JPH0227587B2 - JOSOSEIGYOSOCHI - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a defrosting control device for a refrigerator-freezer or the like.

In general, in various types of cooling devices such as refrigerators, frost adhering to the surface of the cooler is one of the main causes of lowering the cooling capacity, and defrosting measures are important.

Conventionally, most defrosting devices use a timer to accumulate the operating time of the compressor and start defrosting when the accumulated time reaches a predetermined time. In the case of seeds, defrosting is performed regardless of the amount of frost, which is not preferable from the viewpoint of energy saving.

On the other hand, if a frost sensor is used to detect the amount of frost and defrost is performed in accordance with the amount of frost, unnecessary defrost will not be performed and efficient defrost control can be expected.

However, the state of frost on the cooler varies greatly depending on environmental conditions, etc. If frost grows rapidly in a particular area, the air flow changes, frost stops near the frost sensor, and the output of the frost sensor decreases. may no longer change. In this case, since the frost sensor cannot detect the formation of frost, there is a drawback that defrosting cannot be carried out at any time.

The present invention has been made in view of the above-mentioned problems, and it is possible to obtain a highly reliable defrost control device that defrosts reliably by starting defrosting within a predetermined time regardless of the output of a frost sensor. That is.

A detailed explanation will be given below using an example shown in the drawings.

FIG. 1 is a block diagram of the device of the present invention, in which a microprocessor 1 is used for control, and a timer function can be easily implemented using software. Reference numeral 6 denotes a frost sensor for detecting frost formation. For example, it is an optical transmission type frost sensor having characteristics as shown in curve A in Fig. 2, and detects the frost formation state by an increase or decrease in the amount of light from a light emitting diode. be. 7 is a conventionally used temperature sensor for detecting the end of defrosting, which senses when the frost melts and the temperature around the cooler rises due to the operation of the defrosting circuit (not shown). This is to stop the defrosting circuit. Reference numeral 8 denotes a relay for switching between cooling operation and defrosting operation, which can be switched to either cooling operation or defrosting operation by the microprocessor 1 through output port 4. Note that 5 is a comparator and 2 is a memory.

Now, consider the case where defrosting is started at the frost amount M (frost sensor output V ₁ ) in FIG. 2.

When power is supplied, the microprocessor 1 first checks by the comparator 5 through the input port 3 whether the output of the frost sensor 6 is below the detection level _V1 . If the output of the frost sensor 6 is below level _V1 , the relay 8 is switched to defrosting operation, otherwise to cooling operation through the output port 4.

During cooling operation, the microprocessor 1 integrates the operating time of the compressor and checks the frost sensor 6.
The output is monitored, and if it becomes below the reference level _V1 , it is determined that the amount of frost formation is the amount that should be defrosted, and the system switches to defrosting operation. Also, during the defrosting operation, the output of the temperature sensor 7 is monitored, and when the output exceeds a predetermined time, it is determined that the defrosting has ended and the operation is switched to the cooling operation.

On the other hand, as described above, the state of frost on the cooler varies greatly depending on environmental conditions and the like, and there may be cases where frost growth stops around the installation location of the frost sensor 6. In this case, since the output of the frost sensor 6 will not reach the reference level for some time, defrosting will no longer be performed if the microprocessor 1 simply monitors the output of the frost sensor 6.

Therefore, in the present invention, the microprocessor 1 is provided with a timer that totals the operating time of the compressor after the start of the cooling operation, and a timer that determines whether the cumulative time accumulated by the timer has reached a predetermined time. and defrosting start instructing means for instructing to start defrosting regardless of the output of the frost sensor when the cumulative time is equal to or greater than the predetermined time.

Therefore, even if the output of the frost sensor 6 does not reach the reference level no matter how long it takes, if the integrated value of the operating time of the compressor reaches the predetermined time, the defrosting start instruction means will start the defrosting operation. The defrost circuit is activated. Once the defrosting circuit is activated and defrosting is performed, the output of the frost sensor 6 is restored and normal operation returns again.

FIG. 3 shows a flowchart of the apparatus of the present invention.
First, press the start button to supply power and set to the initial state in step _S1 .

Next, in step _S2 , the signal from the frost sensor 6 is passed through the input port 3 to the microprocessor 1 to determine whether or not frost has formed.

Then, if there is no frost at all, or if the amount of frost is below a predetermined amount (NO), the process moves to step _S3 , and the cooling operation is started by the operation of the output port 4 and relay 8. It is done. At this time, if the frost detection is YES, the process moves to step _S8 , where the defrosting operation is switched to via the output port 4 and relay 8, and then the process proceeds to step _S9 , where it is determined whether the defrosting operation has ended or not. is detected by the temperature sensor 7.

In step _S4 , frost formation detection is performed at predetermined intervals during cooling operation, and if YES, the process advances to step _S8 .
If NO, proceed to step _S5 . step
S ₅ determines whether the compressor is ON or OFF,
If the compressor is OFF, go to step 4 again.
If the compressor is ON, the process moves to step _S6 , where a timer is used to add up the operating time of the compressor. Then, in step _S7 , the determining means determines whether the cumulative time accumulated by the timer has reached a predetermined time, and if the cumulative time has not reached the predetermined time, the process returns to step _S4 .
If the defrosting operation has been reached, the process moves to step _S8 where the defrosting start instructing means instructs the start of the defrosting operation.

Incidentally, when the defrosting operation is started in step _S8 , the above-mentioned timer is set to the initial state. Therefore, if there is no abnormality in the frost sensor 6, the frost sensor 6 will be activated and defrosting will be performed before the accumulated time accumulated by the timer reaches the predetermined time.

As described above, the present invention provides a defrosting control device that detects frost formation using a frost sensor and performs defrosting. A determining means for determining whether or not a time has reached a predetermined time; and a defrosting start instructing means for instructing to start defrosting regardless of the output of the frost sensor when the accumulated time is equal to or greater than the predetermined time. Because it is
Defrosting can be reliably performed while taking advantage of the defrosting characteristics of the frost sensor, and a remarkable effect can be achieved in that highly reliable defrosting control can be performed.

[Brief explanation of drawings]

FIG. 1 is a block circuit diagram of the apparatus of the present invention, FIG. 2 is an output characteristic diagram of a frost sensor used in the apparatus of the present invention, and FIG. 3 is a flowchart of the apparatus of the present invention. 1: Microprocessor, 6: Frost sensor.

Claims (1)

[Scope of Claims] 1. In a defrost control device that detects frost formation using a frost sensor and performs defrosting, there is provided a timer for accumulating the operating time of a compressor after the start of cooling operation; a determining means for determining whether the accumulated time has reached a predetermined time; and a defrosting start instruction means for instructing to start defrosting regardless of the output of the frost sensor when the accumulated time is equal to or greater than the predetermined time. A defrosting control device characterized by comprising: