JP4141408B2 - Electronics - Google Patents

Description

  The present invention relates to an electronic device that receives power supply from an external power source via a main switch and operates with the supplied power, and in particular, heat generated by an operation unit of the electronic device is generated by a cooling unit. The present invention relates to an electronic device that cools and operates the cooling means for a predetermined time after the main switch is opened.

  Conventionally, as this type of technology, for example, there is an image forming apparatus disclosed in Japanese Patent Application Laid-Open No. 2001-5366. In an electronic apparatus such as this image forming apparatus, particularly in the fixing process in the image forming process, heating is performed, so that the heat stagnates in the apparatus. This heat causes problems such as melting and fixing of toner, acceleration of deterioration of photosensitive material, malfunction of electronic components, and the like. Therefore, the image forming apparatus not only provides cooling by providing a cooling means, but also performs so-called “post-rotation” in which the cooling fan of the cooling means is rotated for a predetermined time after the image forming process of the apparatus main body is completed. In this way, after the processing of the apparatus main body is completed, a phenomenon in which the temperature inside the apparatus main body, the cartridge, or the like rises due to stagnation of air is prevented. However, when the AC power supply is cut off due to a power failure, the main power switch being cut off, or the like, the cooling fan immediately stops rotating and the temperature inside the apparatus body rises abnormally.

  In view of this, the prior art disclosed in Patent Document 1 includes detection means for generating a signal by detecting that the AC power supply is shut off in an image forming apparatus including a cooling means for cooling the heat generated by the image forming process. And a post-shutdown drive means for driving the cooling means for a predetermined time even after the AC power supply is shut off when receiving the signal generated by the detection means. Specifically, when the AC input is applied, the detection means can detect the zero cross signal at a predetermined timing based on the waveform of the AC power supply voltage, but stops sending the zero cross signal when the AC input is interrupted. To do.

  Therefore, it is possible to determine whether or not the AC input is interrupted by monitoring the zero cross signal by the detecting means. The main body fan, which is a cooling means, is connected to a capacitor via a normally closed relay contact, separately from the ON / OFF switching transistor. When the AC input is shut off, the normally-closed relay contact is closed, and the post-cut-off drive means discharges the voltage charged in the capacitor via the main body fan. In this way, the main body fan operates only during the discharge period to cool the generated heat.

  On the other hand, various methods have been proposed for image forming apparatuses as countermeasures for heat dissipation. For example, as shown in the following Patent Document 2 (Japanese Patent Application Laid-Open No. 11-338333), a technique for blocking heat transfer from a heating roller as a heat source to a protected part such as an electronic substrate or a cleaning device is proposed. Has been. This not only provides a space between the heat source part and the protected part, but also provides a cooling effect by using a Peltier element that is a heat conversion element. The Peltier element is provided with its cooling surface in contact with the thermoelectric unit, and supplies power to dissipate heat absorbed from the cooling surface. In this way, temperature rise during operation of the image forming apparatus can be prevented in a low noise state.

  As another conventional example of heat dissipation measures in the image forming apparatus, there is one disclosed in, for example, the following Patent Document 3 (Japanese Patent Laid-Open No. 2003-81510). This utilizes the feature that the Peltier element which is a thermoelectric element is silent. Specifically, the transfer paper that has been heated by passing through the fixing nip portion is cooled by the heat absorbing portion of the heat pipe. The heat pipe instantaneously moves the heat received by the heat absorbing part to the heat radiating part of the heat pipe. The heat radiating part of the heat pipe is in contact with the heat absorbing part of the Peltier element, and is cooled by this heat absorbing part. The Peltier element moves the heat of the heat absorbing portion to the heat radiating portion by passing an electric current. In this way, the transfer paper is cooled in a silent state.

  As another conventional example of heat radiation countermeasures in an image forming apparatus, for example, there is one disclosed in the following Patent Document 4 (International Publication No. 01/088631 pamphlet). In this method, a Peltier unit is provided as a preheating unit in front of the optical fixing device, and preheating is performed to warm the continuous paper in front of the optical fixing device. The Peltier unit is disposed with the waste heat surface facing the paper conveyance path side, and the lower side is the heat absorption surface. A cooling chamber is disposed on the heat absorption surface side of the Peltier unit. The cooling chamber receives air sucked by an air blower installed in the lower part, cools the air sucked by the cooling chamber facing the heat absorbing surface of the Peltier unit, and sends the cooling air to the optical fixing device for cooling.

