JP2004282893A - Power supply unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power supply unit, having a constitution for locating the occurrence of anomaly and optimally interrupting power. <P>SOLUTION: The power supply unit is constituted of detection units for various operations, such as electricity leakage and abnormal voltage, current, and temperature provided at various points, such as power circuit and loads. If an anomaly monitoring unit decides there is an anomaly based on a detection signal from an operation detecting unit, an anomaly decision processing sequence is executed, where in this anomaly decision processing sequence, the reset switch in the power input stage of the power supply unit and the switch element provided in the input stage or output stage of each power circuit are selectively on/off-controlled, to perform processing for locating the occurrence of the anomaly. With this constitution, the point of occurrence of an anomaly can be identified and informed with accuracy, and further, the optimum power interruption processing, corresponding to the point of occurrence of the anomaly can be performed, and a safe power supply unit of high safety is realized. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a power supply device. In particular, the present invention relates to a power supply device that monitors an operation state of a power supply circuit and has an input cutoff configuration when an abnormality is detected.
[0002]
[Prior art]
2. Description of the Related Art In power supply devices for copiers, printers, and the like, in recent years, demands for improved safety have been increasing year by year. 2. Description of the Related Art A power supply device is conventionally provided with a protection circuit against an abnormal operation that leads to dangers such as smoke and ignition and electric shock. The protection circuit is generally configured to detect various abnormalities, perform an operation stop process of the power supply device, or cut off an input from an AC power supply as a commercial power supply with a fuse or a relay.
[0003]
Further, in various image processing apparatuses such as a copying machine, a printer, a facsimile, and a scanner, which consume a particularly large amount of electric power, there is an increasing demand for a leakage prevention measure for preventing electric shock. In many cases, a leakage breaker is attached to equipment in which equipment such as an image processing apparatus is installed in order to prevent leakage. However, shutting off the power supply of various information processing devices at the same time by a breaker is not preferable because serious data loss may occur in an environment where computer networking is rapidly progressing. Therefore, there is an increasing demand for a configuration in which a dedicated earth leakage breaker is mounted on each device.
[0004]
On the other hand, in order to perform power management for energy saving, an increasing number of devices are equipped with a plurality of power supply devices and a system that efficiently supplies only necessary power. For example, in an image forming apparatus such as a copying machine, a facsimile machine, and a printer, most of the energized time is in a standby state, and reducing power consumption in the standby state has been a major issue from the viewpoint of energy saving. .
[0005]
As a power supply configuration of the image forming apparatus with reduced power consumption, a load required during standby, for example, a first power supply for supplying power to a controller for controlling the image forming apparatus, and a motor and the like required for image forming processing A configuration in which a second power supply for supplying power to a load composed of various drive systems is individually set, that is, a configuration in which a power supply for a controller and a power supply for a mechanism that executes an image forming process are separately set. Proposed.
[0006]
In such an image forming apparatus having a plurality of power supplies, when a user requests a print instruction, power is supplied from both the first power supply and the second power supply to a load required for image forming processing. However, when there is no print instruction from the user, the power supply from the second power supply to the load (image forming process execution mechanism) is cut off for the purpose of reducing power consumption during standby, and only the first power supply device for the controller is provided. Is supplied as a standby power supply, and processing according to a user instruction can be performed.
[0007]
Incidentally, as a configuration for interrupting the power supply from the second power supply to the load, the operation of the switching element driven by the first power supply is stopped, and the switch means such as a relay or an FET is driven by the first power supply. There has been proposed a configuration in which the input is interrupted. Further, various measures have been taken to improve the efficiency of the standby power supply for the purpose of reducing power consumption during standby.
[0008]
With reference to FIG. 7, a description will be given of a power supply shutoff configuration of a conventional general image forming apparatus including a standby power supply circuit, a normal operation power supply, and an alternating current (AC) load such as a fixing device.
[0009]
The input terminal 500 is connected to a standby power supply circuit a 511 via an earth leakage breaker 501 and a power supply switch 502, and is connected to an operation power supply circuit c 512 via a switch element 503 such as a relay and a switch element 504, respectively. Connected to an AC load via circuit 513.
[0010]
The power supply circuit a 511 supplies, for example, the DC voltage Vout 1 to a control circuit of a device such as the controller 520. The power supply circuit c512 outputs the DC voltage Vout2 and supplies power to a drive system device and the like. When the power switch 502 is turned on, AC power is supplied to each power circuit via the earth leakage breaker, and operation starts.
[0011]
The DC voltage Vout1 output from the power supply circuit a511 is supplied to the controller 520 that controls the device, and the controller starts operating. The controller 520 outputs a signal in accordance with the operation of the device. One of the switches is a switch element 503 for turning on / off the input power to the power supply circuit b 512 and an AC power adjustment circuit 513 for supplying power to an AC load. There is a control signal output to the switch element 504 for turning on / off the input power to the switch.
[0012]
The controller 520 connects and disconnects inputs for the purpose of ensuring safety and saving energy. For example, during standby, the power supply input of only the standby power supply circuit (power supply circuit a 511) is connected to save energy, and the input to the other power supply circuits is cut off. Further, various abnormal states are monitored by the abnormality detecting unit 521, and for example, when the fixing device, which is an AC load, has an abnormal temperature rise, the switch element 504 is turned off to cut off the input to the AC load, and Stop the operation of. At the same time, the abnormality of the device is displayed and the information is stored and used as reference information at the time of repair.
[0013]
However, in recent years, devices such as copiers and printers have become more complicated with the advancement of functions, and it is difficult to specify a sufficient abnormality or a failure occurrence location only by recording the conventional abnormality information. There are cases. In an apparatus having a complicated configuration, it is becoming difficult for not only a user but also a service person to find a fault location in a short time. When it is difficult to identify a failed part, there is a case where it is unavoidable to replace the large part set including the normal part and the failed part.
[0014]
In the conventional power supply device configuration, the power loss of the power supply device itself has been reduced due to the use of various power-saving elements, but the power consumption of the safety circuit and the power of the The loss ratio is increasing.
[0015]
In recent years, various functions have been added to safety circuits in power supply devices of image processing apparatuses such as printers and copiers in order to monitor the safety of devices, and power consumption tends to increase accordingly. Under such circumstances, it has become an issue to secure a monitoring circuit for achieving various safety standards and a control circuit such as power cutoff without increasing power consumption.
[0016]
Furthermore, in a power supply device that receives a commercial AC power supply and has a dual power supply configuration for the controller and the image processing unit, as described above, the power supply circuit for normal operation is connected to the commercial AC power supply via a switch, and Although the switch is turned on / off by the output ON / OFF signal to supply / interrupt the AC power, if any abnormality occurs in the power supply circuit for normal operation and the power supply circuit cannot operate normally, There is a danger that AC power will continue to be input to the power supply circuit.
[0017]
In addition, if the power supply is cut off by the controller based on some kind of abnormality detection and the user manually operates the switch to forcibly connect the AC power supply, abnormalities such as overvoltage of the AC power supply and abnormalities inside the power supply circuit will occur. In spite of the occurrence of AC power, AC power is input, and as a result, electric stress is applied to a specific part of the power supply circuit, and there is a possibility that smoke or ignition may occur due to a failure.
[0018]
As a countermeasure, it is conceivable to use elements and components with a necessary and sufficient margin for all possible failures in the power supply unit, but in this case, a circuit with a margin for the rated load capacity Due to the configuration, there is a problem that the size of the power supply device increases, the weight increases, and the cost increases.
[0019]
There is also a configuration in which a safety measure is taken by using a switch with a reset function in the AC input stage.However, a switch with a reset function is generally operated by a plunger or the like. At the time, there was a danger that it would not be possible in the event of a highly urgent abnormality such as overcurrent or heat generation.
