KR0123439B1 - Input frequency control method for refrigerator - Google Patents

Abstract

Disclosed is a method to control input frequency for a refrigerator. The method comprises an internal interrupt routine, an external interrupt routine, a routine for setting damper transition time, and a routine for setting timer initial value. In the internal interrupt routine, input frequencies are compared to an external frequency to find a predetermined input frequency. In the external interrupt routine, an input frequency inputted when the internal interrupt routine is performed, and various tumers for phase control are set. In the routine for setting damper transition time, the damper transition time is set according to the frequency found in the internal interrupt routine. Thereby, the damper is driven according to the input frequency.

Description

Input frequency control method of refrigerator

1 is a circuit diagram of a damper driver of a refrigerator used in the present invention.

2 is an overall flowchart of the input frequency control method of the present invention.

3 is a subroutine of the input frequency control method of the present invention.

* Explanation of symbols for the main parts of the drawings

A: Constant voltage part, B: Input frequency converter,

Everything: micom, la: oscillator,

E: damper driving part, bar: damper detection part.

The present invention relates to an input frequency control method of a refrigerator, and more particularly, to an input frequency control method of a refrigerator in which a damper is driven according to a determined state by determining a frequency input to the refrigerator.

In general, in the case of a damper for supplying and blocking cold air in a refrigerating compartment from a refrigerator, the damper of the refrigerator is opened and closed in close relationship with an input frequency to control a high internal temperature. In other words, the damper of the refrigerator takes about 8 seconds from the opening to the closing operation and about 8 seconds from the closing to the opening operation when the input frequency is 60 Hz. The opening and closing operation time of is about 16 seconds.

Accordingly, when the input frequency is 50 Hz, the damper is less open or less closed when the damper is opened and closed at 60 Hz, which causes cold air to flow out into the refrigerator, thereby making it impossible to accurately maintain and maintain the internal temperature.

Therefore, in countries or regions where the input voltage and frequency are different, the frequency or voltage of the refrigerator must be matched. Therefore, if you want to control the power supply or load, install a separate circuit control unit, There must be an optional terminal.

In particular, in one country where the common frequency of 50Hz / 60Hz is used in common, additional explanations are required at the time of sale, or consumers are required to select the frequency directly. In addition to the problems that must be made to facilitate the operation, as well as occasional incorrect operation due to the careless handling of the operator, there is a problem that causes a serious problem to the device. Therefore, an object of the present invention is to determine the frequency input to the refrigerator, to automatically control the damper and drive in the determined state, in order to realize the above object the present invention is to determine the interrupt period for the input frequency The internal interrupt routine for judging the frequency for a unit time according to the completion time and comparing the discriminated frequency with the external frequency to determine whether it is within a predetermined number range, and determining the incoming frequency and indicating completion, and The internal interrupt routine determines the frequency input from the outside during the internal interrupt execution, counts the external frequency within the unit time if the frequency is discriminated, and sets various timers for controlling the load phase if the unit time has elapsed. Plates from the external interrupts and the internal interrupts And a damper transient time setting routine for determining whether the cut-off frequency is a predetermined frequency and setting a transient time of the damper, and a timer initial value setting routine for setting the unit time according to the frequency in the external interrupt step.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 is a circuit diagram of a damper drive control unit of a refrigerator used in the present invention, in which a constant voltage unit (A) for converting input power into a predetermined constant voltage and a resistor for converting a frequency input to a power terminal of the constant voltage unit (A) An input frequency converter (b) consisting of (R1-R4), capacitors (C1) (C2), and transistor (TR1), and the frequency input from the input frequency converter (b) are controlled in accordance with a predetermined program. And a microcomputer (C) for outputting a drive signal to a signal corresponding to a controlled state, an oscillator (D) for outputting a drive oscillation signal to the microcomputer (C), and a drive signal output from the microcomputer (C). A damper driver (e) for opening and closing the damper, and a reed switch (R / S), a resistor (R5-R7), which detects the transient time and the normal operation of the damper according to the driving of the damper driver (e). Damper detection section consisting of capacitors C3, C4, and transistor TR2 ( ) It is composed of a hayeoseo.