  For this reason, the Peltier unit performs preheating to warm the continuous paper sent to the light fixing unit by the waste heat, and at the same time, the air sucked by the air blower cools the air by the heat absorption of the Peltier unit and passes the cooled air. The light fixing device is cooled by passing the light through the light fixing device. The Peltier unit is disposed with its waste heat surface facing the paper conveyance path side, and after the continuous paper passing along the conveyance path is heated by the heat from the waste heat surface, it enters the optical fixing device. The lower side of the Peltier unit is an endothermic surface, and a cooling chamber is arranged in contact with the endothermic surface.

  Further, in the following Patent Document 5 (Japanese Patent Laid-Open No. 2003-155802), a conventional technique using a power generation function of a Peltier element is disclosed. In this snow melting apparatus, a Peltier element is provided on the top plate attached to the roof, and power is generated by the temperature difference between the front surface and the back surface of the Peltier element that touch the outside air. This generated power is stored in a battery. When melting snow, the heat rays are heated by the battery power to melt the snow. That is, the Peltier element charges the battery by a power generation function based on the temperature difference between the front and back surfaces.

JP 2001-5366 (paragraph [0002], paragraph [0011], paragraph [0014], paragraph [0016] to paragraph [0020]) JP 11-338333 A (paragraph [0020] to paragraph [0023]) JP 2003-81510 A (paragraph [0042] to paragraph [0050]) International Publication No. 01/088631 pamphlet (8 pages, Fig. 1 and Fig. 3) JP 2003-155802 A (paragraph [0014], paragraph [0015], paragraph [0020], paragraph [0021])

  However, in the prior art disclosed in the above-mentioned Patent Document 1, since the charging voltage of the capacitor is discharged to the fan as the cooling means after the AC power supply is cut off, the fan cannot be operated sufficiently. In other words, an electronic device that generates a large amount of heat and has a high temperature must be sufficiently cooled because its residual heat is also high. It is impossible to operate it. In particular, such a conventional technique has a problem that it is not possible to reliably cool the remaining heat over a sufficient time with a powerful fan.

  On the other hand, in an electronic apparatus having a heat source such as an image forming apparatus, it is considered that cooling is performed using a Peltier element as shown in Patent Documents 2 to 4 described above. Furthermore, as shown in the above-mentioned Patent Document 5, it is considered to charge the battery by using the power generation function of the Peltier element. However, even with these techniques, it is not possible to achieve reliable cooling after the AC power source, which is an external power source, is shut off.

  Therefore, the present invention eliminates the conventional problems, and in cooling the heat generated by the electronic device by the cooling means, even if the power supply from the external power supply is interrupted, the cooling means is operated reliably to cool the remaining heat. An object is to provide a sufficiently performed electronic device.

In order to solve the above-mentioned problem, the invention according to claim 1 of the present application is provided with an operation part and a cooling unit which are supplied with electric power from an external power source via a main switch and are operated by the supplied electric power. In the electronic device that cools the heat generated from the part by the cooling means and operates the cooling means only for a predetermined time after opening the main switch,
Energy conversion means for converting thermal energy generated during operation of the operating portion into electrical energy;
A rechargeable battery for charging the power obtained by the energy conversion means;
AC interruption detection means (for example, thermoelectric element 20) that detects that the power supply from the external power supply is cut off and sends a detection signal;
First control means for operating said cooling means to supply the power for the predetermined time to the cooling means from the charging battery when the detection signal is sent by the AC cutting detection unit (e.g., processing circuit 23 And control means comprising a third switch circuit 24).