[0020]
Furthermore, in the conventional configuration, in many cases, the power supply to all the power supply circuits is stopped to maintain the safety by performing a simultaneous cutoff process of each switch element when an abnormality occurs. If this is done, there is a problem that the power is shut down while the location of the abnormality is insufficiently specified. If the power is shut down while the location of the abnormality is insufficient, the operator must perform an inspection to identify the location of the abnormality.In this case, the power is supplied to each circuit and load individually to perform the inspection. It is necessary to do. As a result, there is a problem that it takes time and cost to specify the failure location.
[0021]
[Problems to be solved by the invention]
As described above, with the enhancement of functions of copiers, printers, and other devices, it is difficult to identify the location of an abnormality or a failure by only recording the conventional abnormality information. Difficult to find in a short time. As a result, for example, it is necessary to replace a large part set including a normal part and a failed part at the time of repair, which causes an economic loss. In addition, if the failure location is not sufficiently specified, the possibility that the failure or abnormality will occur again increases. In this case, there is a problem that the user cannot use the device.
[0022]
Further, it is said that the demand for energy saving for the copier / printer is only increasing, and the standby power in the copier / printer should be further reduced. However, in actual equipment, the current situation is that a large amount of power is consumed in the earth leakage breaker of the power supply unit and other monitoring circuits for maintaining safety, so that the earth leakage without sacrificing necessary functions such as safety. It is essential to reduce the loss of a power supply including a breaker.
[0023]
In addition, if the device configuration uses a combination of components dedicated to each component, such as an earth leakage breaker and a power conversion device, it is necessary to configure a control voltage power generation circuit in each of the earth leakage breaker and the power conversion device. In terms of cost, waste is occurring.
[0024]
Further, as described above, there is a problem of processing time and cost in an inspection for specifying an abnormal portion after power is turned off for ensuring safety.
[0025]
The present invention has been made in order to address such a problem, and realizes improvement of safety and energy saving performance, and automatically executes a process of identifying an abnormal portion when an abnormality occurs, thereby enabling an abnormality after a power shutdown. An object of the present invention is to provide a power supply device capable of omitting or simplifying a specific process at a location.
[0026]
[Means for Solving the Problems]
According to a first aspect of the present invention, there is provided a power supply device including a plurality of power supply circuits each of which supplies power to a different load, wherein a reset switch that switches between supplying and stopping power to the power supply device and the plurality of power supplies are provided. A plurality of switch elements for switching supply and stop of power to individual power circuits provided corresponding to the respective circuits, and a plurality of operation detection units for detecting abnormalities installed at a plurality of positions of the power supply device An abnormality monitoring unit that performs abnormality determination processing based on a detection signal from the operation detection unit, a reset switch driving unit that drives the reset switch based on a control signal from the abnormality monitoring unit, and the abnormality monitoring unit A switch control circuit that selectively controls the plurality of switch elements based on a control signal that specifies the switch elements from The normal monitoring unit executes an abnormality determination processing sequence based on an abnormality determination based on a detection signal from the operation detection unit, and selectively controls the reset switch and the plurality of switch elements in the abnormality determination processing sequence to detect an abnormality. There is provided a power supply device for executing a process for specifying an occurrence location.
[0027]
According to this configuration, when an abnormality occurs, the abnormality monitoring unit executes the abnormality determination processing sequence based on the abnormality determination based on the detection signal from the operation detection unit, and selectively resets the reset switch and the plurality of switch elements. Since the ON / OFF control is executed to execute the process of identifying the location of the abnormality, the location of the abnormality can be identified without executing the process of detecting the location of the abnormality by the user or the operator. An abnormality notification can be performed.
[0028]
Further, in one embodiment of the power supply device of the present invention, the plurality of switch elements include a switch element provided on an input side of each of the plurality of power supply circuits, and the abnormality monitoring unit is configured to receive a signal from the operation detection unit. In the abnormality determination processing sequence executed based on the detection signal, a switch element configured on the input side of each of the plurality of power supply circuits is selectively controlled to provide a power supply circuit related to abnormality occurrence and a power supply not related to abnormality occurrence. It is characterized by executing a process of determining a circuit.
[0029]
According to this configuration, when an abnormality occurs, the abnormality determination processing sequence is executed by the selective ON / OFF control of the switch element provided in the power input stage corresponding to the power supply circuit. It is possible to determine the circuit.
[0030]
Further, in one embodiment of the power supply device of the present invention, the plurality of switch elements are provided on an input side of each of the plurality of power supply circuits, and are provided on an output side of each of the plurality of power supply circuits. A switch element, wherein the abnormality monitoring unit selects a switch element configured on an input side and an output side of each of the plurality of power supply circuits in an abnormality determination processing sequence executed based on a detection signal from the operation detection unit. And performing a process of determining whether the location where the abnormality has occurred is in the power supply circuit or a power supply load from the power supply circuit.
[0031]
According to this configuration, when an abnormality occurs, the abnormality determination processing sequence is executed by the selective ON / OFF control of the switch elements configured in the power supply input stage and the output stage of each of the plurality of power supply circuits. It is possible to determine whether the power supply is in the power supply circuit or the power supply load from the power supply circuit.
[0032]
Further, in one embodiment of the power supply device of the present invention, the abnormality monitoring unit, in the abnormality determination processing sequence, the control signal for shutting off the power supply to the identified abnormality occurrence location, the reset switch drive unit and the It is configured to output to at least one of the switch control circuits and execute power supply cutoff processing for the identified abnormality occurrence location.
[0033]
According to this configuration, in the abnormality determination processing sequence executed when an abnormality occurs, each switch is controlled so as to shut off power supply to the identified abnormality occurrence location. High security is maintained.
[0034]
Further, in one embodiment of the power supply device of the present invention, the abnormality monitoring unit outputs, to the controller as the load, abnormality state information including abnormality occurrence location information identified in the abnormality determination processing sequence. Is characterized by executing information output processing based on abnormal state information.
[0035]
According to this configuration, in the abnormality determination processing sequence executed when an abnormality occurs, the abnormal state information including the identified abnormality occurrence location information is output to the controller, and the controller performs the output processing of the abnormal state information on a display or the like. Thus, the user or the operator can immediately and accurately obtain the abnormality information.
[0036]
Further, in one embodiment of the power supply device of the present invention, the plurality of power supply circuits include a normal operation power supply circuit as a main power supply circuit and a standby power supply circuit as a sub power supply circuit, and the standby power supply circuit Is configured to perform power supply to a controller as the load that executes control during a normal operation stop, and to supply power to the plurality of operation detection units, an abnormality monitoring unit, a reset switch driving unit, and a switch control circuit. It is characterized by being.
[0037]
According to this configuration, it is not necessary to separately provide a power supply unit that supplies power to the operation detection unit, the abnormality monitoring unit, the reset switch driving unit, and the switch control circuit, thereby realizing cost reduction and energy saving.
[0038]
Furthermore, in one embodiment of the power supply device of the present invention, each of the plurality of power supply circuits executes power supply to a connection load, and includes a plurality of operation detection units, an abnormality monitoring unit, a reset switch driving unit, and a switch. It is characterized in that it is configured to supply power to the control circuit.
[0039]
According to this configuration, it is not necessary to separately provide a power supply unit that supplies power to the operation detection unit, the abnormality monitoring unit, the reset switch driving unit, and the switch control circuit, thereby realizing cost reduction and energy saving.
[0040]
Further, in one embodiment of the power supply device of the present invention, the operation detection unit is configured to include at least one of a leakage detection unit, a voltage detection unit, and a current detection unit.
[0041]
According to this configuration, it is possible to reliably determine abnormality detection based on leakage detection, voltage detection, current detection, and the like, and a power supply device with improved safety is realized.
[0042]
Further, in one embodiment of the power supply device of the present invention, the operation detection unit includes a voltage detection unit and a current detection unit, and the voltage detection unit and the current detection unit are configured to output power from the plurality of power supply circuits and the power supply circuit. Is set in accordance with at least one of the loads supplied.
[0043]
According to this configuration, abnormality detection based on voltage detection, current detection, or the like can be determined for each power supply circuit, and individual power supply circuits can be handled.
