JP3540572B2 - Refrigerator abnormality detection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To detect with a single abnormality detector whether any one of two fan motors is locked in a refrigerator. SOLUTION: There are provided current value detection means for detecting the total sum of currents flowing through an in-refrigerator fan motor 17 and a machine chamber fan motor 17A, revolution detection means for detecting revolutions of the fan motors 17, 17A, and alarming means. When there is elapsed for a predetermined time interval the state where the total sum of the currents flowing through the fan motors 17, 17A are larger than a lock current based upon an output of the current detection means, it is judged that any one not rotated of the fan motors 17, 17A is abnormal, and the alarming means is actuated.

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a refrigerator abnormality detection device including two fan motors and a control device for controlling the operation of these fan motors.
[0002]
[Prior art]
Conventionally, in a home refrigerator of this type, as disclosed in, for example, JP-A-8-247606 (F25D17 / 06), a freezing room, a refrigerating room, a vegetable room, and the like are formed in a storage of an insulated box body. Cool air from a cooler provided on the back is circulated and cooled in each chamber by an in-compartment fan (cool air circulation fan) driven by a fan motor.
[0003]
Further, a machine room is formed below the heat insulating box, and a compressor and a condenser which constitute a refrigerant circuit together with the cooler are installed in the machine room. Further, a machine room fan (condenser fan) driven by a fan motor for air-cooling the compressor and the condenser is installed in the machine room.
[0004]
[Problems to be solved by the invention]
By the way, these cold air circulation internal fan and condenser mechanical room fan are those in which the fan is fixed to the rotating shaft of each fan motor by a spring or the like. In some cases, the fan may be caught by the fan, or the fan motors may be locked due to deterioration over time.
[0005]
However, conventionally, in order to detect which of the two fan motors is locked, it is necessary to attach lock detection devices to both the fan motors in the refrigerator and the machine room, respectively. There was a problem that caused the cost to rise.
[0006]
The present invention has been made to solve such a conventional technical problem, and a single abnormality detection device determines which of the two fan motors of a refrigerator is locked. The purpose is to detect.
[0007]
[Means for Solving the Problems]
That is, the refrigerator abnormality detection device of the present invention includes two fan motors and a control device that controls the operation of these fan motors, and the control device calculates the total value of the current flowing through each fan motor. A current value detecting means for detecting, a rotational speed detecting means for detecting a rotational speed of each fan motor, and a notifying means, and a total value of a current flowing through each fan motor based on an output of the current value detecting means is a lock current. When a state larger than the predetermined period has elapsed, the non-rotating fan motor is determined to be abnormal based on the output of the rotational speed detecting means, and an abnormality detecting operation for operating the notifying means is performed.
[0008]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is an electric circuit diagram of the refrigerator of the present invention, and FIGS. 2 and 3 are flowcharts showing programs of a microcomputer attached to the refrigerator of the present invention.
[0009]
In FIG. 1, reference numeral 2 denotes a general-purpose microcomputer constituting the control device 1 of the refrigerator. The microcomputer 2 includes a fan motor drive circuit 31, a machine room fan motor drive circuit 32, and an alarm circuit 33. It is connected. In the internal fan motor drive circuit 31, a PWM (pulse width modulation) output port of the microcomputer 2 is connected to the base of the transistor 7 via the resistor 3. The emitter of the transistor 7 is grounded, the collector is connected to the base of the transistor 8 via the resistor 4, and the emitter of the transistor 8 is connected to a DC + 16.5V power supply.
[0010]
The collector of the transistor 8 is connected to one terminal of the fan motor 17 via the forward diode 12 and the coil L1. A capacitor 10 is connected between the coil L1 and the ground, and the coil L1 and the capacitor 10 form a smoothing circuit. A surge absorbing diode 13 is connected between the diode 12 and the coil L1 and between the ground.
[0011]
The fan motor 17 is composed of a DC motor and drives a fan in the refrigerator (not shown) that circulates cool air in the refrigerator. The in-compartment fan includes the fan motor 17 and a fan fixed to a rotating shaft of the fan motor 17 by a spring or the like. Further, the fan motor 17 has a built-in Hall IC serving as rotation speed detecting means, and the output of the Hall IC is connected to the base of the transistor 9 via the resistor 5. The emitter of this transistor 9 is grounded, and the collector is connected via a resistor 6 to a DC +5 V power supply. The collector and the resistor 6 are connected to a rotation speed input port of the microcomputer 2.