In the invention of claim 1, the electronic device is
A detection circuit (for example, the detection circuit 17) for detecting the open / closed state of the main switch and a first control means (for example, a control means comprising an arithmetic processing circuit 23 and a third switch circuit 24);
The AC cutoff detection means detects that the power supply from the external power source is shut off in the closed state of the main switch, and sends a detection signal,
The first control unit supplies the electric power from the rechargeable battery to the cooling unit for the predetermined time when the detection signal is sent to operate the cooling unit.

Further, in the invention according to claim 2 of the present application, in the invention of claim 1 , the electronic device is
A detection circuit for detecting the open / closed state of the main switch and a second control means (for example, a control means comprising a timer circuit 18, an arithmetic processing circuit 23, a third switch circuit 24, etc.);
The AC shutoff detection means detects that power supply from the external power source is shut off during the cooling operation of the cooling means after the main switch is switched from the closed state to the open state, and sends a detection signal. And
The second control means supplies power from the rechargeable battery to the cooling means until the predetermined time ends, and continues the cooling operation.

The present invention has the following excellent effects by including the above-described configuration. That is, in the invention according to claim 1 of the present application, an electric power supply is received from an external power source via the main switch, and an operating part and a cooling unit that operate by the supplied electric power are provided, and the heat generated by the operating part is In the electronic device that is cooled by the cooling means and operates the cooling means only for a predetermined time after opening the main switch, the thermal energy generated during operation is converted into electrical energy by the energy conversion means and charged to the rechargeable battery. The When the power supply from the external power supply is cut off for some reason, the AC cut-off detection means detects this, and the first control means supplies power from the rechargeable battery to the cooling means.

  Therefore, since the cooling means can be operated for a predetermined time by the power charged in the rechargeable battery during operation, firstly, wasteful thermal energy generated by the operation of the electronic device is removed when the external power source is shut off. Since it is used for cooling power, the rechargeable battery does not need to be charged from an external power source, and the power consumption of the electronic device itself can be reduced. Secondly, when charging a rechargeable battery, it is possible to obtain a large amount of large power for a relatively long period of time at a high temperature and to sufficiently charge it, and it operates for a long time using a powerful cooling means. It is possible to reliably eliminate the adverse effects of residual heat.

In the invention according to claim 1 of the present application, an electric power supply is received from an external power source via a main switch, and an operating part and a cooling unit that operate by the supplied electric power are provided, and the heat generated by the operating part is In the electronic device that is cooled by the cooling means and operates the cooling means only for a predetermined time after opening the main switch, the thermal energy generated during operation is converted into electrical energy by the energy conversion means and charged to the rechargeable battery. The And after the main switch is opened and the operation is stopped, the cooling means is continuously operated for a predetermined time to cool the remaining heat, but the power supply from the external power source is cut off when the main switch is closed. Then, the detection circuit and the AC interruption detection means detect this, and the first control means supplies power from the rechargeable battery to the cooling means.

Therefore, the present invention removes the abnormally high temperature of the electronic equipment due to residual heat and prevents the equipment casing, parts, consumables, etc. from being damaged or deteriorated. Have.
First, since wasteful heat energy generated by the operation of the electronic device is used as cooling power when the external power supply is shut off, the rechargeable battery does not need to be charged from the external power supply and the power consumption of the electronic device itself is reduced. Savings can be achieved.
Secondly, when charging a rechargeable battery, it is possible to obtain a large amount of large power for a relatively long period of time at a high temperature and to sufficiently charge it, and it operates for a long time using a powerful cooling means. It is possible to reliably eliminate the adverse effects of residual heat.

Further, in the invention according to claim 2 of the present application, an electric power supply is received from an external power source via the main switch, and an operating part and a cooling unit that are operated by the supplied electric power are provided, and the heat generated by the operating part is In the electronic device that is cooled by the cooling means and operates the cooling means only for a predetermined time after opening the main switch, the thermal energy generated during operation is converted into electrical energy by the energy conversion means and charged to the rechargeable battery. The Then, after the main switch is opened and the operation is stopped, the cooling means is continuously operated for a predetermined time to cool the remaining heat, but during the cooling operation after the main switch is changed from the closed state to the open state. When the power supply from the external power source is interrupted, the detection circuit and the AC interruption detection means detect this, and the second control means supplies the electric power from the rechargeable battery to the cooling means until the end of a predetermined time.