[0044]
Further, in one embodiment of the power supply device of the present invention, the operation detecting unit may be configured to include any one of a temperature detecting element, an odor detecting element, a sound detecting element, a smoke detecting element, and a time change detecting element. Features.
[0045]
According to this configuration, an optimum abnormality detection process and safety measures can be performed according to the configuration of each power supply circuit and load.
[0046]
Further, in one embodiment of the power supply device of the present invention, the reset switch is configured to be provided in a power input unit for the power supply device.
[0047]
According to this configuration, it is possible to shut off the input to the power supply device from the beginning when an abnormality occurs, and more secure power shutoff is realized.
[0048]
Further, in one embodiment of the power supply device of the present invention, the plurality of switch elements are constituted by semiconductor elements capable of high-speed response based on an input signal from the switch control circuit.
[0049]
According to this configuration, it is possible to quickly stop the power supply for each power supply circuit, and to immediately stop the power supply to the abnormal part from the abnormality detection.
[0050]
Further, in one embodiment of the power supply device of the present invention, the plurality of switch elements for switching between supply and stop of power to the individual power supply circuits are operated by a signal from the switch control circuit and connected to the power supply device. It is also configured to operate in response to a signal from the specified controller.
[0051]
According to this configuration, the processing of the monitoring program on the controller side is also executed, and more robust monitoring and safety measures can be performed.
[0052]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, the power supply device of the present invention will be described in detail with reference to the drawings.
[0053]
[Example of power supply unit configuration]
FIG. 1 is a block diagram illustrating a configuration of a power supply device according to an embodiment of the present invention. The power supply device according to the present embodiment is built in an image forming apparatus such as a copying machine and a printer.
[0054]
The input terminal 101 of the image forming apparatus is connected to an AC power supply. The AC power supply includes a plurality of power supply circuits configured in the power supply device 110, that is, a power supply circuit b112 which is a power supply circuit for normal operation as a main power supply circuit, a power supply circuit a111 which is a standby power supply circuit as a sub power supply circuit, and The power is supplied to a power supply circuit c113 that is a power supply circuit for loads such as a fixing device, and power is supplied to various loads via these power supply circuits.
[0055]
The power supply device shown in FIG. 1 has a configuration in which a plurality of power supply devices are mounted in order to perform power management for energy saving. The power supply circuit a (standby power supply) 111 is a sub power supply circuit that supplies power to the controller 103 and the like. The power supply circuit b (power supply for normal operation) 112 is a main power supply circuit that supplies power to an image processing unit that executes an image forming process. Further, the power supply device 110 has a power supply circuit c113 having a function as an AC power adjustment circuit for supplying power to the fixing device and the like.
[0056]
Power is supplied to each load (not shown) via each of these power supply circuits. A switch (SW5) 151 as a semiconductor element composed of a relay, an FET, or the like is connected to an output portion of the power supply circuit a (standby power supply) 111. When the switch (SW5) 151 is turned on, a control system load 161 such as a controller is turned on. Is supplied with power.
[0057]
A switch (SW6) 152 as a semiconductor element composed of a relay, an FET, and the like is also connected to an output portion of the power supply circuit b (power supply for normal operation) 112, and a drive system such as a motor when the switch (SW6) 152 is turned on. Power is supplied to the load 162.
[0058]
For example, when the user requests a print instruction, the first power supply, that is, the power supply circuit a (standby power supply) 111, the second power supply, that is, the power supply circuit b (normal operation power supply) 112, and the power supply circuit c 113 When power is supplied to a load required for image forming processing and there is no instruction from the user, a second power supply (power supply circuit b (power supply for normal operation) 112) is supplied from the second power supply to the load for the purpose of reducing power consumption during standby. The power supply and power supply from the power supply circuit c113 to the load are cut off, power is supplied only to the first power supply (power supply circuit a (standby power supply) 111), and power is supplied only to the control system load 161 such as a controller. .
[0059]
The power supply cut-off process for the loads of the power supply circuit b (power supply for normal operation) 112 and the power supply circuit c 113 is performed by the controller 103 supplied with power from the first power supply (power supply circuit a (standby power supply) 111). This is executed by a process of turning off the switching elements 115 and 116 composed of switching means such as a relay and an FET based on the signal.
[0060]
According to the power supply device of the present invention, the operation detection unit 120 detects various operation states and abnormal states, the abnormality monitoring unit 132 inputs monitoring information from the operation detection unit 120, and outputs a reset switch driving circuit based on the input information. The process of shutting off the AC power by inputting the output from the switch 131 to the reset switch (SW1) 102, and inputting the monitoring information from the operation detecting unit 120 to the abnormality monitoring unit 132 and turning on / off the switch based on the input information. The output from the OFF circuit (switch control circuit) 133 is supplied to switch elements (SW2 to SW4) 114 to 116 provided in the power input stage of each power supply circuit, and further, to the switch elements (SW2 to SW4) provided in the power output stage of each power supply circuit. SW5, SW6) 151 and 152 to execute a process of cutting off the power input stage of each power supply circuit or the power output stage of each power supply circuit. To.
[0061]
Although the sequence of the cutoff process of each switch will be described later, the configuration of the present invention has a configuration in which the abnormality determination process sequence of performing the cutoff process of each switch is performed while executing the process of specifying the location where the abnormality has occurred. Details of these processes will be described later.
[0062]
As shown in the drawing, the operation detection unit 120 includes a leakage detection unit 121, a voltage detection unit 123, a current detection unit 122, and an abnormality detection unit 124. These detection units, at least the voltage detection unit 123, and the current detection A plurality of units 122 and abnormality detection units 124 are individually set corresponding to a plurality of power supply circuits 111, 112, 113 or a load to which power is supplied from the power supply circuits.
[0063]
The abnormality monitoring unit 132 determines an abnormality occurrence site based on an input signal from the operation detection unit 120 and, based on the determined abnormality occurrence site, the reset switch (SW1) 102 or a plurality of switch elements (SW2 to SW5). A control signal for selectively operating any one of the switches 114, 115, 116, 151, and 152 is output to the reset switch driving circuit 131 or the switch ON / OFF circuit 133. The abnormality detection unit 124 includes a temperature detection element, an odor detection element, a sound detection element, a smoke detection element, a time change detection element that detects a time change state of the element, and the like. Attached to a certain site.
[0064]
Power for the operation detection unit 120, the abnormality monitoring unit 132, the reset switch drive circuit 131, and the switch ON / OFF circuit 133 is supplied from the DC output unit of the power supply circuit a (standby power supply) 111.
[0065]
Further, the configuration of the present embodiment is not limited to the DC output section of the power supply circuit a (standby power supply) 111, the DC output section of the power supply circuit b (normal operation power supply) 112, and the AC output section of the power supply circuit c113. The configuration is such that power can be supplied to the operation detection unit 120, the abnormality monitoring unit 132, the reset switch drive circuit 131, and the switch ON / OFF circuit 133 via the rectifying diodes 141, 142, and 143.
[0066]
Therefore, even if the power supply circuit a (standby power supply) 111 fails, the operation detection unit 120 and the abnormality monitoring unit 132 are based on the DC output of the power supply circuit b (normal operation power supply) 112 or the AC output of the power supply circuit c113. , The reset switch driving circuit 131 and the switch ON / OFF circuit 133 can be operated, and the reliability can be improved and the redundancy can be improved.
[0067]
In a conventional power supply device, for example, a configuration in which power is always supplied directly from an input voltage to a leakage detection unit is generally used. However, in this configuration, a DC power supply circuit a (standby power supply) 111 Since power is supplied from the output unit, etc., it is possible to simplify the configuration and greatly reduce power loss without having an independent power supply configuration for the operation detection and abnormality monitoring unit etc. It becomes.
