures indicate the same or equivalent parts.

Claims (1)

[Claims for Utility Model Registration] (1) A temperature sensor as a frost detection means and a temperature sensor as a room temperature detection means attached to the evaporator, and a temperature sensor as the frost detection means installed on the evaporator. Compressor operation stop time determining means is provided for setting the compressor operation stop time when frost formation is detected and the operation time after restarting the operation. An air conditioner comprising a control unit that controls the air conditioner. (2) A utility model characterized in that the compressor operation stop time determining means sets the continuous operation time and stop time of the compressor from the time when frost formation is detected by the temperature sensor serving as the frost formation detection means. An air conditioner according to claim 1. (3) The utility model according to claim 1 or 2, wherein the compressor operation stop time determining means sets the continuous operation time and stop time of the compressor according to the room temperature. Air conditioner.