  Therefore, the present invention removes the abnormally high temperature of the electronic equipment due to residual heat and prevents the equipment casing, parts, consumables, etc. from being damaged or deteriorated. Have. First, since wasteful heat energy generated by the operation of the electronic device is used as cooling power when the external power supply is shut down, the rechargeable battery does not need to be charged from the external power supply and the power consumption of the electronic device itself Can be saved. Second, after the main switch is switched from the closed state to the open state, the cooling means is supplied from the rechargeable battery even if the power supply from the external power source is cut off during the cooling operation by receiving the power supply from the external power source. Since the cooling operation is continued upon receiving the power supply, the remaining heat can be reliably cooled. Thirdly, when charging a rechargeable battery, it is possible to obtain a large amount of large power for a relatively long period of time at a high temperature and sufficiently charge it, and operate for a long time using a powerful cooling means. It is possible to reliably eliminate the adverse effects of residual heat.

  An embodiment as the best mode for carrying out the present invention will be described below in detail with reference to the drawings. FIG. 1 is a block diagram showing an electronic apparatus in an embodiment of the present invention. FIG. 2 is an explanatory diagram showing a specific arrangement state of the thermoelectric elements in FIG. FIG. 3 is a time chart showing the operation when the main switch is opened in the state where the AC power is normally supplied in FIG. FIG. 4 is a time chart showing the operation when the supply of AC power is cut off while the electronic device is operating in FIG. FIG. 5 is a flowchart showing the operation of the arithmetic processing circuit in FIG. FIG. 6 is a time chart showing an operation when the supply of AC power is cut off within a predetermined time after the main switch is opened in a state where the external power is normally supplied in FIG.

  In FIG. 1, for example, an electronic device 10 that is an electronic copying machine includes an operating unit 11 that is an image forming apparatus, a power supply circuit 12 that receives power supply from an AC power source that is an external power source, a main switch 13 of an operation unit, An operation switch circuit 14 interposed between the circuit 12 and the operation unit 11 and controlled by a main switch (main SW) 13, a fan 15 for cooling heat generated in the operation unit 11, and a power supply circuit 12 A first switch circuit (first SW circuit) 16 that is interposed between the fan 15 and controlled by the main switch 13 is provided. When the main switch 13 is closed while the power supply circuit 12 is supplied with power from the AC power supply, the operation switch circuit 14 is closed and the operation unit 11 is operated. At the same time, the first switch circuit 16 is closed and the fan 15 is activated, and a first loop R1 including the power supply circuit 12, the first switch circuit 16, and the fan 15 is formed. Yes.

  Furthermore, the electronic device 10 detects that the main switch 13 has been switched from the closed state to the open state and sends a detection signal S1, and counts a predetermined time using the detection signal S1 of the detection circuit 17 as a trigger. And a second switch circuit 19 that is interposed between the power supply circuit 12 and the fan 15 and is closed only while the timer circuit 18 is counting. A second loop R2 including a power supply circuit 12, a second switch circuit (second SW circuit) 19, and a fan 15 is formed.

  Furthermore, the electronic device 10 is charged with a thermoelectric element 20 arranged to receive heat generated in the operating unit 11 and electric power generated by converting the thermal energy received by the thermoelectric element 20 from the operating unit 11. The rechargeable battery 21, the AC interruption detection circuit 22 that sends out a detection signal S 2 that detects that the supply of AC power in the power supply circuit 12 is cut off, and the detection signal S 2 of the AC interruption detection circuit 22 and detection of the detection circuit 17. The arithmetic processing circuit 23 that receives the signal S1 and the count output of the timer circuit 18 as input, and a third circuit that is controlled to open and close depending on the presence or absence of the output signal S3 of the arithmetic processing circuit 23 and is inserted between the rechargeable battery 21 and the fan 15 Switch circuit (third SW circuit) 24.