[0068]
Next, the internal configuration of the power supply device 110 shown in FIG. 1 will be described. As shown in the figure, the operation detection unit 120 includes an electric leakage detection unit 121, a current detection unit 122, a voltage detection unit 123, and an abnormality detection unit 124 that detects an abnormality such as temperature detection. Hereinafter, each detection unit will be described.
[0069]
The leakage detecting unit 121 is a circuit that detects whether or not a leakage current that may cause an electric shock is generated in the primary circuit. A current difference between an incoming current of the AC power supply supplied to the power supply circuit and a return current (for example, a leakage current caused by a person touching a live part becomes a current difference) is converted to a zero-phase current transformer (ZCT). ), And further amplified by an amplifier (AMP) in the abnormality monitoring unit, and when a certain criterion is exceeded, it is determined that there is abnormal leakage.
[0070]
The leakage detection signal is input to the abnormality monitoring unit 132, and the abnormality monitoring unit 132 outputs a control signal to the reset switch driving circuit 131, and the reset switch driving circuit 131 controls (ON / OFF) the reset switch (SW1) 102. ) Then, if necessary, turn off and cut off the input of the AC power supply.
[0071]
By turning off the switch elements 114, 115, 116, 151, and 152 at the input stage or output stage of each power supply circuit, it is possible to increase the quick-stop performance more than simply turning off the reset switch 102, thereby improving safety. Can be. Since the reset switch (SW1) 102 is configured to cut off the connection by, for example, the operation of the plunger, the reset switch 102 actually operates after the reset switch driving circuit 131 receives the output signal from the abnormality monitoring unit 132. Although it takes time until the input is cut off, switch elements (SW2) 114, switch element (SW3) 115, switch element (SW4) 116, switch element (SW5) 151, and switches at the input and output stages of each power supply circuit are provided. The element (SW6) 152 is composed of switching means such as a relay and an FET. After the switch ON / OFF circuit 133 receives the output signal from the abnormality monitoring unit 132, each of the switching elements 114, 115, 116, 151 , 152 is short, and each power supply circuit is immediately turned on after an abnormality is detected. It can be shut off input power or the output.
[0072]
The voltage detection unit 123 detects an input voltage to the power supply circuit, and determines that an overvoltage has occurred when the input voltage exceeds a predetermined reference value. The abnormality monitoring unit 132 outputs a control signal to the reset switch driving circuit 131, The reset switch drive circuit 131 controls the reset switch (SW1) 102 to turn it off as necessary, thereby cutting off the input of the AC power supply.
[0073]
The interruption process of each of these switches is executed with an abnormality determination process according to a certain sequence. These processes will be described later.
[0074]
By turning off the switch element at the input stage of each power supply circuit as well, it is possible to increase the quick-acting property as compared with simply turning off the reset switch, as in the case of the leakage cutoff.
[0075]
Note that the voltage detection unit 123 is provided in each part where the voltage may increase when the power supply circuit is abnormal. For example, by providing the power supply circuit a (standby power supply) 111, the power supply circuit b (normal operation power supply) 112, or the power supply circuit c113 at each output unit, the output abnormality of each power supply circuit is individually determined, and the abnormality is determined. One of the switch elements 114, 115, 116, 151, 152 provided at the input or output of a certain power supply circuit is turned off, so that the AC power supply or output to each power supply circuit can be selectively cut off. .
[0076]
The current detection unit 122 detects a current of a circuit whose current may increase when an abnormality occurs, and the abnormality detection unit 124 detects, for example, the temperature of an element whose temperature increases when the power supply circuit is abnormal, and outputs a detection signal. The detection signal is input to the input abnormality monitoring unit 132.
[0077]
When an abnormality detection signal is input to the abnormality monitoring unit 132, the abnormality monitoring unit 132 outputs a control signal to the reset switch drive circuit 131, and the reset switch drive circuit 131 controls the reset switch (SW1) 102 Turn off if necessary, and cut off the input of the AC power supply. Alternatively, the abnormality monitoring unit 132 outputs a control signal specifying the switch element to be controlled to the switch ON / OFF circuit 133, and the switch ON / OFF circuit 133 specifies the ON / OFF from the abnormality monitoring unit 132. A plurality of switch elements (SW2 to SW4) 114, 115, and 116 of each power supply circuit input stage are selectively operated (OFF or ON) based on a control signal, and power supply to each power supply circuit is cut off as necessary. I do.
[0078]
Further, the abnormality monitoring unit 132 outputs a control signal specifying the switch element to be controlled to the switch ON / OFF circuit 133, and the switch ON / OFF circuit 133 outputs the switch element (SW5) provided at the output stage of each power supply circuit. , SW6) 151 and 152 are selectively operated (OFF or ON), and the output of the power supply circuit a (standby power supply) 111 and the power supply circuit b (normal operation power supply) 112 to the load is interrupted or switched as necessary. Connecting.
[0079]
The process of shutting off each of these switches is executed with an abnormality determination process according to a certain sequence. These processes will be described later.
[0080]
Note that the current detection unit 122 and the abnormality detection unit 124 are also provided in each part where an abnormality such as a current value abnormality or a temperature rise may occur, similarly to the voltage detection unit 123 described above. For example, by providing the power supply circuit a (standby power supply) 111, the power supply circuit b (normal operation power supply) 112, and the power supply circuit c at each output unit, the abnormality of each power supply circuit is individually determined, and the abnormal power supply The switch elements 114, 115, and 116 or the output-stage switch elements 151 and 152 provided at the input part of the circuit are selected and turned off, and each power supply circuit or output can be selectively cut off.
[0081]
If the abnormality monitoring unit 132 determines that an abnormality has occurred, the abnormality monitoring unit 132 outputs an abnormality alarm to the controller 103. That is, abnormality information including abnormality occurrence part information determined by the abnormality monitoring unit 132 is output to the controller 103. The controller 103 outputs a message indicating the occurrence of an abnormal state to the display 104 based on the input information. In addition, the controller 103 may output a drive signal for each switch based on the abnormality alarm input, and execute ON / OFF control of each switch.
[0082]
It is also possible to output a drive signal for each switch and stop the power supply to each power supply circuit based on the safety monitoring program of the controller 103 itself.
[0083]
Whether the reset switch drive circuit 131 is driven to shut off the power to the power supply device 110 entirely or the switch ON / OFF circuit 133 is driven to shut off the switch elements 114, 115, 116, 151, and 152. Can be selectively executed, and which one to operate is determined by the abnormality monitoring unit 132 in accordance with a predetermined sequence based on the content of the detected abnormality and the location of the abnormality, and control based on the determination is performed. . An example of a specific processing sequence will be described later.
[0084]
In addition, the abnormality detection unit 124 performs not only the above-described temperature detection, but also an odor detection circuit that detects an abnormal odor due to semiconductor damage or an abnormal temperature of a fixing device, and a sound that detects a plosive sound generated when a semiconductor or the like is damaged. The detection circuit includes a detection circuit, a smoke detection circuit for detecting smoke generated by heat generation of an electric component or the like due to a failure, and the like, and each abnormality detection element is installed at a portion where each abnormality may occur. In addition, in order to shut off the input as an abnormality when the device reaches the end of its life, the abnormality monitoring unit may determine the abnormality by detecting various characteristics that increase with use time. For example, the temperature detection value of a component (such as an electrolytic capacitor) in which the temperature rise speed of the component increases with the life thereof is stored, and if the rise speed increases, it is determined that the component is abnormal, and the reset switch 102 or the switch element 114, 115, 116, 151 and 152 may be operated.
[0085]
With the configuration shown in FIG. 1, power supply to a power supply circuit in which various abnormalities have occurred can be continuously stopped. According to this configuration, the power supply can be reliably stopped when an abnormality occurs in the power supply circuit.Therefore, the power supply circuit does not have a circuit configuration corresponding to a load capacity exceeding the rated load capacity, and thus can withstand a steady load. The cost can be reduced simply by selecting the optimal elements and components. Further, not only the reset switch 102 operated by the plunger, but also the input of each power supply circuit is cut off by turning off the switch elements 114, 115, 116, 151, and 152 at the input stage of each power supply circuit including switch means such as a relay and an FET. With this configuration, it is possible to shorten the time from the occurrence of an abnormality until the power is cut off. In addition, the power supply circuit a (standby power supply) 111 or the power supply circuit b (normal operation) can be selectively used depending on the location of the abnormality. AC power supply to the power supply circuit 112) or the power supply circuit c113, or the output of each power supply circuit.