2 is an overall flowchart of the input frequency control method of the present invention. A frequency is determined for a unit time according to an interrupt period decision with respect to an input frequency, and a predetermined number is determined by comparing the determined frequency with an external frequency. Determining whether or not it is within the range, the internal interrupt routine to determine that the incoming frequency and indicates completion, and the frequency to be separately input from the outside during the internal interrupt in the internal interrupt routine, and if the frequency discrimination, within the unit time The external frequency is counted, and when the unit time has elapsed, the external interrupt routine for setting the various timers for controlling the load phase and the frequency determined by the internal interrupt routine determine whether the predetermined frequency is a transient time of the damper. Damper transient time setting routine to set and the external Timer initial value setting unit for setting the time according to the frequency at the interrupt step is to occur in a routine.

3 is an initialization step 201 for initializing a microcomputer upon power-up and an interrupt cycle determination for determining a timer interrupt cycle of a frequency to be determined at power-up, with each subroutine of the input frequency control method of the present invention. Step 202, an interrupt period elapsed judging step 203 for determining whether a predetermined period of the timer determined in the interrupt period determining step 202 has elapsed, and a predetermined period in the interrupt period elapsed judging step 203 Elapsed, a timer initialization step 204 for initializing a timer, a frequency discrimination completion step 205 for determining whether frequency discrimination is completed if the timer is initialized in the timer initialization step 204, and the frequency discrimination completion If the frequency discrimination is not completed in step 205, the frequency discrimination step 206 and the frequency discrimination step 206 determine whether the frequency discrimination is performed. If it is not during the frequency discrimination, the unit time timer initialization step 207 for initializing the unit time timer and the frequency discrimination step in the frequency discrimination step 206, or if the unit time timer initialization step 207, the comparison, A comparison unit time elapsed determination step 208 for determining whether the unit time has elapsed, a frequency discrimination completion step 209 for completing frequency discrimination if the unit time has elapsed in the comparison unit time elapsed determination step 208, and The unit time initialization step 201 for initializing the unit time timer after the frequency discrimination completion step 209 and the unit time initialization in the unit time initialization step 201 is performed. If the external input frequency determination step 211 and the external input frequency determination step 211 is a predetermined frequency or more, the external input frequency A first frequency range determination step 212 for determining whether the predetermined first frequency is within a predetermined range, and if the external induction frequency is not greater than or equal to a predetermined frequency range in the external induction frequency determination step 211, the external induction frequency is a second predetermined frequency; In the second frequency range determination step 213 for determining whether it is within the range, and if the incoming frequency is in the predetermined frequency range in the first and second frequency range determination steps 212 and 213, it is determined as a frequency within that range. Frequency discrimination initialization step (214) (215) and the frequency discrimination completion step, the initial display of the discrimination time, initialization of the identification time, initializing the discrimination during the discrimination in the frequency display step (214) (215) 216 and, if not in the preset range in the first and second frequency range determination steps 212 and 213, a frequency initialization step 217 for initializing a unit time timer and an external incoming frequency counter; The internal interrupt routine performed by the internal frequency discrimination initialization step 216 and the internal timer setting step 218 to set various internal timers when the frequency initialization step 217 is performed, and the external interrupt routine is performed by the internal interrupt routine. External incoming frequency discrimination step 301 for determining whether the incoming frequency is being determined from the external incoming frequency count step of counting the external incoming frequency if the external incoming frequency is determined in the external incoming frequency discrimination step 301 ( 302 and an external incoming frequency count initialization step 303 for initializing an external incoming frequency count that counts an external incoming frequency if the external incoming frequency discrimination completion step 301 is completed during the external incoming frequency discrimination. A unit time elapsed determination step 304 of determining whether the unit time has elapsed when the external incoming frequency count or the count is completed; The unit time initialization step 305 for initializing the unit time if the time has elapsed in the unit time elapsed determination step 304, and if the unit time is initialized in the unit time initialization step 305, the load controlling the load phase. An external interrupt routine performed by the phase control step 306, a timer setting step 307 for setting various necessary timers, and a 60 Hz external input frequency discrimination step for determining whether the external input frequency determined by the internal interrupt routine is 60 Hz. 401, a 60 Hz transient time setting step 402 for setting a corresponding 60 Hz transient time if the 60 Hz, and a 50 Hz transient time setting step 403 for setting a 50 Hz transient time if the 60 Hz is not 60 Hz. A damper transient time setting routine, an external frequency judging step 501 for determining whether an external frequency input from the external interrupt routine is 60 Hz, and an external frequency judging step 501 60 Hz, 60 Hz unit time setting step (502) of setting 60 pulses as the unit time timer, 50 Hz unit time setting step (503) of setting the unit time timer 50 pulses other than 60 Hz in the external frequency determination step (501) It consists of timer initial value setting routine.