  When the detection output S2 is input under the condition that the detection signal S1 is not input, the arithmetic processing circuit 23 performs a processing operation for outputting the output signal S3 for a predetermined time. When the detection signal S1 is input within a predetermined time after the detection signal S1 is input, the arithmetic processing circuit 23 counts the remaining time until the end of the predetermined time of the timer circuit 18 and outputs the output signal S3 for a predetermined time. The processing operation is performed until the end. The third switch circuit 24 is closed by the output signal S3. By closing the third switch circuit 24, a third loop R3 including the rechargeable battery 21, the third switch circuit 24, and the fan 15 is formed. Here, the arithmetic processing circuit 23, the third switch circuit 24, etc. are cut off from the power supply from the power supply circuit 12, but are switched to the power supply from the rechargeable battery 21 by sending out the output signal S3. .

  A specific arrangement state of the thermoelectric element 20 is shown in FIG. 2, but the thermoelectric element 20 is arranged in the fixing unit 111 of the operating unit 11. The fixing unit 111 includes a heating roller 112 serving as a heat generation source and a pressure roller 113, and fixes the sheet 115 conveyed by the conveyance unit 114 by heating and pressing. Then, the heating roller 112 and the pressure roller 113 are surrounded by a plurality of thermoelectric elements 20, and one surface of these thermoelectric elements 20 is arranged toward the heating roller 112 side. By arranging in this way, the other surface of the thermoelectric element 20 faces the low temperature part 116. The thermoelectric element 20 has a temperature difference between one surface and the other surface, generates a thermoelectromotive force by the Seebeck effect, and charges the rechargeable battery 21.

Next, the operation of the electronic device 10 having the above-described configuration will be described with reference to FIGS. FIG. 3 shows a state in which the main switch 13 is opened and closed while the AC power is normally supplied. First, as shown in FIG. 3 (3A), the main switch 13 is closed at time T1 in FIG. 3 (3B) in a state where the AC power is normally supplied. When the main switch 13 is closed, the operation switch circuit 14 is closed, and the operation unit 11 operates as shown in FIG. 3 (3C). At the same time, the first switch circuit 16 is closed by closing the main switch 13 to form a first loop R1 as shown in FIG. 3 (3D), and power is supplied to the fan 15.

  The fan 15 operates by power supply as shown in FIG. The cooling operation by the fan 15 forcibly cools a large amount of heat generated from the heating roll 112 of the fixing unit 111 for image formation, removes adverse effects on various parts, consumables, etc. Maintain proper operation. At the same time, the thermoelectric element 20 receives the heat generated by the heating roller 112 and charges the rechargeable battery 21 with a thermoelectromotive force obtained by converting the heat energy into electric energy.

Next, when the work of the electronic device 10 is finished, the main switch 13 is opened as shown at time T2 in FIG. 3 (3B). The operation switch circuit 14 is opened by opening the main switch 13, and the operation of the operation unit 11 is stopped as shown in FIG. 3 (3C). At the same time, the first switch circuit 16 is also opened, and the loop R1 is not formed at the time T2 as shown in FIG. 3 (3D). Therefore, the power supply to the fan 15 by the loop R1 is stopped. However, since the temperature is excessively high due to residual heat, it is necessary to operate and cool the fan 15 for a while.

  Therefore, as shown in FIG. 3 (3F), it is detected that the main switch 13 has been switched from the closed state to the open state, and a detection signal S1 is sent as a trigger signal. ), The second switch circuit 19 is closed to form the second loop R2 until the time T3 after the predetermined time elapses after the timer circuit 18 starts counting. Power is supplied from the power supply circuit 12 to the fan 15 by forming the second loop R2. Therefore, at time T2, the fan 15 automatically switches the power supply from the first loop R1 to the power supply by the second loop R2.

  By this switching, the fan 15 is automatically and continuously operated after the time T2. At time T3, the output signal S3 disappears and the second switch circuit 19 is opened. By opening the second switch circuit 19, the second loop R2 is not formed and the operation of the fan 15 is stopped. That is, when the operation of the operation unit 11 is stopped by the opening of the main switch 13, the fan 15 receives power from the power supply circuit 12 for a predetermined time and performs a cooling operation to automatically remove the remaining heat in the electronic device 10. Cooling.