[0086]
If necessary, a timer circuit is incorporated in the abnormality monitoring unit 132, and the value indicated by the abnormality signal sent from each of the leakage detection unit 121, the voltage detection unit 123, the current detection unit 122, and the abnormality detection unit 124 becomes the normal value. The switch that is continuously deviating is measured, and when the measured period exceeds a predetermined period, it is determined that the circuit is abnormal, the abnormal circuit is determined, and the switch connected to the abnormal circuit is determined. One of the elements 114, 115, 116, 151 and 152 is operated (OFF) by the switch ON / OFF circuit 133 to cut off the power supply to the abnormal circuit, or to operate the reset switch drive circuit 131 to reset the switch. A configuration may be adopted in which the input is cut off by turning off 102. According to this configuration, it is possible to prevent erroneous detection of a power supply abnormality due to a transient state that occurs when the power supply device starts up or the like.
[0087]
According to this configuration, abnormality occurs in each of the loads connected to the power supply circuit a (standby power supply) 111 or the power supply circuit b (normal operation power supply) 112 or the power supply circuit c113 such as the controller 103 and a drive circuit (not shown). Even in the case of occurrence, by arranging the detection elements of the operation detection unit 120 respectively, it is possible to easily detect an abnormality at each position. The power supply to the circuit can be cut off, and higher safety is ensured.
[0088]
[Circuit configuration example]
FIG. 2 is a diagram specifically illustrating the circuit configuration of the power supply device according to the above-described embodiment. The power supply circuit a310 includes an input filter circuit 311 for removing high-frequency components, a primary rectification / smoothing circuit 312 for performing rectification / smoothing of an input signal, a transformer 313, and a control for outputting a control signal for controlling a transformer output, for example, a pulse width signal. The circuit includes a circuit 314, a switching element 315 for executing a switching process on the primary side of the transformer 313, and a secondary rectifying / smoothing circuit 316 for rectifying and smoothing the output signal on the secondary side of the transformer. A control system load 381 such as a controller is connected to the subsequent stage of the secondary rectifying / smoothing circuit 316 via a switch element (SW5) 375.
[0089]
The power supply circuit b320 has the same configuration as the power supply circuit a310, and a drive system load 382 such as a motor is connected to an output stage of the power supply circuit b320 via a switch element (SW6) 376.
[0090]
The switch element (SW5) 375 and the switch element (SW6) 376 are semiconductors such as relays and FETs, similarly to the switch elements (SW1 to SW3) 372, 373, and 374 provided in front of the power supply circuits 310, 320, and 330. It is a switch, and ON / OFF control is performed by a control signal from a switch ON / OFF circuit 356 and a control signal from a controller (not shown).
[0091]
The reset switch (SW1) 371 is provided at the subsequent stage of the input terminal 301, that is, at the input stage of the power supply device, and ON / OFF control is executed by a control signal from the reset switch driving circuit 351.
[0092]
The earth leakage detecting unit 352 has a zero-phase current transformer (ZCT) 303 installed before or after the reset switch (SW1) 371, and the earth leakage detecting unit 352 detects a difference between the forward and return AC input currents. When the difference becomes equal to or higher than a certain level, the abnormality monitoring unit 355 determines that there is a leakage. If it is determined that a short circuit has occurred, a signal is sent from the abnormality monitoring unit 355 to the reset switch driving circuit 351 to control ON / OFF of the reset switch (SW1) 371, and the reset switch driving circuit 351 is driven to entirely reduce power to the power supply device. Whether to shut off or drive the switch ON / OFF circuit 356 to shut off the switch elements (SW2 to SW6) 372 to 376 can be selectively executed. Which one to operate depends on the content of the detected abnormality and The abnormality monitoring unit 355 makes a determination in accordance with a predetermined sequence based on the location where the abnormality has occurred, and control based on the determination is performed. Details of this processing will be described later.
[0093]
The current detector 353 detects the input current with the current transformer 357, inputs the detected value to the abnormality monitor 353, and determines whether the abnormality monitor 353 has an abnormal current. If it is determined that an abnormality has occurred, a signal is sent from the abnormality monitoring unit 353 to the reset switch drive circuit 351 to turn on the switch elements (SW2 to SW6) 372 to 376 provided in the input and output stages of each of the power supply circuits 310, 320, and 330. By executing the / OFF control, an abnormality determination is executed, and any switch is selectively turned off as necessary to cut off the input.
[0094]
As described above, the instantaneous abnormal current is captured by the current transformer 357 and the input is cut off. At the same time, by installing the circuit breaker 304 on the AC input line having a different polarity, an effective (thermal) overcurrent is prevented. , The circuit breaker 304 can be operated to cut off the input. These two current cutoff methods can cope with various current abnormalities.
[0095]
The voltage detection unit 354 detects the smoothed voltage of the primary rectification and smoothing circuit 312 that rectifies and smoothes the AC input voltage to the power supply circuit a310, for example, and the abnormality monitoring unit 355 determines whether the voltage is abnormal overvoltage. In the case of an abnormality, a signal is sent from the abnormality monitoring unit 355 to the reset switch driving circuit 351 to control ON / OFF of the reset switch (SW1) 371, and the reset switch driving circuit 351, the leakage detection unit 352, the current detection unit 353, the voltage detection The operating voltages of the unit 354, the abnormality monitoring unit 355, and the switch ON / OFF circuit 356 are supplied from the primary side of the transformer 313 in the power supply circuit a310. For this, a DC voltage generated as an operating voltage of the control circuit 314 on the primary side of the transformer 313 can be used. Alternatively, a configuration in which a new DC voltage is generated and supplied using the transformer 313 may be employed. Note that power to these units may be supplied not only from the power supply circuit a310 but also from the power supply circuit b320 and the power supply circuit c330.
[0096]
FIG. 3 is a diagram illustrating a specific circuit configuration example of the abnormality monitoring unit, the reset switch driving circuit, and the reset switch.
[0097]
At the time of leakage detection in the leakage detection unit, the voltage induced in the zero-phase current transformer 303 is input to the operational amplifier (op amp1) 411 via the diode 421 and the resistor 422, and exceeds the threshold set in the operational amplifier (op amp1) 411. Then, the photocoupler 412 is turned on by the output of the operational amplifier (op amp1) 411 to operate the coil 413 of the reset switch (SW1) 371 to cut off the AC input.
[0098]
When an overcurrent is detected in the current detection unit, the voltage induced in the current transformer 357 is input to the operational amplifier (op amp2) 431 via the diode 441 and the resistor 442, and when the voltage exceeds the threshold set in the operational amplifier (op amp2) 431, the operational amplifier When the threshold value of (op amp2) 431 is exceeded, the photocoupler 412 is turned on by the output of the operational amplifier (op amp2) 431 and the coil 413 of the reset switch (SW1) 371 is operated to cut off the AC input.
[0099]
The processing at the time of overvoltage detection in the voltage detection unit is as follows. When the voltage rectified by the temporary rectifying / smoothing circuit 312 inside the power supply circuit a310 is higher than a specified value, the zener diode 451 operates, the photocoupler 452 turns on, and the coil 413 of the reset switch (SW1) 371 operates to input the AC input. Cut off.
[0100]
Although FIG. 3 shows only the operation configuration of the reset switch (SW1) 371, the operation control of switch elements (SW2 to SW6) such as relays and FETs provided at the input and output stages of each power supply circuit is performed. A switch ON / OFF circuit that receives an output signal output by the abnormality monitoring unit based on a signal from each operation detection unit, and controls the switch ON / OFF circuit to output a drive signal for each switch element based on the received signal. It is executed according to the sequence.