Referring to the effects of the present invention made as described above are as follows. First, when power is applied to the refrigerator, the microcomputer (C) of the refrigerator goes to the initialization step 201 of the internal interrupt routine and is initialized, and supplies the voltage input from the constant voltage unit as the operating power, and at the same time, the constant voltage unit When the external frequency input from the power supply terminal of (A) is converted through the input frequency conversion unit (B) and input to the microcomputer (C), the microcomputer (C) goes to the interrupt cycle determination step 202 and pulls in from the outside. An interrupt predetermined time period (10 ms) is determined for the external frequency to be determined.

When the interrupt time period is determined, the microcomputer (c) determines the incoming external frequency at a predetermined time period (10ms), but the microcomputer (c) determines the external incoming frequency of the external interrupt routine (301). If it is determined that the external incoming frequency is determined, the external incoming frequency count step 302, the external incoming frequency is counted, and if the external incoming frequency discrimination step 301 In the microcomputer (c), go to the external input frequency count initialization step 303 to initialize the counted external input frequency, go to the unit time elapsed determination step 304, and the time for counting the external input frequency is the unit time (1 second). ), And if the unit time has elapsed, the microcomputer (C) goes to the unit time initialization step 305 and counts the external incoming frequency. Initializing the unit time and, to go to the load phase control stage 306 controls the phase in the lower part sikimyeo phase control load, go to a timer setting step 307, thereby setting the various timers required.

At this time, the setting of the unit time (1 second) goes to the external frequency judging step 501 of the timer initial value setting routine, and it is determined whether the input frequency is 60 Hz. If the determination result is 60 Hz, the microcomputer sets the unit time of 60 Hz. In step 502, the unit time is set to 60 pulses for 1 second, and if the frequency is not 60 Hz, the microcomputer (c) goes to the 50 Hz unit time setting step 503 to set the unit time to 50 pulses for 1 second.

However, if the unit time has not passed to the unit time elapsed determination step 304, the microcomputer (c) goes to the internal interrupt routine and performs an internal interrupt.

As described above, when the external input frequency for a predetermined time period (10ms) is determined with respect to the external input frequency in the interrupt cycle determination step 202, the microcomputer (c) goes to the interrupt cycle elapsed determination step 203. It is determined whether a predetermined period (10ms) has elapsed. If this predetermined period (10ms) has not elapsed, the microcomputer (C) performs an internal interrupt routine until the predetermined period (10ms) has elapsed. While determining the external incoming frequency, if a predetermined period (10ms) has elapsed in the interrupt period elapsed determination step 203, the microcomputer (C) goes to the timer initialization step 204, a predetermined period (10ms) timer The microcomputer (C) then proceeds to the frequency discrimination completion step 205 to determine whether the frequency discrimination being performed in the external interrupt routine is completed.

At this time, if the frequency discrimination is completed, the microcomputer (c) goes to the internal timer setting step 218 to set the internal timer necessary for the operation.