  Next, the operation of the case where the supply of AC power, which is an external power supply, is interrupted while the electronic device 10 is in operation will be described with reference to FIGS. First, as shown in FIG. 4 (4A), the main switch 13 is closed and the operation switch circuit 14 is closed at time T1 in FIG. When the operation switch circuit 14 is closed, the operation unit 11 operates as shown in FIG. 4 (4C). At the same time, the first switch circuit 16 is closed by closing the main switch 13 to form a first loop R1 as shown in FIG. 4 (4D), and power is supplied to the fan 15.

  As shown in FIG. 4 (4E), the fan 15 operates by supplying power and performs a cooling operation. At the same time, the thermoelectric element 20 receives heat generated by the heating roller 112 and charges the rechargeable battery 21 by electromotive force. At time T4 when the main switch 13 is closed and the operating unit 11 is in operation, if the AC power supply is interrupted due to a power failure, the outlet being unintentionally disconnected, etc., the supply from the power supply circuit 12 is lost. The operation of the operation unit 11 is stopped, and power supply to the fan 15 by the loop R1 is stopped.

  However, the AC interruption detection circuit 22 detects that the supply of AC power has been interrupted, and sends the detection signal S2 and inputs it to the arithmetic processing circuit 23 as shown in step 101 of FIG. 4 (4F) and FIG. . The arithmetic processing circuit 23 determines whether or not the detection signal S1 is already input in a state where the detection signal S2 is input. When the detection signal S1 is not obtained, the supply of AC power is cut off when the main switch 13 is in a closed state, that is, in a state in which the first switch circuit 16 is closed as shown in step 102 of FIG. It is determined that Further, in the arithmetic processing circuit 23, based on this determination, the internal timer starts counting for a predetermined time as shown in step 103 of FIG. 4 (4G) and FIG.

  Then, during the counting period, the output signal S3 is sent to close the third switch circuit 24. By closing the third switch circuit 24, a third loop R3 is formed, and the power supply to the fan 15 is switched from the second loop R2 to the third loop R3. At the same time, power is supplied from the rechargeable battery to the arithmetic processing circuit 23, the third switch circuit 24, and the like. Therefore, the fan 15 is continuously operated by supplying power from the rechargeable battery 21 as shown in Step 104 of FIG. 4 (4E) and FIG.

  The arithmetic processing circuit 23 detects the elapse of a predetermined time at time T5 as indicated by step 105 in FIG. By this detection, the arithmetic processing circuit 23 stops sending the output signal S3 as shown in FIG. 4 (4G). By stopping the output signal S3, the third switch circuit 24 is opened and the third loop R3 is not formed in step 106 of FIG. As shown in the next step 107 and FIG. 4 (4E), the power supply to the fan 15 is stopped. That is, the operation of the fan 15 is stopped after the time T5. In this way, when the power supply from the AC power supply is cut off without the opening operation of the main switch 13 being performed, the fan 15 is automatically charged by the thermoelectric element 20 until then for a predetermined time. The power supply from the battery 21 is received to perform a cooling operation, and the remaining heat in the electronic device 10 is cooled.

  In addition, when the main switch 13 is opened by operation and power is automatically supplied to the fan 15 from the power supply circuit 12, and the power supply from the AC power supply is cut off during the cooling operation by the fan 15 normally. Will be described with reference to FIGS. First, as shown in FIG. 6 (6A), the main switch 13 is closed and the operation switch circuit 14 is closed at time T1 in FIG. By closing the operation switch circuit 14, the operation unit 11 operates as shown in FIG. 6 (6C). At the same time, the second switch circuit 16 is closed by closing the main switch 13 to form the first loop R1 as shown in FIG. 6 (6D), and power is supplied to the fan 15. As shown in FIG. 6 (6E), the fan 15 operates by supplying power and performs a cooling operation. At the same time, the thermoelectric element 20 receives heat generated by the heating roller 112 and charges the rechargeable battery 21 by thermoelectromotive force.

