JP2024029473A - electrical equipment - Google Patents

Abstract

To provide electrical equipment that operates using AC electric power as power supply electric power, in which inconveniences due to that DC electric power is included in the power supply electric power is reliably prevented.SOLUTION: According to a multifunctional machine (10) pertaining to the present disclosure, when it is detected by a DC mixture detection circuit 506 that DC electric power is included in the power supply electric power, a DC detection signal Sdc is outputted from the DC mixture detection circuit 506. This DC detection signal Sdc is inputted to a lock mechanism 300. The lock mechanism 300 forcibly turns a main power supply switch 100 off, in response to input of the DC detection signal Sdc. Furthermore, the lock mechanism 300 maintains the state of the main power supply switch 100 being turned off, in effect locking it. Thus, the main power supply switch 100 is blocked from being inadvertently turned on by manual operation. As a result, inconveniences due to that DC electric power is included in the power supply electric power are reliably prevented.SELECTED DRAWING: Figure 6

Description

The present disclosure relates to electrical equipment, and particularly relates to electrical equipment that operates using alternating current power as power source power.

An example of this type of electrical equipment is an electrophotographic image forming apparatus. In an electrophotographic image forming apparatus, a toner image is formed on an image recording medium such as paper, and heat is applied to the toner image to fix the toner image on the image recording medium. Therefore, a fixing device having a heater is provided. Some fixing devices have a configuration in which AC power as power source power is directly input to a heater (particularly without being converted to DC power). In this configuration, on/off means is provided for turning on/off input of AC power to the heater.

For example, Patent Document 1 discloses a configuration in which a heater of a fixing device (thermal fixing device) is provided with a triac and a relay as on/off means in series. According to this configuration, the heating temperature of the heater is controlled by turning the triac on and off as appropriate. Then, when the temperature of the heater rises abnormally, the relay is turned off, thereby preventing abnormal overheating of the heater.

Japanese Patent Application Publication No. 6-236127

By the way, AC power as power source is generally obtained from a commercial power source, but the power source power may be obtained from a solar power generation system. However, when power source power is obtained from a solar power generation system that employs a transformerless type power conditioner, if the power conditioner breaks down, DC power may appear in the power source power. This is extremely inconvenient for electrical equipment that operates using AC power as power source. For example, in the configuration disclosed in Patent Document 1 mentioned above, the triac is no longer turned off, and as a result, AC power continues to be input to the heater, and there is a risk that the heater may be abnormally overheated. In addition, the contacts of the relay are welded by arc discharge, and the relay is no longer turned off. As a result, abnormal overheating of the heater is not prevented, and electrical equipment including the heater may be damaged.

Therefore, an object of the present disclosure is to provide a novel electrical device that can reliably prevent the inconvenience caused when the power source power includes DC power.

To achieve this objective, the present disclosure provides an electrical device that operates using AC power as power source, and includes a switch, a detection means, a switch-off means, and a blocking means. The switch turns on/off acceptance of input of power source power by manual operation. The detection means detects whether or not the power source power includes DC power. The switch-off means forcibly turns off the switch when the detection means detects that the power source power includes DC power. The blocking means prevents the switch from being manually turned on when the switch is turned off by the switch-off means.

Note that the blocking means may include a first maintaining means. The first maintaining means maintains (fixes) the switch in an off state, thereby preventing the switch from being turned on by manual operation.

Further, in the present disclosure, a cover may further be provided. This cover is provided so as to be able to change between a state of covering the switch and a state of exposing the switch to the outside, and is in a state of covering the switch while the electrical device is in operation. In this case, the blocking means may include second retaining means. The second maintaining means prevents the switch from being manually turned on by maintaining (fixing) the switch covered by the cover.

Furthermore, in the present disclosure, an AC load may be provided.

The AC load referred to here includes, for example, a heater and an on/off means. Among these, the heater receives input of AC power and is heated. The on/off means turns on/off supply of AC power to the heater as appropriate.

The electrical device according to the present disclosure may be an electrophotographic image forming apparatus. This image forming apparatus includes a fixing device that has a heater that is an AC load.

According to the present disclosure, when power source power includes DC power, inconveniences caused by this can be reliably prevented.

FIG. 1 is a perspective view of a multifunction peripheral according to a first embodiment of the present disclosure. FIG. 2 is a front view of the multifunction device according to the first embodiment. FIG. 3 is a block diagram showing the electrical configuration of the multifunction device according to the first embodiment. FIG. 4 is an enlarged view of a portion including the main power switch of the multifunction peripheral according to the first embodiment. FIG. 5 is a further enlarged view of a portion including the main power switch of the multifunction device according to the first embodiment. FIG. 6 is a partial electrical circuit diagram including a main power switch of the multifunction peripheral according to the first embodiment. FIG. 7 is a diagram schematically showing the internal configuration of the main power switch in the first embodiment. FIG. 8 is a diagram schematically showing another state of the internal configuration of the main power switch in the first embodiment. FIG. 9 is a diagram schematically showing still another state of the internal configuration of the main power switch in the first embodiment. FIG. 10 is a diagram schematically showing still another state of the internal configuration of the main power switch in the first embodiment. FIG. 11 is a partial electrical circuit diagram including a main power switch of a multifunction peripheral according to a second embodiment of the present disclosure. FIG. 12 is a diagram schematically showing the internal configuration of the main power switch in the second embodiment. FIG. 13 is a diagram for explaining the locking mechanism in the second embodiment. FIG. 14 is another diagram for explaining the locking mechanism in the second embodiment.・ FIG. 15 is yet another diagram for explaining the locking machine in the second embodiment. FIG. 16 is yet another diagram for explaining the locking mechanism in the second embodiment. FIG. 17 is yet another diagram for explaining the locking mechanism in the second embodiment.

[First example]
A first embodiment of the present invention will be described using a multifunction peripheral (MFP) 10 shown in FIGS. 1 and 2 as an example.

The multifunction peripheral 10 according to the first embodiment is a type of image forming apparatus, and has multiple functions such as a copy function, an image scanner function, a printer function, and a fax function. Note that FIG. 1 is a perspective view of the multifunction device 10 showing the front, top, and left side of the multifunction device 10 installed in a usable state. That is, the vertical direction in FIG. 1 corresponds to the vertical direction of the multifunction device 10. The diagonally lower left in FIG. 1 corresponds to the front of the multifunction device 10, and the diagonally upper right in FIG. 1 corresponds to the rear of the multifunction device 10. Further, the diagonally upper left side in FIG. 1 corresponds to the left side of the multifunction device 10, and the diagonally lower right side in FIG. 1 corresponds to the right side of the multifunction device 10. FIG. 2 is a front view of the multifunction device 10.

An image reading section 12 serving as an image reading means is provided at the top of (the main body of) the multifunction device 10 . The image reading unit 12 is responsible for image reading processing of reading an image of a document (not shown) and outputting two-dimensional read image data corresponding to the image of the document. For this reason, the image reading unit 12 includes a document table (not shown) on which the document is placed. This document table is formed of a transparent member such as glass having a substantially rectangular flat plate shape, and is provided with both main surfaces thereof aligned in the horizontal direction. The upper surface of both main surfaces of the document table is a surface on which the document is placed. Below the document table, there is an image reading unit (not shown) having a light source, a mirror, a lens, a line sensor, etc., and an image reading position (not shown) by the image reading unit is moved along the bottom surface of the document table ( Appropriate elements including a drive mechanism (not shown) for scanning) are provided. That is, with the document placed on the document table, the image reading position of the image reading unit is moved by the drive mechanism, so that the image of the document is read using a so-called fixed reading method. Additionally, an automatic document feeder (ADF) 14 is provided above the document table, which also serves as a document holding cover for holding down the document placed on the document table.

The automatic document feeder 14 is provided so as to be able to transition between a state in which the top surface of the document table (document placement surface) is exposed to the outside (open state) and a state in which the top surface of the document table is covered (closed state). . Therefore, the automatic document feeder 14 is coupled to the main body (casing) of the multifunction device 10 via a suitable fulcrum support member such as a hinge (not shown). Note that in FIGS. 1 and 2, the automatic document feeder 14 is in a closed state. Further, the automatic document feeder 14 performs its original function when it is in the closed state.