[0012]
The Hall IC generates an output corresponding to the rotation speed of the fan motor 17 and turns on / off the transistor 9 to input the rotation speed of the fan motor 17 to the rotation speed input port of the microcomputer 2. The other terminal of the fan motor 17 is grounded via a resistor 18 as small as about 10 ohms.
[0013]
The machine room fan motor drive circuit 32 has the same circuit configuration as the in-compartment fan motor drive circuit 31. That is, in the machine room fan motor drive circuit 32, another PWM (pulse width modulation) output port of the microcomputer 2 is connected to the base of the transistor 7A via the resistor 3A. The emitter of the transistor 7A is grounded, the collector is connected to the base of the transistor 8A via the resistor 4A, and the emitter of the transistor 8A is connected to a DC + 16.5V power supply.
[0014]
The collector of the transistor 8A is connected to one terminal of a fan motor 17A via a forward diode 12A and a coil L1A. A capacitor 10A is connected between the coil L1A and the ground, and the coil L1A and the capacitor 10A form a smoothing circuit. A surge absorbing diode 13A is connected between the diode 12A and the coil L1A and between the ground.
[0015]
The fan motor 17A is constituted by a DC motor, circulates air in a machine room of a refrigerator (not shown), and drives a machine room fan for air cooling of a compressor and a condenser of a cooling device (not shown). The machine room fan includes the fan motor 17A and a fan fixed to a rotating shaft of the fan motor 17A by a spring or the like. The fan motor 17A also has a built-in Hall IC serving as a rotation speed detecting means, and the output of the Hall IC is connected to the base of the transistor 9A via a resistor 5A. The emitter of this transistor 9A is grounded, and the collector is connected to a DC + 5V power supply via a resistor 6A. The collector and the resistor 6A are connected to another rotation speed input port of the microcomputer 2.
[0016]
The Hall IC generates an output according to the rotation speed of the fan motor 17A, and turns on / off the transistor 9A to input the rotation speed of the fan motor 17A to the rotation speed input port of the microcomputer 2. The other terminal of the fan motor 17A is also grounded via the resistor 18. That is, the resistor 18 is configured to flow a current in which the currents flowing through the two fan motors 17 and 17A are combined.
[0017]
The voltage between the fan motors 17 and 17A and the resistor 18 is connected to the plus input terminal of the OP amplifier 14, and the minus input terminal of the OP amplifier 14 is grounded via the resistor 19. A negative feedback resistor 16 is connected between the output of the OP amplifier 14 and the negative input terminal, and the output of the OP amplifier 14 is connected to an A / D (analog / digital) conversion input port of the microcomputer 2. .
[0018]
As described above, since the total current of the two fan motors 17 and 17A flows through the resistor 18, a voltage proportional to the total current value is amplified by the OP amplifier 14 and input to the A / D conversion input port of the microcomputer 2. Configuration.
[0019]
The alarm output port of the microcomputer 2 is connected to the base of a transistor 22 via a resistor 20, and the emitter of the transistor 22 is grounded. The collector of the transistor 22 is connected via a resistor 21 to one end of an alarm device 23 composed of an LED as an alarm means, and the other end of the alarm device 23 is connected to a DC + 5V power supply. The alarm device 33, the transistor 22, and the resistors 20, 21 constitute the alarm circuit 33.
[0020]
The microcomputer 2 generates an output from each of the PWM output ports, and controls ON / OFF of the transistor 8 or 8A via the transistor 7 or 7A. In this case, the fan motors 17 and 17A are turned ON and OFF by issuing ON and OFF commands in synchronization with ON / OFF of the compressor based on the temperature of the refrigerator (not shown). Is also turned off when is opened. The transistors 8 and 8A output a pulse having a width corresponding to the ON time, and the pulse is smoothed by the coil L1 (L1A) and the capacitor 10 (10A) and applied to each fan motor 17 or 17A.
[0021]
The microcomputer 2 changes the voltage applied to each fan motor 17, 17A by changing the ON time of the transistor 8 or 8A, that is, the pulse width, thereby changing the rotation speed of the fan motor 17, 17A. It is to adjust.