[0101]
[Processing sequence]
Next, the operation of the power supply device of the present invention will be described with reference to the flowcharts of FIGS. FIG. 4 is a flowchart showing a processing procedure when executing processing (print processing) based on power supply from the power supply circuit from the start-up of the power supply device of the present invention. FIGS. 5 and 6 are flowcharts showing the procedure of the abnormality determination process. In the following description of the flow, description will be made with reference to the configuration of FIG.
[0102]
First, a processing procedure related to execution of processing from the start-up of the power supply device in FIG. 4 will be described. In step S101, the reset switch (SW1) 102 (see FIG. 1) is turned on. This is handled manually by the user. In step S102, power is supplied to the power supply circuit a (standby power supply) 111. The switch element (SW2) 114 and the switch element (SW5) 151 are set to an ON state in a normal state (default).
[0103]
In step S103, power is supplied from the power supply circuit a111 to the controller 103, which is the control system load 161, and the controller 103 is started. In step S104, a signal is output from the controller 103, and the switch element (SW3) 115 and the switch element (SW6) 152 are turned on. In step S105, the power supply circuit b (power supply for normal operation) 112 and the drive system load 162 are turned on. Electric power is supplied to this.
[0104]
In step S106, a signal is output from the controller 103, and the switch element (SW4) 116 is turned on. In step S107, power is supplied to the power supply circuit c113 which is a power supply circuit to the fixing device and the like.
[0105]
In step S108, it is determined whether or not printing has been started, and power is supplied to each print processing unit via the power supply circuit c113 to perform a printing operation. If it is determined in step S110 that printing has been completed, the process returns to step S108.
[0106]
If printing is not started in step S108, the flow advances to step S111 to determine whether or not to shift to a standby state. The determination process is executed by the controller 103 as a determination process of shifting to the standby state when the non-operation state continues for a predetermined time. When shifting to the standby state, the process proceeds to step S112, in which the switch element (SW4) 116 provided at the preceding stage of the power supply circuit c113 is turned off based on a signal from the controller 103. Stop supply.
[0107]
Further, in step S114, the switch element (SW3) 115 provided in the preceding stage of the power supply circuit b (power supply for normal operation) 112 is turned off, and in step S115, power supply to the power supply circuit b (power supply for normal operation) 112 is performed. Stop. In step S116, the presence / absence of a return signal is determined. If the return signal is present, the process proceeds to step S104, and the switch element (SW3) 115 provided in the preceding stage of the power supply circuit b (power supply for normal operation) 112 is turned on. The following steps S105 and subsequent steps are repeatedly executed. The return signal is a signal generated by the controller inside the controller based on a user input such as a start of printing.
[0108]
Next, with reference to FIGS. 5 and 6, a description will be given of a procedure of an abnormality determination process performed in the power supply device of the present invention. This flow will be described with reference to FIG. 1 similarly to the above-described flow.
[0109]
In step S201, the abnormality monitoring unit 132 determines the presence or absence and the position of the abnormality based on the input from the operation detection unit 120. Note that, as described in the above-described embodiment, the abnormality detection units for overvoltage, overcurrent, temperature rise, etc. are provided in each unit of the power supply device, and the abnormality monitoring unit is based on the input from each abnormality detection unit. To determine where an abnormality has occurred.
[0110]
In step S201, first, it is determined whether or not leakage has occurred. If it is determined that there is no leakage, the process proceeds to step S202. If it is determined that there is a short circuit, the process proceeds to step S301 (FIG. 6). The processing after step S301 will be described later.
[0111]
When it is determined that the current is not in the short-circuit state and the process proceeds to step S202, it is determined in step S202 whether or not the input overvoltage is abnormal. This is determined by the abnormality monitoring unit 132 based on the detection signal of the voltage detection unit of the input unit of the power supply device.
[0112]
If it is determined in step S202 that the input overvoltage is abnormal, the process proceeds to step S221, and the abnormality monitoring unit 132 outputs abnormal state information to the controller 103, that is, information indicating that the input power supply is abnormal. Abnormality information, that is, information indicating that the input power supply is abnormal, is displayed on the display 104 based on the input information.
[0113]
Next, in step S222, the abnormality monitoring unit 132 outputs a control signal to the reset switch driving circuit 131, and the reset switch driving circuit 131 turns off the reset switch (SW1) 102.
[0114]
If it is determined in step S202 that the input overvoltage is not abnormal, the process proceeds to step S203, in which the abnormality monitoring unit 132 performs control to turn off the switch element (SW3) 115 and the switch element (SW4) 116 at the preceding stage of the power supply circuit b112 and the power supply circuit c113. The switch ON / OFF circuit 133 outputs a signal to the switch ON / OFF circuit 133. The switch ON / OFF circuit 133 outputs a switch element (SW3) 115 and a switch element (SW4) preceding the power circuit b112 and the power circuit c113 based on the control signal. 116 is turned off.
[0115]
In step S204, it is determined whether the abnormality continues in this state. This abnormality determination is made based on each detection signal input by the abnormality monitoring unit 132 that receives a detection signal from the operation detection unit 120.
[0116]
If it is determined in step S204 that the abnormality has continued, the process proceeds to step S231. In step S231, the abnormality monitoring unit 132 outputs a control signal for turning off the switch element (SW5) 151 at the output stage of the power supply circuit a111 to the switch ON / OFF circuit 133, and the switch ON / OFF circuit 133 The switch element (SW5) 151 at the output stage of the power supply circuit a111 is turned off based on the signal.
[0117]
In step S232, it is determined whether the abnormality continues in this state. This abnormality determination is made based on each detection signal input by the abnormality monitoring unit 132 that receives a detection signal from the operation detection unit 120.
[0118]
If it is determined that the abnormality has continued, the process proceeds to step S251. In step S251, the abnormality monitoring unit 132 outputs abnormal state information to the controller 103, that is, information indicating that the standby power supply, that is, the power supply circuit a111 is abnormal, and the controller 103 outputs the information to the display 104 based on the input information. Abnormality information, that is, information indicating that the standby power supply is abnormal is displayed.
[0119]
Next, in step S252, the abnormality monitoring unit 132 outputs a control signal for turning off the switch element (SW2) 114 at the input stage of the power supply circuit a111 to the switch ON / OFF circuit 133, and the switch ON / OFF circuit 133 The switch element (SW2) 114 at the input stage of the power supply circuit a111 is turned off based on the control signal.
[0120]
If it is determined in step S232 that the abnormality has not continued, the process proceeds to step S261. In step S261, the abnormality monitoring unit 132 outputs abnormal state information to the controller 103, that is, information indicating that the control system load 161 is abnormal, and the controller 103 displays abnormality information on the display 104 based on the input information. That is, information indicating that the control system load is abnormal is displayed.
[0121]
If it is determined in step S204 that the abnormality has not continued, the process proceeds to step S205. In step S205, the abnormality monitoring unit 132 outputs a control signal for turning on the switch element (SW3) 115 and the switch element (SW6) 152 at the input / output stage of the power supply circuit b112 to the switch ON / OFF circuit 133, The ON / OFF circuit 133 turns on the switch element (SW3) 115 and the switch element (SW6) 152 at the input / output stage of the power supply circuit b112 based on the control signal.
[0122]
In step S206, it is determined whether the abnormality continues in this state. This abnormality determination is made based on each detection signal input by the abnormality monitoring unit 132 that receives a detection signal from the operation detection unit 120.
[0123]
If it is determined in step S206 that the abnormality has continued, the process proceeds to step S207. In step S207, the abnormality monitoring unit 132 outputs a control signal for turning off the switch element (SW6) 152 in the output stage of the power supply circuit b112 to the switch ON / OFF circuit 133, and the switch ON / OFF circuit 133 The switch element (SW6) 152 at the output stage of the power supply circuit b112 is turned off based on the signal.