That is, the automatic document feeder 14 has a document placement tray 14a. On this document placement tray 14a, a document, more precisely a sheet document, can be placed, and in particular, a plurality of documents can be placed in a stacked manner. Then, the automatic document feeder 14 automatically takes in the documents placed on the document tray 14a one by one into the automatic document feeder 14. The document taken into the automatic document feeder 14 is sent to the upper surface of the document table, and more specifically, to the image reading position by the image reading unit described above. As a result, the image of the document is read in a so-called skimming method. Thereafter, the original is ejected to the original ejection tray 14b of the automatic original feeder 14.

An image forming section 16 as an image forming means is provided below the image reading section 12, with an outwardly opened internal body space 10a interposed therebetween. The image forming section 16 is responsible for image forming processing of forming an image based on appropriate image data such as the above-mentioned read image data on a sheet-like image recording medium (not shown), such as paper. This image forming process is performed using a known electrophotographic method. For this reason, the image forming section 16 includes a photoreceptor drum, a charging device, an exposure device, a developing device, a transfer device, a cleaning device, and a static eliminator (not shown). Additionally, the image forming section 16 includes a fixing device 16a (see FIG. 3), which will be described later. The paper after the image forming process by the image forming section 16, so to speak, the printed matter, is discharged into the internal space 10a, and more precisely, onto a paper discharge tray 18 provided in the internal space 10a. In addition to the paper discharge tray 18 provided in the internal space 10a, an external paper discharge tray 20 is provided on the outside of the multifunction device 10, specifically on the right side. When this external paper discharge tray 20 is set as the paper discharge destination, printed matter is discharged to the external paper discharge tray 20.

A paper feeding section 22 as a paper feeding means is provided below the image forming section 16, in other words, at the bottom of the multifunction device 10. This paper feeding section 22 has one or more, for example, three, paper feeding cassettes 22a, 22a, . . . . Each of the paper feed cassettes 22a, 22a, . . . stores sheets of appropriate sizes, for example, sheets of different sizes. Further, a manual feed tray 22b, which is an auxiliary paper feed tray, is provided at an appropriate position of the multifunction device 10, for example, on the right side of the multifunction device 10. In FIG. 1, the manual feed tray 22b can be seen, and more specifically, the manual feed tray 22b can be seen in a closed state. The manual feed tray 22b can be switched between a closed state and an open state, and can be used when it is in the open state. Then, the paper feed section 22 uses one of the paper feed cassettes 22a, 22a, .

In addition, a generally rectangular plate-shaped operating unit 24 is provided at the top of the multifunction device 10 and at the front of the main body of the multifunction device 10 . The operation unit 24 is coupled to the main body of the multifunction device 10 with one main surface facing outward. One main surface of the operating unit 24 facing outward is an operating surface, and a display 24b with a touch panel 24a is provided on this operating surface. Further, the angle (orientation) of the operation surface of the operation unit 24 with respect to the horizontal direction can be changed within a predetermined range, and in other words, the operation unit 24 is provided so that this can be done.

The display 24b with the touch panel 24a is a component in which a display 24b having a rectangular display surface and a sheet-like touch panel 24a provided so as to overlap the display surface of the display 24b are combined together. be. Among these, the touch panel 24a is an operation receiving means that can receive a touch operation by a user (not shown) using the multifunction peripheral 10, and is, for example, a projected capacitive panel. The display 24b is a display means that displays various screens on a display surface, and is, for example, a liquid crystal display (LCD). Note that the touch panel 24a is not limited to the projected capacitive type, but may be a surface type capacitive type, an electromagnetic induction type, a resistive film type, an infrared type, or other type of panel. Further, the display 24b is not limited to a liquid crystal display, but may be an organic electroluminescence (EL) display or the like.

A user typically stands in front of the multifunction device 10 and uses the multifunction device 10, in particular operating the operating unit 24. In order to improve the operability and visibility of the operation surface of the operation unit 24 by the user at that time, the angle of the operation surface with respect to the horizontal direction can be changed as described above. In addition to the touch panel 24a, the operation unit 24 includes appropriate hardware switches such as push button switches (not shown). In addition to the display 24b, the operation unit 24 also includes appropriate light emitting means such as a light emitting diode (LED) (not shown).

