JP2006271055A - Resetting method of overcurrent protection circuit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a resetting method of an overcurrent protection circuit capable of surely driving a load, by allowing a current to flow the load after confirming whether an overcurrent protection element is reset. <P>SOLUTION: If abnormality occurs in driving of a motor M, a voltage across both terminals of a thermister 42 is fetched via an A/D conversion circuit 16, to detect temperature of a PTC thermistor 41. The detected temperature is compared with the temperature in normal state for deciding abnormality. In case of abnormality, a load drive control signal output is stopped. When the temperature of the PTC thermistor 41 restores to the temperature in a normal state, interruption of the output of the load drive control signal is released. Thus, a load is surely operated by allowing a current to flow the load, after confirming whether the PTC thermister 41 has been reset. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a reset method for an overcurrent protection circuit, that is, a reset method when a load is not driven by an overcurrent protection element.

  Many terminal motors such as fan motors, toner transport motors, and paper transport motors are used in terminal devices such as digital multi-function peripherals and facsimile machines. Since there is a possibility of damage due to a layer short of the motor winding or damage due to overheating of the motor drive circuit, power supply to the motor is stopped when the current flowing through the motor exceeds the reference current. It was.

  However, in such a configuration, the circuit becomes complicated, so it is possible to cut off the current at the time of abnormal load using a thermal fuse or a current fuse. However, if a fuse is used in this way, the fuse is rated. When a current greater than the current flows, the current is cut and power supply to a load such as a DC motor is stopped. After that, when the load of the terminal device such as a digital multi-function peripheral is driven again, an error is displayed, and the fuse needs to be replaced for normal operation, which is troublesome. The problem arises.

For this reason, it has been proposed to use a polymer-based PTC thermistor (positive temperature coefficient thermistor) having a PTC (Positive Temperature Coefficient Resistor) characteristic in which the resistance value increases as the temperature rises (for example, as a protective element). , See Patent Document 1).
Japanese Patent Laid-Open No. 6-167881

As shown in the temperature-resistance characteristic diagram of FIG. 9, the PTC thermistor has a very low resistance value when the circuit is operating normally, an overcurrent flows and is overheated. The resistance changes (trips) and limits the flowing current.
Therefore, by connecting this PTC thermistor in series with a load such as a motor, when an overcurrent flows through the load, the PTC thermistor self-heats due to this overcurrent. It becomes resistance and can reduce load current and prevent breakage of the load. Since a small current continues to flow even after the PTC thermistor becomes high resistance, heat generation continues as long as a voltage is applied to the load, and the PTC thermistor does not return to low resistance.

  On the other hand, when the power supply of the load is cut off, the resistance value of the PTC thermistor gradually returns from the high resistance to the reference resistance value due to cooling, and when the temperature drops even when tripped, it returns to the normal state. Therefore, it is possible to perform stable control without the need for resetting at the time.

  As described above, conventionally, a PTC thermistor is used to protect a load such as a motor from overcurrent. However, once the PTC thermistor enters the trip region, it takes time until the resistance value returns to the original state. Even if a current is immediately applied to the load, a sufficient current does not flow, the load cannot be driven, and the device becomes an error.

In this case, after the occurrence of an abnormality, it can be temporarily released with the stop or reset key of the terminal device body, but since the control circuit can be enabled again at the time of operation requiring subsequent load driving such as a DC motor, In some cases, the drive circuit may be adversely affected.
In other words, if it takes time for the PTC thermistor to enter the trip region and the resistance value to return to the original value, the load cannot be driven → Error display → Temporary release with a stop key etc. → Load drive (control circuit operation) → The load cannot be driven → Error display will be repeated.

  The present invention has been made in view of the above-described problems, and overcurrent protection that can surely drive a load by flowing current to the load after confirming whether or not the overcurrent protection element has been reset. An object of the present invention is to provide a circuit reset method.

  In order to achieve the above-mentioned object, the overcurrent protection circuit reset method of the invention according to claim 1 measures the resistance value of the overcurrent protection element, and if the measured resistance value is equal to or lower than a predetermined resistance value, It is assumed that the current protection element is reset, and the drive of the load is permitted. On the other hand, when the measured resistance value is larger than the predetermined resistance value, the drive of the load is not permitted.

  The overcurrent protection circuit reset method of the invention according to claim 2 is the overcurrent protection circuit reset method according to claim 1, wherein whether or not the overcurrent protection circuit is greater than a predetermined resistance value is determined at room temperature. It is based on the comparison with the resistance value of the overcurrent protection element.

  Furthermore, the overcurrent protection circuit reset method of the invention according to claim 3 is such that the temperature of the overcurrent protection element is measured, and the overcurrent protection element is reset if the measured temperature falls below a predetermined temperature. While driving the load is permitted, the driving of the load is not permitted when the measured temperature is higher than a predetermined temperature.