[0124]
In step S208, it is determined whether the abnormality continues in this state. This abnormality determination is made based on each detection signal input by the abnormality monitoring unit 132 that receives a detection signal from the operation detection unit 120.
[0125]
If it is determined in step S208 that the abnormality has continued, the process proceeds to step S209. In step S209, the abnormality monitoring unit 132 outputs a control signal for turning off the switch element (SW3) 115 at the input stage of the power supply circuit b112 to the switch ON / OFF circuit 133, and the switch ON / OFF circuit 133 The switch element (SW3) 115 at the input stage of the power supply circuit b112 is turned off based on the signal.
[0126]
Next, in step S210, the abnormality monitoring unit 132 outputs abnormality state information to the controller 103, that is, information indicating that the main (main) power supply, that is, the power supply circuit b112, is abnormal. Is displayed on the display 104 on the basis of the information, that is, information indicating that the main (main) power supply is abnormal.
[0127]
If it is determined in step S208 that the abnormality has not continued, the process proceeds to step S271. In step S271, the abnormality monitoring unit 132 outputs abnormal state information to the controller 103, that is, information indicating that the driving system load 162 is abnormal, and the controller 103 displays abnormality information on the display 104 based on the input information. That is, information indicating that the load is a drive system load is displayed.
[0128]
If it is determined in step S206 that the abnormality has not continued, the process proceeds to step S241. In step S241, the abnormality monitoring unit 132 outputs a control signal to turn on the switch element (SW4) 116 at the input stage of the power supply circuit c112 to the switch ON / OFF circuit 133, and the switch ON / OFF circuit 133 The switch element (SW4) 116 at the input stage of the power supply circuit c113 is turned on based on the signal.
[0129]
In step S242, it is determined whether the abnormality continues in this state. This abnormality determination is made based on each detection signal input by the abnormality monitoring unit 132 that receives a detection signal from the operation detection unit 120.
[0130]
If it is determined in step S242 that the abnormality has continued, in step S244, the abnormality monitoring unit 132 notifies the controller 103 of the abnormal state information, that is, the abnormality of the fixing device which is a load of the power supply circuit c. The controller 103 outputs abnormality information, that is, information indicating that the fixing device is abnormal, on the display 104 based on the input information, and the switch element (SW4) 116 of the input stage of the power supply circuit c113 in step S245. Is turned off and the process ends.
[0131]
If it is determined in step S242 that the abnormality has not continued, the process proceeds to step S243. In step S243, as a result of the abnormality determination processing performed by the abnormality monitoring unit 132, an abnormal part is not found, and an abnormality determination error has occurred in the abnormality monitoring unit. That is, it is determined that a malfunction has occurred, and the abnormality monitoring unit 132 outputs abnormal state information to the controller 103, that is, information indicating that the malfunction has occurred, and indicates that the controller 103 has malfunctioned on the display 104 based on the input information. Is displayed.
[0132]
Next, in step S201, a process performed when it is determined that an electric leakage has occurred will be described with reference to the flow of FIG.
[0133]
In step S301, the abnormality monitoring unit 132 outputs, to the switch ON / OFF circuit 133, a control signal for turning off the switch element (SW3) 115 and the switch element (SW4) 116 at the preceding stage of the power supply circuit b112 and the power supply circuit c113. The switch ON / OFF circuit 133 turns off the switch element (SW3) 115 and the switch element (SW4) 116 at the preceding stage of the power supply circuit b112 and the power supply circuit c113 based on the control signal.
[0134]
Next, in step S302, it is determined whether or not the electric leakage continues in this state. This abnormality determination is made based on the leakage detection signal input by the abnormality monitoring unit 132 that receives the detection signal from the operation detection unit 120.
[0135]
If it is determined in step S302 that the leakage has not continued, the process proceeds to step S303. In step S303, the abnormality monitoring unit 132 outputs a control signal for turning on the switch element (SW4) 116 at the input stage of the power supply circuit c113 to the switch ON / OFF circuit 133, and the switch ON / OFF circuit 133 The switch element (SW4) 116 at the input stage of the power supply circuit c113 is turned on based on the signal.
[0136]
In step S304, it is determined whether the abnormality continues in this state. This abnormality determination is made based on each detection signal input by the abnormality monitoring unit 132 that receives a detection signal from the operation detection unit 120.
[0137]
If it is determined that the abnormality continues, the process proceeds to step S321. In step S321, the abnormality monitoring unit 132 outputs abnormal state information to the controller 103, that is, information indicating that the fixing device, which is the load of the power supply circuit c113, is leaked, and the controller 103 performs display based on the input information. Anomaly information 104, that is, information indicating that the fixing device is short-circuited, is displayed at 104.
[0138]
Next, in step S322, the abnormality monitoring unit 132 outputs a control signal for turning off the switch element (SW4) 116 at the input stage of the power supply circuit c113 to the switch ON / OFF circuit 133, and the switch ON / OFF circuit 133 The switch element (SW4) 116 at the input stage of the power supply circuit c113 is turned off based on the control signal.
[0139]
If it is determined in step S304 that the abnormality has not continued, the process proceeds to step S305. In step S305, the abnormality monitoring unit 132 outputs a control signal for turning on the switch element (SW3) 115 at the input stage of the power supply circuit b112 to the switch ON / OFF circuit 133, and the switch ON / OFF circuit 133 The switch element (SW3) 115 at the input stage of the power supply circuit b112 is turned on based on the signal.
[0140]
In step S306, it is determined whether the abnormality continues in this state. This abnormality determination is made based on each detection signal input by the abnormality monitoring unit 132 that receives a detection signal from the operation detection unit 120.
[0141]
If it is determined that the abnormality has continued, the process proceeds to step S307. In step S307, the abnormality monitoring unit 132 outputs abnormal state information to the controller 103, that is, information indicating that the main (main) power supply, that is, the power supply circuit b112 is abnormal, and the controller 103 performs the operation based on the input information. Abnormality information, that is, information indicating a main (main) power supply abnormality is displayed on the display 104.
[0142]
Next, in step S308, the abnormality monitoring unit 132 outputs a control signal for turning off the switch element (SW3) 115 at the input stage of the power supply circuit b112 to the switch ON / OFF circuit 133, and the switch ON / OFF circuit 133 The switch element (SW3) 115 at the input stage of the power supply circuit b112 is turned off based on the control signal.
[0143]
If it is determined in step S306 that the electric leakage has not continued, the process proceeds to step S331. In step S331, as a result of the leakage detection processing executed by the abnormality monitoring unit 132, a leakage point is not found, and an abnormality determination error has occurred in the abnormality monitoring unit. That is, the malfunction monitoring unit 132 determines that the malfunction has occurred, outputs the malfunction status information to the controller 103, that is, information indicating that the malfunction has occurred, and the controller 103 stores the malfunction information based on the input information. Information indicating malfunction is displayed at 104.
[0144]
If it is determined in step S302 that the electric leakage has continued, in step S311, the abnormality monitoring unit 132 outputs abnormal state information to the controller 103, that is, information indicating that electric leakage has occurred. 103 displays abnormality information on the display 104 based on the input information, that is, information indicating occurrence of electric leakage.
[0145]
Further, in step S312, the abnormality monitoring unit 132 outputs a control signal for turning off the reset switch (SW1) 102 of the power supply input stage to the reset switch driving circuit 131, and the reset switch driving circuit 131 outputs the control signal to the control signal. Based on this, the reset switch (SW1) 102 of the power supply input stage is turned off.
[0146]
As described above, according to the abnormality determination processing sequence described with reference to FIGS. 5 and 6, it is determined which part of the plurality of power supply circuits has an abnormality, and based on the determination result, the abnormality occurrence location is determined. Since the power supply is cut off, it is possible to perform a power cut-off process only on a portion that needs to be cut off. Further, by displaying the abnormal state information on the display via the controller, the user or the operator can know the location of the abnormality without executing a new abnormality location detection process, and quickly take a measure such as repair. It is possible to execute.