FIG. 3 is a block diagram showing the electrical configuration of the multifunction device 10. As shown in FIG. As shown in FIG. 3, the multifunction device 10 includes an image reading section 12, an automatic document feeder 14, an image forming section 16, a paper feed section 22, and an operation unit 24, as well as a control section 30, an auxiliary storage section 32, and an auxiliary storage section 32. , a communication section 34, and the like. These are connected to each other via a common bus 40. Note that the image reading section 12, automatic document feeder 14, image forming section 16, paper feeding section 22, and operation unit 24 are as described above. In particular, the image forming section 16 includes a fixing device 16a. Further, in FIG. 3, illustrations of elements that are not directly related to the gist of the present invention are omitted.

The control unit 30 is a control means that controls the entire multifunction device 10. For this reason, the control unit 30 includes a computer, such as a CPU 30a, as a control execution means. In addition, the control unit 30 has a main storage unit 30b as a main storage means that can be directly accessed by the CPU 30a. The main storage unit 30b includes a ROM and a RAM (not shown). A control program (firmware) for controlling the operation of the CPU 30a is stored in the ROM. The RAM constitutes a work area and a buffer area when the CPU 30a executes processing based on a control program.

The auxiliary storage section 32 is an auxiliary storage means that stores various data such as the above-mentioned read image data. This auxiliary storage section 32 includes, for example, a hard disk drive (not shown). Further, the auxiliary storage unit 32 may include a rewritable nonvolatile memory such as a flash memory.

The communication unit 34 is a communication means that handles bidirectional communication processing via a LAN line (not shown). The communication unit 34 also handles two-way communication processing via a public switched telephone network (not shown). Note that the communication unit 34 is connected to the LAN line, for example, by wire, but may also be connected to the LAN line wirelessly, for example, by Wi-Fi (registered trademark).

Now, the multifunction device 10 according to the first embodiment operates using AC power as power source. The AC power referred to here can be obtained from, for example, a commercial power source.

A main power switch 100 that turns on/off acceptance of input of AC power as the power supply is provided at an appropriate position of the multifunction device 10, for example, in a position covered by the front cover 50. installed in a location that cannot be seen from the outside. Note that the front cover 50 is provided to cover the image forming section 16, and specifically, it can be placed in a state in which it covers a part of the image forming part 16 (closed state) or in a state in which it exposes a part of the image forming part 16 to the outside ( (opened state).

When the front cover 50 is opened, a portion of the interior of the image forming section 16 is exposed to the outside, as shown in FIG. 4, and a main power switch 100 is provided at an appropriate position, for example, on the left side. Note that the main power switch 100 is further covered by a switch cover 200. The switch cover 200 is provided so as to be able to transition between a state that covers the main power switch 100 (closed state) and a state that exposes the main power switch 100 to the outside (open state). Further, in FIG. 4, a generally circular object 16b on the right side of the main power switch 100 (switch cover 200) is a toner cartridge.

The switch cover 200 is a generally flat rectangular box-like body with one main surface open, and one edge thereof is connected to the housing (front panel) 16c of the image forming unit 16 above the main power switch 100. be done. The switch cover 200 is provided so as to be able to transition between the closed state and the open state as described above, that is, to be rotatable, using the joint portion with the casing 16c of the image forming unit 16 as a fulcrum. Further, when the switch cover 200 is in the closed state, the open main surface side faces the main power switch 100 side, that is, the open main surface side covers the main power switch 100. provided.

As shown in FIG. 5, when the switch cover 200 is opened, the main power switch 100 is exposed to the outside, that is, the main power switch 100 is in a state where it can receive manual operation. The main power switch 100 is, for example, a two-pole single-throw seesaw switch (rocker switch). Further, in the area covered by the switch cover 200 and above the main power switch 100, there is a rectangular flat cover panel 400 for covering (hiding) a lock release operator 304b of the lock mechanism 300, which will be described later. provided. This cover panel 400 is fixed to the casing 16c of the image forming section 16 with an appropriate number of screws 402, 402, for example, two screws.