Next, when the work of the electronic device 10 is finished, the main switch 13 is opened as shown at time T6 in FIG. 6 (6B). The operation switch circuit 14 is opened by opening the main switch 13, and the operation of the operation unit 11 is stopped as shown in FIG. 6 (6C). At the same time, the first switch circuit 16 is also opened, and the loop R1 is not formed at time T6 as shown in FIG. 6 (6D). For this reason, the power supply to the fan 15 by the loop R1 is stopped. However, since the temperature becomes abnormally high due to residual heat, it is necessary to operate the fan 15 for cooling for a while.

  Therefore, as shown in FIG. 6 (6F), it is detected that the main switch 13 is switched from the closed state to the open state, and a detection signal S1 as a trigger signal is sent out. ), The timer circuit 18 starts counting, and the second switch circuit 19 is closed to form the second loop R2. Power is supplied from the power supply circuit 12 to the fan 15 by forming the second loop R2. Therefore, at time T6, the power supply from the first loop R1 to the fan 15 is automatically switched to the power supply by the second loop R2. By this switching, the fan 15 continues to operate after time T7.

  However, at time T7 in FIG. 6 (6G), if power supply from the AC power supply is interrupted during cooling of the remaining heat, power supply from the power supply circuit 12 to the fan 15 by the second loop R2 is stopped. However, the AC interruption detection circuit 22 detects that the supply of AC power has been interrupted, and sends the detection signal S2 and inputs it to the arithmetic processing circuit 23 as shown in step 101 of FIG. 6 (6F) and FIG. . The arithmetic processing circuit 23 determines in step 102 in FIG. 5 that the main switch 13 is not in a closed state, that is, is in a condition in which it is opened by a normal operation. Then, in step 108 of FIG. 5, it is determined whether or not the timer output of the timer circuit 18 is supplied and within a predetermined period. If it is determined in step 108 that it is within the predetermined period, as shown in the next step 109 and FIG. 6 (6I), the internal counter of the arithmetic processing circuit 23 continuously counts the remaining time from time T7. The output signal S3 is sent out.

  The third switch circuit 24 is closed by sending the output signal S3. By closing the third switch circuit 24, a third loop R3 is formed, and the power supply to the fan 15 is switched from the second loop R2 to the third loop R3. At the same time, power is supplied from the rechargeable battery to the arithmetic processing circuit 23, the third switch circuit 24, and the like. In the next step 110, whether or not the remaining time has passed is determined. When the remaining time elapses and a predetermined time T8 is reached as shown in FIG. 6 (6I), transmission of the output signal S3 is stopped. When the output signal S3 is stopped, the third switch circuit 24 is opened as shown in step 111, the loop R3 is not formed, and the operation of the fan 15 is stopped. In this way, when the power supply from the AC power supply is cut off while the main switch 13 is closed and the cooling operation is automatically performed, the fan 15 is cooled by receiving the power supply from the rechargeable battery 21. The operation is continued and the remaining heat in the electronic device 10 is cooled.

  As described above, in the embodiment of the present invention, power is supplied from the AC power source, which is an external power source, via the main switch 13, and the operating unit 11 is operated by the supplied power. The generated heat is cooled by the fan 15 which is a cooling means operated by the electric power, and is generated during the operation of the operating unit 11 in the electronic device 10 which operates the fan 15 for a predetermined time after the main switch 13 is opened. Thermal energy is converted into electrical energy by the thermoelectric element 20 which is an energy conversion means. The thermoelectromotive force obtained by this conversion is charged in the rechargeable battery 21.

  Then, after the main switch 13 is opened and the operation is stopped, the fan is continuously operated for a predetermined time to cool the remaining heat, but when the power supply from the external power source is cut off for some reason, the AC interruption detection The means detects this, and power is supplied from the rechargeable battery to the cooling means by the control means. Therefore, since the cooling means can be operated for a predetermined time by the power charged in the rechargeable battery during operation, firstly, wasteful thermal energy generated by the operation of the electronic device is removed when the external power source is shut off. Since it is used for cooling power, the rechargeable battery does not need to be charged from an external power source, and the power consumption of the electronic device itself can be reduced. Secondly, when charging a rechargeable battery, it is possible to obtain a large amount of large power for a relatively long period of time at a high temperature and to sufficiently charge it, and it operates for a long time using a powerful cooling means. It is possible to reliably eliminate the adverse effects of residual heat.