[0022]
Next, control of the number of revolutions of the fan motor 17 of the internal fan motor drive circuit 31 by the microcomputer 2 will be described with reference to FIG. Since the rotation speed control of the fan motor 17A of the machine room fan motor drive circuit 32 is the same, the description is omitted. Also, the microcomputer 2 is assumed to have preset rotation speeds of the respective fan motors 17 and 17A.
[0023]
The microcomputer 2 determines in step S1 whether an operation (ON) command for the fan motor 17 has been issued, and if the operation command has been issued and the fan motor 17 is operating, sets a certain time in step S2. Proceed to step S3.
[0024]
In step S3, the microcomputer 2 determines whether or not the fixed time set in step S2 has elapsed. If the fixed time has not elapsed, the microcomputer 2 repeats step S3 and waits. When the predetermined time has elapsed in step S3, the process proceeds to step S4, where the microcomputer 2 determines that the rotation speed of the fan motor 17 input to the rotation speed input port as described above is equal to the preset rotation speed. It is determined whether or not the rotation speeds are equal, and if the rotation speed is the set rotation speed, the process returns to step S2.
[0025]
If the rotation speed of the fan motor 17 is different from the set rotation speed in step S4, the process proceeds to step S5, and it is determined whether the rotation speed of the fan motor 17 is higher than the set rotation speed. If it is higher than the set rotation speed, the process proceeds to step S6. Therefore, the microcomputer 2 subtracts the set number of revolutions from the current number of revolutions of the fan motor 17 input to the number of revolutions input port and divides the result by a predetermined ratio A. After the conversion to ΔV, the process proceeds to step S7.
[0026]
Here, the microcomputer 2 changes the rotation speed of the fan motor 17 in a predetermined number of steps. In the conversion in step S6, if the difference between the rotation speeds is small, the calculation result is smaller than 1. , ΔV is determined to be 0. Therefore, in step S7, the microcomputer 2 determines whether or not the calculation result in step S6 is 0. If the calculation result is 0, the microcomputer 2 proceeds to step S8, sets ΔV to 1 (step), and proceeds to step S9. If it is not 0 in step S7, the process proceeds directly to step S9.
[0027]
In step S9, the microcomputer 2 determines a value obtained by subtracting the calculation result ΔV in step S6 or step S8 from the voltage currently applied to the fan motor 17 as the voltage to be applied to the fan motor 17. Based on this determination, the microcomputer 2 reduces the voltage applied to the fan motor 17 and reduces the rotation speed by reducing the pulse width.
[0028]
On the other hand, when the rotation speed of the fan motor 17 is lower than the set rotation speed, the process proceeds from step S5 to step S10. Therefore, the microcomputer 2 subtracts the current rotation speed of the fan motor 17 input to the rotation speed input port from the set rotation speed, similarly divides the ratio by the ratio A, and determines the difference between the rotation speeds as the number of voltage change steps ΔV After that, the process proceeds to step S11.
[0029]
In step S11, the microcomputer 2 determines whether or not the calculation result in step S10 is 0. If the calculation result is 0, the microcomputer 2 proceeds to step S12, sets ΔV to 1 (step) as described above, and proceeds to step S13. If it is not 0 in step S11, the process directly proceeds to step S13.
[0030]
Then, in step S13, the microcomputer 2 determines a value obtained by adding the calculation result ΔV of step S10 or step S12 to the voltage currently applied to the fan motor 17 as the voltage to be applied to the fan motor 17. The microcomputer 2 increases the voltage applied to the fan motor 17 by increasing the pulse width based on this determination, thereby increasing the rotation speed.
[0031]
After the processing in step S9 or step S13, the microcomputer 2 returns to step S2, sets a fixed time again, waits in step S3, and then executes the rotation speed adjustment in step S4 and thereafter.
[0032]
Note that the machine room fan motor 17A of the machine room fan motor drive circuit 32 is also controlled in the same manner as the in-compartment fan motor drive circuit 31, but in this case, the determination in step S4 is based on the setting rotation of the machine room fan motor 17A. The numbers are of interest.