  According to a fourth aspect of the present invention, there is provided a reset method for an overcurrent protection circuit according to any one of the first to third aspects, wherein when driving of a load is not permitted, This is notified.

According to the reset method of the overcurrent protection circuit of the inventions according to claims 1 to 3, after confirming whether or not the overcurrent protection element has been reset based on the resistance value or temperature of the overcurrent protection element. Since current can flow through the load, the load can be operated reliably.
Further, according to the reset method of the overcurrent protection circuit of the invention according to claim 4, when the load cannot be driven, the user is notified of this, a standby until resetting or a request for replacement of the overcurrent protection element, etc. It is possible to allow the user to take appropriate processing.

Hereinafter, an embodiment in which the reset method of an overcurrent protection circuit of the present invention is applied to a digital multi-function peripheral will be described with reference to the drawings.
FIG. 1 is a schematic block diagram showing the configuration of a control system of a digital multi-function peripheral. As shown in the figure, the digital multi-function peripheral has an MPU 1, a ROM (Read Only Memory) 2, a RAM (Random Access Memory) 3, a display / operation. A unit 4, a CCD 5, a scanner image processing circuit 6, an image memory 7, a printer 8, a codec 9, a modem 10, a network control unit NCU 11, a timer 12, and an interface 13 are connected to each other via a bus 14.

  The MPU 1 controls each part of the hardware of the digital multi-function peripheral via the bus 14, and executes various programs based on the programs stored in the ROM 2. The ROM 2 performs various programs and operations necessary for the operation of the digital multi-function peripheral. Messages, error messages, etc. are stored in advance. The RAM 3 is composed of an SRAM or the like, and stores temporary data generated when the program is executed, and the normal temperature or resistance value of the PTC thermistor, the set value of the number of times of abnormality detection until the service call is displayed, and the like Remember.

  The display / operation unit 4 includes a display unit that displays an operation state of the digital multifunction peripheral and displays an operation screen for various functions, and an operation unit that includes a plurality of operation keys for operating the digital multifunction peripheral. As shown in FIG. 2 as an example, the LCD display unit 21 constituting the display unit, and the numeric keypad 22, start key 23, reset key 24, stop key 25, cross key 26, return key 27 as the operation unit. Various keys such as a set key 28, a FAX switching key 29, a copy switching key 30, and a scanner switching key 31 are provided.

The CCD 5 reads a document set on a reading document placing table such as an auto document feeder (ADF) or a flatbed scanner (FBS) and outputs an analog image signal, and a scanner image processing circuit 6 outputs the analog image signal from the CCD 5. Processed into dot image data.
The image memory 7 is constituted by using a DRAM or the like, and stores image data to be transmitted or received image data or image data read by the CCD 5, and the printer 8 is an electrophotographic printer or the like. Printed out data, copy original data, and the like.

  The codec 9 encodes and decodes image data in accordance with a predetermined protocol. In order to transmit the image data of the read original, the codec 9 encodes the image data by the MH, MR, or MMR method, and receives the image data received from the outside. The modem 10 is connected to the bus 14 and has a function as a fax modem capable of facsimile communication. The modem 10 is also connected to the NCU 11 connected to the bus 14. The NCU 11 is hardware for closing and opening an analog line, and connects the modem 10 to a public switched telephone network (PSTN) 17 as necessary.

  The timer 12 measures the time, and the interface 13 is connected to motor drivers 15 and A / D conversion circuits 16 of a large number of motors M such as a fan motor, a toner transport motor, and a paper transport motor. . The MPU 1 drives each motor M via the interface 13 and the motor driver 15 and takes in a signal input to the A / D conversion circuit 16 via the interface 13.

  The digital multi-function peripheral has the above-described configuration. When sending a facsimile, the image data of the original is read by the CCD 5, and the signal processed by the scanner image processing circuit 6 is compressed by the codec 9 and stored in the image memory 7. Is done. The compressed image data is read from the image memory 7, modulated by the modem 10, and transmitted from the NCU 11 to the communication partner through the PSTN 17. At the time of facsimile reception, the received image data is demodulated by the modem 10, stored in the image memory 7, decoded by the codec 9 and printed by the printer 8.

On the other hand, FIG. 3 is a diagram showing a drive circuit of the motor M, and a series circuit of the motor M and the PTC thermistor 41 is inserted between the power supply Vcc and the drive transistor Tr. When a control signal is input to the transistor Tr via the resistor R1 and the control signal is turned ON, the transistor Tr is turned on and the motor M is driven. The diode D is a diode for overvoltage protection.
Further, a normal thermistor 42 as a temperature sensor is provided in the vicinity of the PTC thermistor 41, and a series circuit of the thermistor 42 and a resistor R2 is connected between the power source Vcc and the ground. The voltage across the thermistor 42 is input to the A / D conversion circuit 16 connected to the interface 13 in FIG.