  In addition, when the power supply from the external power supply is cut off with the main switch 13 closed, the AC power supply cut-off detection circuit 22 serving as a detection means detects this and forms a first control means. Power is supplied from the rechargeable battery to the fan 15 by the processing circuit 23 and the third switch circuit 24. Further, when the power supply from the external power supply is cut off during the cooling operation after the main switch 13 is switched from the closed state to the open state, the AC power supply cut-off detection circuit 22 detects this and performs the second control. Electric power is supplied from the rechargeable battery 21 to the fan 15 until the end of a predetermined time by the timer circuit 18, the arithmetic processing circuit 23, the third switch circuit 24, and the like forming means.

  Therefore, the fan 15 removes the electronic device 10 from becoming abnormally hot due to residual heat. Even if the external power supply is shut off during the removal of the remaining heat, the fan 15 receives power supply from the rechargeable battery 21 and in any case rotates to cool until the end of the predetermined time. In addition, since the rechargeable battery 21 is charged by a thermoelectromotive force using useless heat energy generated during operation of the electronic device 10, the electronic device 10 itself saves power. Further, the rechargeable battery 21 can cool the remaining heat powerfully by using a sufficiently large capacity as required.

  In the above-described embodiments of the present invention, the image forming apparatus is applied as the electronic apparatus 10, but the present invention is not limited thereto, and is also applied to an electronic apparatus having a high-temperature heat source such as a projector or a liquid crystal display. Of course you can.

It is a block diagram which shows the electronic device in the Example of this invention. It is explanatory drawing which shows the specific arrangement | positioning state of the thermoelectric element in FIG. 2 is a time chart showing an operation when a main switch is opened in a state where AC power is normally supplied in FIG. 1. 2 is a time chart illustrating an operation when the supply of AC power is interrupted while the electronic device is operating in FIG. 1. It is a flowchart which shows operation | movement of the arithmetic processing circuit in FIG. 2 is a time chart showing an operation when the supply of AC power is cut off within a predetermined time after the main switch is opened in a state where external power is normally supplied in FIG.

Explanation of symbols

10 Electronic Device 11 Actuator 12 Power Supply Circuit 13 Main Switch (Main SW)
14 operation switch (SW) circuit 15 fan 16 first switch (SW) circuit 17 detection circuit 18 timer circuit 19 second switch (SW) circuit 20 thermoelectric element 21 rechargeable battery 22 AC interruption detection circuit 23 arithmetic processing circuit 24 third switch (SW) circuit 111 fixing unit 112 heating roller 113 pressure roller 114 transport unit 115 sheet 116 low temperature part

Claims (2)

An electric power supply is received from an external power source through a main switch, and an operation unit that operates by the supplied electric power and a cooling unit are provided, and heat generated from the operation unit is cooled by the cooling unit, and the main switch is In an electronic device that operates the cooling means for a predetermined time after opening,
Energy conversion means for converting thermal energy generated during operation of the operating portion into electrical energy;
A rechargeable battery for charging the power obtained by the energy conversion means;
AC interruption detection means for detecting that the power supply from the external power supply is cut off and sending a detection signal;
First control means for operating the cooling means by supplying electric power from the rechargeable battery to the cooling means for the predetermined time when a detection signal is sent by the AC interruption detection means;
A detection circuit for detecting an open / closed state of the main switch;
With
The AC cutoff detection means detects that the power supply from the external power source is shut off in the closed state of the main switch, and sends the detection signal.
The electronic device according to claim 1, wherein when the detection signal is sent, the first control unit supplies electric power from the rechargeable battery to the cooling unit for the predetermined time to operate the cooling unit . The electronic device is
A detection circuit for detecting an open / closed state of the main switch and a second control means;
The AC interruption detection means detects that the power supply from the external power source is cut off during the cooling operation of the cooling means after the main switch is switched from the closed state to the open state, and outputs the detection signal. Send out,
2. The electronic device according to claim 1, wherein the second control unit supplies power from the rechargeable battery to the cooling unit until the end of the predetermined time to continue the cooling operation.

Images