On the other hand, if the frequency discrimination is not completed in the frequency discrimination completion step 205, the microcomputer (C) goes to the frequency discrimination step 206 to determine whether a frequency is being determined. In step unit 207, the timer is initialized, and the timer is initialized, and the unit time lapse determination step 208 is performed to determine whether the comparison unit time (1 second) has elapsed. In the case of frequency discrimination, the process proceeds to the comparison unit time elapsed determination step 208 to determine whether the comparison unit time (1 second) has passed. Therefore, if the unit time has not elapsed in the comparison unit time elapsed judging step 208, the microcomputer (C) goes to the internal timer setting step 218 to set the internal timer necessary for the operation and repeats the internal interrupt routine. . However, if the comparison unit time (1 second) has elapsed in the comparison unit time elapsed judging step 208, the microcomputer (C) goes to the frequency discrimination completion step 209 to complete the frequency discrimination, and the unit time initialization step ( Go to 210 to initialize the tire.

When the unit time is initialized as described above, the microcomputer (c) goes to the external input frequency determination step 211 to determine whether the external input frequency is a predetermined number 55 or more, and the external input frequency is the predetermined number. When the microcomputer (c) goes to the first frequency range determination step 212, it is determined whether the counted external inlet frequency is within a predetermined range (57 ≤ external inlet frequency ≤ 63). The microcomputer (c) goes to the incoming frequency display step 214 to indicate that the external incoming frequency is 60 Hz, and if the external incoming frequency is not more than the predetermined number 55 in the external incoming frequency determination step 211, the second Go to the frequency range determination step 213 to determine whether the external inlet frequency is within a predetermined range (47≤external inlet frequency≤53), and if it is within the predetermined range, the microcom Go to the frequency display step 215 it is determined that the external incoming frequency is 50Hz.

When the determination of the external inlet frequency is completed as described above, the microcomputer (c) goes to the frequency discrimination initialization step 216 to perform the frequency discrimination completion display, unit time timer initialization, discrimination display initialization, and external inlet frequency count initialization. Then, go to the internal timer setting step 218 to set various internal timers required for the operation.

However, when the external inlet frequency determined in the first and second frequency range determination steps 212 and 213 does not fall within a predetermined range, the microcomputer (c) goes to the frequency initialization step 217 to determine the unit time. The timer is initialized, the external frequency input count is initialized, and the internal timer setting step 217 is performed to set various internal timers required for the operation.

After the determination of the external incoming frequency is completed as described above, the microcomputer (c) goes to the 60 Hz external incoming frequency discrimination step 401 of the damper transient time setting routine to determine whether the external incoming frequency determined by the internal interrupt routine is 60 Hz. In this case, if the determination result is 60 Hz, the microcomputer (c) goes to the 60 Hz transient time setting step 402 and sets the damper transient timer of the damper driver (e) at a time corresponding to 60 Hz to 1840 ms to drive the damper. .

On the other hand, if it is not 60Hz, the microcomputer (c) goes to the 50Hz transient time setting step 403 and sets the damper transient time of the damper driver (e) to 2100ms corresponding to 50Hz to drive the damper, thereby providing an input frequency. Corresponding damper drive can be made accurately.

As described above, the present invention determines the frequency input from the power terminal in the refrigerator as a predetermined unit time, and automatically sets the driving time of the damper to be opened and closed according to the determined state, thereby opening and closing the damper to vary according to the input frequency. It is to provide an effect that can solve all the problems caused by the error of time.

Claims (1)

For the input frequency, the frequency is discriminated for the unit time according to the interrupt cycle decision, and the determined frequency is compared with the external frequency to determine whether it is within a predetermined number range, and it is determined that it is the incoming frequency. The internal interrupt routine and the internal interrupt interrupt frequency are separately determined during the internal interrupt, and if the frequency discrimination is performed, the external frequency is counted within the unit time, and if the unit time has elapsed, the load phase is determined. An external interrupt routine for setting various necessary timers to control, a damper transient time setting routine for setting a transient time of a damper by judging whether the frequency determined by the internal interrupt routine is a predetermined frequency, and according to the frequency at the external interrupt Timer initial value to set unit time An input frequency control method of a refrigerator characterized in that formed on a regular routine.