  Thus, by connecting the PTC thermistor 41 in series to the motor M, as described above, when an overcurrent flows through the motor M, the PTC thermistor 41 self-heats due to this overcurrent, and the temperature of the PTC thermistor 41 is increased. However, for example, when the temperature exceeds 80 ° C., the PTC thermistor 41 has a high resistance, the load current can be reduced, and the motor M can be prevented from being damaged.

Next, the operation of the digital multi-function peripheral when an overcurrent flows and the PTC thermistor trips will be described.
The flowchart of FIG. 4 shows the operation when the digital multifunction peripheral is shipped or when a service person installs the device. At the time of shipment or when the device is installed, the temperature of the PTC thermistor at which the operator can determine that it has returned to normal. For example, after setting 50 ° C. (step 101), the number of times of abnormality detection until the service call display is performed, for example, 5 times is set (step 102). These set values are stored in the RAM 3.

Next, the operation of the MPU 1 at the time of load driving in the steady operation will be described with reference to the flowchart of FIG.
When the power of the digital multi-function peripheral is turned on, the MPU 1 starts the program shown in the flowchart of FIG. 5 and enters a standby state (step 201). When a copy operation or fax transmission / reception operation is performed, the MPU 1 drives a load such as the motor M (step 202).

  At this time, the MPU 1 determines whether or not there is an abnormality in driving of the motor M from the output of the paper detection sensor or toner sensor (not shown) (step 203). Return. On the other hand, when it is determined that an abnormality has occurred in driving the motor M, the MPU 1 detects the temperature of the PTC thermistor 41 by taking in the voltage across the thermistor 42 via the A / D conversion circuit 16 and the interface 13 ( Step 204).

  Next, the MPU 1 determines whether or not the detected temperature is abnormal by comparing the detected temperature of the PTC thermistor 41 with the normal temperature (50 ° C.) stored in the RAM 3 (step 205). If it is determined that is not abnormal, the process returns to step 201. On the other hand, when it is determined that the detected temperature is higher than 50 ° C. and abnormal, the MPU 1 stops outputting the load drive control signal (step 206), and then displays, for example, “motor drive error, for a while. An error message such as “Please wait” is displayed (step 207).

  Next, the MPU 1 adds 1 to the number of abnormality detections (initial value: 0) stored in the RAM 3 and stores it in the RAM 3 (step 208), and then the number of abnormality detections is stored in the RAM 3 (step 208). (5 times) has been exceeded (step 209). If it is determined that the number of abnormality detections has not exceeded the set number of times, the timer 12 starts counting and whether or not 5 minutes have elapsed from the output of the timer 12 Is determined (step 210).

Then, when 5 minutes have elapsed from the start of the timer 12, the MPU 1 again detects the temperature of the PTC thermistor 41 by taking in the voltage across the thermistor 42 via the A / D converter circuit 16 and the interface 13 (step S1). 211) It is determined whether the detected temperature is abnormal by comparing the detected temperature with the normal temperature (step 212). When it is determined that the detected temperature is not abnormal, the MPU 1 cancels the output stop of the load drive control signal (step 213), and then returns to step 201.
As described above, since the current flows through the load after confirming whether or not the temperature of the PTC thermistor 41 has returned to near the steady state, that is, whether or not the PTC thermistor 41 has been reset, It can be operated.

On the other hand, if the detected temperature is determined to be abnormal again in step 212, the MPU 1 continues to stop outputting the load drive control signal, continues to display the error, and counts up the number of times of abnormality detection, and then stores the number of times of abnormality detection in the RAM 3 again. It is determined whether the set number of times (5 times) has been exceeded (step 209). If it is determined that the number of abnormality detections exceeds the set number, the MPU 1 displays a serviceman call display such as “Please call a serviceman” on the LCD display unit 21 (step 214), and ends the program.
That is, when the temperature of the PTC thermistor 41 does not decrease even after 25 minutes or more, or when the temperature of the PTC thermistor 41 has once decreased, but the temperature of the PTC thermistor 41 has increased five times or more, a service call display is displayed. Is done.