[0033]
The means (Hall IC) for detecting the number of revolutions of the fan motor 17 (17A) is provided, and the microcomputer 2 controls the number of revolutions of the fan motor 17 to the set number of revolutions based on the number of revolutions output from the Hall IC. Therefore, even if the load applied to the fan motor 17 fluctuates, the set rotation speed can be maintained.
[0034]
In particular, since the microcomputer 2 repeatedly adjusts the rotation speed of the fan motor 17 (17A) at a constant cycle (constant time), the microcomputer 2 starts the adjustment at a stage where the rotation speed is stabilized after the fan motor 17 is started. The adjustment is performed at a constant cycle. Thus, the operation of the fan motor 17 can be stabilized.
[0035]
Next, an operation of detecting an abnormality of the refrigerator by the microcomputer 2 will be described with reference to FIG. The lock current in the case where both the in-compartment fan motor 17 and the machine room fan motor 17A are locked (a state in which the rotating shaft is locked and the motor does not rotate despite the energization) is assumed to be a specified value 1. The lock current when one of the fan motor 17 and the fan motor 17A is locked is stored in the microcomputer 2 as the specified value 2 in advance.
[0036]
The microcomputer 2 determines in step S21 whether an operation (ON) command for the in-compartment fan motor 17 has been issued, and if the operation command has been issued, proceeds to step S22. In step S22, it is determined whether or not an operation (ON) command for the machine room fan motor 17A has been issued. If so, the process proceeds to step S23. Then, the microcomputer 2 sets the lock current to the specified value 1 in step S23 and proceeds to step S26 because the operation commands of the two fan motors 17 and 17A have been issued.
[0037]
If the operation command of the in-compartment fan motor 17 has not been issued in step S21, the microcomputer 2 proceeds to step S24, in which it determines whether or not the operation command of the machine room fan motor 17A has been issued. If the operation command of 17A has been issued, the process proceeds to step S25, where the lock current is set to the specified value 2 and the process proceeds to step S26.
[0038]
If the operation command of the machine room fan motor 17A has not been issued in step S24, the process returns to step S21. That is, the microcomputer 2 waits by repeating steps S21 and S24 when the operation command of both fan motors 17 and 17A is not issued.
[0039]
Also, when the operation command of the machine room fan motor 17A is not issued in step S22, the process proceeds to step S25, and the lock current is set to the specified value 2, and the process proceeds to step S26.
[0040]
That is, the microcomputer 2 sets the lock current to the specified value 1 when the operation command of both the fan motors 17 and 17A is issued in step S23, and at step S25, selects one of the two fan motors 17 and 17A. If an operation command has been issued, the lock current is set to the specified value 2 and the process proceeds to step S26.
[0041]
Then, in step S26, the timer is set to 2 seconds, and the process proceeds to step S27. In step S27, the microcomputer 2 determines whether or not the total current of the two fan motors 17 and 17A input to the A / D conversion input port is larger than the lock current set as described above. That is, when the operation command of both fan motors 17 and 17A is issued, the total current is larger than the specified value 1, and when either one of the operation commands is issued, the total current is larger than the specified value 2. It is determined whether or not each is larger.
[0042]
If the current is not larger than the lock current, the process returns to step S21, and if larger, the process proceeds to step S28. Then, it is determined in step S28 whether or not 2 seconds have elapsed, and in the case of NO, the process returns to step S27. That is, by repeating steps S27 and S28, it is determined whether or not the state where the total current is larger than the lock current has continued for 2 seconds.
[0043]
If YES in step S28, the microcomputer 2 determines in step S29 whether or not the internal fan motor 17 is rotating based on the data of the rotational speed input port, and detects the rotational speed signal. The process proceeds to step S32.
[0044]
Further, in step S32, the microcomputer 2 determines whether or not the machine room fan motor 17A is rotating based on the data of the rotation speed input port. Proceed to processing.
[0045]
If the rotation speed signal of the internal fan motor 17 does not enter the rotation speed input port of the microcomputer 2 in step S29 (in this case, the internal fan motor 17 is stopped), the process proceeds to step S30. Then, in step S30, the lock of the in-compartment fan motor 17 is notified and the process proceeds to step S31, in which the operation of the in-compartment fan motor 17 is stopped, and the process proceeds to step S32. That is, the microcomputer 2 blinks the alarm device 23 and stops the operation of the internal fan motor 17.