[0147]
The present invention has been described in detail with reference to the specific embodiments. However, it is obvious that those skilled in the art can modify or substitute the embodiment without departing from the spirit of the present invention. That is, the present invention has been disclosed by way of example, and should not be construed as limiting. In order to determine the gist of the present invention, the claims described at the beginning should be considered.
[0148]
【The invention's effect】
As described above, according to the power supply device of the present invention, various operation detection units for electric leakage, voltage, current abnormality, temperature abnormality, and the like are set in each part such as a power supply circuit and a load, and the abnormality monitoring unit detects the operation. When an abnormality is determined based on a detection signal from the unit, an abnormality determination processing sequence is executed. In this abnormality determination processing sequence, the reset switch of the power input stage of the power supply device and the input switch or the output stage of each power supply circuit are provided. Since the process for selectively performing the ON / OFF control of the switch element and performing the process for specifying the location where the abnormality has occurred is performed, the abnormality occurrence location is not newly performed by the user or the operator, and the abnormality occurrence location is not executed. The location can be specified, and optimal power shutdown and abnormality notification can be performed.
[0149]
Further, according to the configuration of the present invention, since the power to the operation detection unit, the abnormality monitoring unit, and the like is output from the existing power supply circuit, it is not necessary to provide a unique power supply configuration to the abnormality monitoring unit. Energy saving is realized.
[0150]
Further, according to the configuration of the present invention, in the abnormality determination processing sequence, the reset switch of the power input stage of the power supply device and the selective ON / OFF control of the switch element provided at the input or output stage of each power supply circuit are executed. Power supply path corresponding to the abnormal site can be reliably shut off, and the power supply with high safety can be shut off. An apparatus is realized.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration example of a power supply device of the present invention.
FIG. 2 is a diagram showing a specific circuit configuration example in a configuration example of the power supply device of the present invention.
FIG. 3 is a diagram showing a specific circuit configuration example in a configuration example of the power supply device of the present invention.
FIG. 4 is a flowchart illustrating a startup and operation processing sequence in the power supply device of the present invention.
FIG. 5 is a flowchart illustrating an abnormality determination processing sequence in the power supply device of the present invention.
FIG. 6 is a flowchart illustrating an abnormality determination processing sequence in the power supply device of the present invention.
FIG. 7 is a diagram illustrating a configuration example of a conventional power supply device.
[Explanation of symbols]
101 input terminal, 102 reset switch,
103 controller, 104 display
110 power supply unit, 111 power supply circuit a (standby power supply),
112 power supply circuit b (power supply for normal operation), 113 power supply circuit c
114, 115, 116 switch element
120 operation detector, 121 earth leakage detector
122 current detector, 123 voltage detector
124 abnormality detection unit, 131 reset switch drive circuit
132 Error monitoring unit, 133 Switch ON / OFF circuit
141, 142, 143 Diode
151, 152 switch element
161 control system load, 162 drive system load
301 input terminal, 303 zero-phase current transformer
304 circuit breaker
310 power supply circuit, 311 input filter
312 Primary rectification smoothing circuit, 313 transformer
314 control circuit, 315 switching element
316 secondary rectification smoothing circuit, 320 power supply circuit b
330 power supply circuit c, 351 reset switch drive circuit
352 leakage detector, 353 current detector, 354 voltage detector
355 Abnormality detector, 356 switch ON / OFF circuit
357 Current transformer, 371 Reset switch
372 to 376 switch element, 381 control system load
382 drive system load, 411 operational amplifier, 412 photocoupler
421 diode, 422 resistor
431 operational amplifier, 441 diode
442 resistor, 451 Zener diode
452 photo coupler,
501 input terminal, 502 power switch
503, 504 switch element, 511 power supply circuit a
512 power supply circuit c, 513 AC power adjustment circuit
520 controller, 521 error monitor

Claims (13)

In a power supply device having a plurality of power supply circuits each supplying power to a different load,
A reset switch for switching between supply and stop of power to the power supply device,
A plurality of switch elements for switching between supply and stop of power to individual power circuits provided corresponding to each of the plurality of power circuits,
A plurality of operation detection units that detect abnormalities installed at a plurality of positions of the power supply device,
An abnormality monitoring unit that performs abnormality determination processing based on a detection signal from the operation detection unit,
A reset switch driving unit that drives the reset switch based on a control signal from the abnormality monitoring unit,
A switch control circuit that selectively controls the plurality of switch elements based on a control signal specifying the switch element from the abnormality monitoring unit,
The abnormality monitoring unit executes an abnormality determination processing sequence based on an abnormality determination based on a detection signal from the operation detection unit, and selectively controls the reset switch and the plurality of switch elements in the abnormality determination processing sequence. A power supply device for executing a process for specifying a location where an abnormality has occurred. The plurality of switch elements include switch elements provided on the input side of each of the plurality of power supply circuits,
The abnormality monitoring unit selectively controls a switch element configured on an input side of each of the plurality of power supply circuits in an abnormality determination processing sequence executed based on a detection signal from the operation detection unit, and generates an abnormality. The power supply device according to claim 1, wherein a process of determining a power supply circuit related to the power supply circuit and a power supply circuit not related to the occurrence of the abnormality is performed. The plurality of switch elements include a switch element provided on an input side of each of the plurality of power supply circuits, and a switch element provided on an output side of each of the plurality of power supply circuits,
The abnormality monitoring unit, in an abnormality determination processing sequence executed based on a detection signal from the operation detection unit, selectively controls a switch element configured on an input side and an output side of each of the plurality of power supply circuits, The power supply device according to claim 1, wherein a process of determining whether the abnormality occurrence location is in the power supply circuit or a power supply load from the power supply circuit is performed. The abnormality monitoring unit, in the abnormality determination processing sequence, outputs a control signal for shutting off power supply to the identified abnormality occurrence location to at least one of the reset switch driving unit and the switch control circuit, and is identified. The power supply device according to claim 1, wherein the power supply device is configured to execute a power supply cutoff process for a failure occurrence location. A configuration in which the abnormality monitoring unit outputs, to the controller as the load, abnormality state information including the abnormality occurrence location information identified in the abnormality determination processing sequence, and the controller performs information output processing based on the abnormality state information. The power supply device according to claim 1, wherein The plurality of power supply circuits include a normal operation power supply circuit as a main power supply circuit, and a standby power supply circuit as a sub power supply circuit,
The standby power supply circuit performs power supply to a controller as the load that executes control during a normal operation stop, and supplies power to the plurality of operation detection units, an abnormality monitoring unit, a reset switch driving unit, and a switch control circuit. The power supply device according to claim 1, wherein the power supply device is configured to supply power. Each of the plurality of power supply circuits is configured to perform power supply to a connection load and to supply power to the plurality of operation detection units, an abnormality monitoring unit, a reset switch driving unit, and a switch control circuit. The power supply device according to claim 1. The power supply device according to claim 1, wherein the operation detection unit includes at least one of a leakage detection unit, a voltage detection unit, and a current detection unit. The operation detection unit includes a voltage detection unit and a current detection unit, and the voltage detection unit and the current detection unit correspond to at least one of the plurality of power supply circuits and a load supplied with power from the power supply circuit. The power supply device according to claim 1, wherein the power supply device has a set configuration. 2. The power supply device according to claim 1, wherein the operation detection unit includes any one of a temperature detection element, an odor detection element, a sound detection element, a smoke detection element, and a time change detection element. 3. The power supply device according to claim 1, wherein the reset switch has a configuration provided in a power input unit for the power supply device. 2. The power supply device according to claim 1, wherein the plurality of switch elements are constituted by semiconductor elements capable of high-speed response based on an input signal from the switch control circuit. 3. The plurality of switch elements for switching between supply and stop of power to the individual power supply circuits operate by signals from the switch control circuit and also operate by signals from a controller connected to a power supply device. The power supply device according to claim 1, wherein:

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