In the above embodiment, the abnormal state is detected by detecting the temperature of the PTC thermistor. However, the abnormal state can also be detected by the resistance value of the PTC thermistor. Hereinafter, the embodiment of detecting the resistance value of the PTC thermistor will be described. explain.
FIG. 6 is a diagram showing a motor drive circuit when an abnormal state is detected by the resistance value of the PTC thermistor. A resistor R3 is connected between the connection point of the motor M and the PTC thermistor 41 and the ground. The resistance value of the resistor R3 is set to a sufficiently large value and does not affect the driving current of the motor M. On the other hand, the voltage obtained by dividing the power supply voltage Vcc by the PTC thermistor 41 and the resistor R3 is A / D. By inputting to the conversion circuit 16, the resistance of the PTC thermistor 41 can be detected.

  FIG. 7 is a flowchart showing the operation when the digital multifunction peripheral is detected when an abnormal state is detected by the resistance value of the PTC thermistor or when the service person installs the equipment. After setting the resistance value of the PTC thermistor determined to have returned, for example, 10Ω (step 301), the number of times of abnormality detection until the service call display is performed, for example, 5 times is set (step 302). These set values are stored in the RAM 3 as described above.

  FIG. 8 is a flowchart showing the action of the MPU 1 at the time of load driving in a steady operation when an abnormal state is detected by the resistance value of the PTC thermistor. In steps 404 and 411, instead of the temperature, the PTC thermistor 41 and the resistance Whether the resistance value of the PTC thermistor 41 is abnormal by detecting the resistance value of the PTC thermistor 41 from the divided voltage with R3 and comparing the detected resistance value of the PTC thermistor 41 with a normal value (10Ω) in steps 405 and 412. The only difference is in determining whether or not, and the other operations are the same as those in the flowchart of FIG.

  As described above, by determining whether or not the resistance value of the PTC thermistor is abnormal, it is possible to flow a current through the load after confirming whether or not the PTC thermistor has been reset. It is possible to operate a load such as a motor.

In the above embodiment, the example in which the reset method of the overcurrent protection circuit of the present invention is applied to the motor abnormality protection circuit of the digital multifunction peripheral has been described. It can also be applied to loads other than devices and motors.
In the above embodiments, the case where the method of resetting the overcurrent protection circuit of the present invention is applied to a protection circuit in which a PTC thermistor is provided in the motor has been described. It is also possible to use other elements whose resistance value changes rapidly.

  Furthermore, in the above embodiment, when the drive of the load is not permitted, an error is displayed on the LCD display unit. However, an abnormal state can be notified by voice or the like, and in the above embodiment, the PTC thermistor Although the thermistor is used to detect the temperature, other temperature sensors such as thermocouples can also be used.

2 is a block diagram illustrating a hardware configuration of a digital multi-function peripheral. FIG. It is a figure which shows the detail of a display and operation part. 2 is a diagram illustrating a drive circuit of a motor M. FIG. 6 is a flowchart illustrating an operation when a digital multifunction peripheral is shipped and when a device is installed. It is a flowchart which shows the effect | action of MPU at the time of the load drive in steady operation. It is a figure which shows the motor drive circuit in the case of detecting an abnormal state with the resistance value of a PTC thermistor. It is a flowchart which shows the effect | action at the time of the shipment of the digital multi-functional peripheral and apparatus installation in the case of detecting an abnormal state with the resistance value of a PTC thermistor. It is a flowchart which shows the effect | action of MPU at the time of the load drive in steady operation in the case of detecting an abnormal state with the resistance value of a PTC thermistor. It is a figure which shows the temperature-resistance characteristic of a PTC thermistor.

Explanation of symbols

1 MPU
2 ROM
3 RAM
4 Display / Operation unit 5 CCD
6 Scanner image processing circuit 7 Image memory 8 Printer 9 Codec 10 Modem 11 NCU
12 Timer 13 Interface 14 Bus 15 Motor Driver 16 A / D Converter 17 PSTN
21 LCD display

Claims (4)

  The resistance value of the overcurrent protection element is measured, and if the measured resistance value falls below the predetermined resistance value, it is assumed that the overcurrent protection element has been reset, and the drive of the load is permitted, while the measured resistance value is A method of resetting an overcurrent protection circuit, wherein driving of a load is not permitted when the resistance value is larger than a predetermined resistance value. In the reset method of the overcurrent protection circuit according to claim 1,
A method for resetting an overcurrent protection circuit, wherein whether or not the resistance value is greater than a predetermined resistance value is determined based on a comparison with a resistance value of an overcurrent protection element at room temperature.   The temperature of the overcurrent protection element is measured, and if the measured temperature falls below the predetermined temperature, the overcurrent protection element is assumed to be reset, and the drive of the load is permitted, while the measured temperature is lower than the predetermined temperature. A method for resetting an overcurrent protection circuit, characterized by not permitting driving of a load when the load is high. In the reset method of the overcurrent protection circuit according to any one of claims 1 to 3,
A method of resetting an overcurrent protection circuit, wherein when a drive of a load is not permitted, it is notified.

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