[0046]
That is, if a command to operate the internal fan motor 17 is issued, and the detected current is larger than the lock current, and the fan motor 17 is not rotating, it is determined that the fan motor 17 is locked. The judgment is made, an alarm is issued, and the operation command of the in-compartment fan motor 17 is canceled to stop the operation of the in-compartment fan motor 17.
[0047]
When the rotation speed signal of the machine room fan motor 17A does not enter the rotation speed input port of the microcomputer 2 in step S32 (in this case, the machine room fan motor 17A is stopped), the machine room fan motor 17A is locked. Then, the process proceeds to step S33. Then, in step S33, the lock of the machine room fan motor 17A is notified, and the process proceeds to step S34, in which the operation of the machine room fan motor 17A is stopped. That is, the microcomputer 2 blinks the alarm device 23 and stops the operation of the machine room fan motor 17A.
[0048]
That is, when a command to operate the machine room fan motor 17A is issued, and the detected current is larger than the lock current, and the fan motor 17A is not rotating, it is assumed that the fan motor 17A is locked. The judgment is made, an alarm is issued, and the operation command of the fan motor 17A is canceled to stop the operation of the machine room fan motor 17A.
[0049]
As described above, when a state in which the total current flowing through the two fan motors 17 and 17A is larger than the lock currents of the two fan motors 17 and 17A has passed for a certain period (2 seconds), the microcomputer 2 determines which of the two It is determined that the fan motors 17 and 17A are abnormal, the alarm device 23 is operated, and the operation of the non-rotating fan motor 17 (17A) is stopped. Thus, the locked fan motor 17 (17A) can be accurately detected.
[0050]
In addition, since one of the two fan motors 17 and 17A can detect whether one of the two fan motors 17 and 17A is locked by a single OP amplifier 14 or the like, the cost can be significantly reduced. It becomes possible.
[0051]
【The invention's effect】
As described above in detail, according to the present invention, in a refrigerator including two fan motors, the control device detects current value detection means for detecting a total value of current flowing through each fan motor, and controls rotation of each fan motor. A number of rotations detecting means for detecting the number, and a notifying means, based on the output of the current value detecting means, when a state in which the total value of the current flowing through each fan motor is larger than the lock current has passed for a certain period of time, Based on the output of the rotation speed detection means, it is determined that the fan motor that is not rotating is abnormal, and the abnormality detection operation for operating the notification means is performed. It is possible to accurately detect and judge an increase in the current value due to the lock of the fan motor, and to notify the increase by the notification means.
[0052]
In addition, since a single abnormality detection device can detect which one of the two fan motors is locked, cost can be reduced. In particular, in this case, since an operation such as stopping one of the fan motors is not required, a quick abnormality determination can be performed, and the adverse effect on the cooling action can be minimized.
[Brief description of the drawings]
FIG. 1 is an electric circuit diagram of a refrigerator according to the present invention.
FIG. 2 is a flowchart showing a program of a microcomputer relating to fan motor control of the refrigerator of the present invention.
FIG. 3 is a flowchart showing a program of a microcomputer relating to an abnormality detection operation of the refrigerator of the present invention.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Abnormality detection device 2 Microcomputer 3 Resistance 4 Resistance 5 Resistance 6 Resistance 7 Transistor 8 Transistor 9 Transistor 10 Capacitor 12 Diode 13 Diode 14 OP amplifier 16 Resistance 17 Fan motor 17A Fan motor 18 Resistance 19 Resistance 20 Resistance 21 Resistance 22 Transistor 23 Alarm Device 31 Internal fan motor drive circuit 32 Machine room fan motor drive circuit 33 Alarm circuit

Claims (1)

In a refrigerator equipped with two fan motors and a control device for controlling the operation of these fan motors,
The control device includes a current value detection unit that detects a total value of current flowing through each of the fan motors, a rotation speed detection unit that detects a rotation speed of each of the fan motors, and a notification unit. When a state in which the sum of the currents flowing through the respective fan motors is larger than the lock current for a certain period based on the output of the means has elapsed for a certain period, the fan motor that is not rotating is abnormal based on the output of the rotation speed detecting means. And performing an abnormality detection operation for operating the notification means.

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