Then, when the main power switch 100 is turned on, AC power as power source power is input to the multifunction device 10, and the multifunction device 10 becomes operable. Strictly speaking, the multifunction device 10 becomes operational when the main power switch 100 is turned on, the switch cover 200 is closed, and the front cover 50 is further closed. In other words, even if the main power switch 100 is turned on, the multifunction device 10 does not operate when the front cover 50 is open.

As described above, the AC power as the power supply for the multifunction device 10 can be obtained from, for example, a commercial power source, but instead may be obtained from a solar power generation system (not shown). However, when power source power is obtained from a solar power generation system that employs a transformerless type power conditioner, if the power conditioner breaks down, DC power may appear in the power source power. This is extremely inconvenient for the multifunction device 10, which operates using AC power as power source.

In particular, the fixing device 16a has a heater 162 as described later, and AC power as power source power is directly input to the heater 162. Additionally, a triac 164 and a thermostat 166 are provided in series with the heater 162 as on/off means for appropriately turning on/off input of AC power to the heater 162 . If DC power is input to the heater 162, triac 164, and thermostat 166, which are such AC loads, the heater 162 may be abnormally overheated, and the multifunction device 10 including the heater 162 may be damaged. That is, when DC power is input to the triac 164, the triac 164 is no longer turned off. Then, when DC power is input to the thermostat 166, the contacts of the thermostat 166 are welded by arc discharge, and the contacts remain turned on. As a result, DC power continues to be input to the heater 162, causing abnormal overheating of the heater 162, which may cause damage to the multifunction device 10 including the heater 162.

In order to reliably prevent this inconvenience, in the first embodiment, the main power switch 100 is forcibly turned off when the power supply includes DC power. A locking mechanism 300 is provided for maintaining (fixing) the main power switch 100 in an off state, in other words, for preventing the main power switch 100 from being turned on by manual operation.

Specifically, as shown in FIG. 6, the multifunction device 10 has an AC input terminal (receptacle) 500 that is an input section for AC power as power supply. This AC input terminal 500 is connected to a power supply circuit 502 via a main power switch 100, and more specifically to a DC conversion circuit 504. The DC conversion circuit 504 converts AC power input via the main power switch 100 into DC power, and further generates a plurality of DC voltages V1, V2, . . . with various voltage values. These DC voltages V1, V2, . . . are input to each DC load as the power supply voltage of each DC load.

Further, the power supply circuit 502 includes a DC mixture detection circuit 506 , and power is also input to this DC mixture detection circuit 506 via the main power switch 100 . The DC contamination detection circuit 506 detects whether or not the power source power input via the main power switch 100 includes DC power, and when it detects that the power source power includes DC power, it detects the DC power. Outputs signal Sdc.

Although detailed description including illustrations will be omitted, the DC mixing detection circuit 506 includes a current sensor using a Hall element, for example. The current sensor detects the direction and magnitude of a current component (that is, current) of power source power. The DC contamination detection circuit 506 determines, that is, detects, whether or not the power source power includes DC power, based on the detection result by the current sensor. Further, the DC mixing detection circuit 506 operates using a DC voltage Vn of an appropriate voltage value given from the DC conversion circuit 504 as a power supply voltage. The DC detection signal Sdc output from the DC contamination detection circuit 506 is input to the lock mechanism 300, and is input to the solenoid 302, which will be described in detail later.

Additionally, the AC input terminal 500 is connected to the DC circuits of the heater 162, triac 164, and thermostat 166 of the fixing device 16a via the main power switch 100. The heater 162 is a heating means for heating a heating roller (not shown) of the fixing device 16a. AC power as power supply is input to this heater 162 via a triac 164 and a thermostat 166. The triac 164 is turned on/off according to a control signal given from a control circuit (not shown), thereby controlling the heating temperature of the heater 162. The thermostat 166 is turned on when the temperature of the heater 162 is below a predetermined threshold, and is turned off when the temperature of the heater 162 exceeds a predetermined threshold, thereby preventing abnormal overheating of the heater 162. Ru.

Locking mechanism 300 is incorporated into main power switch 100, as shown in FIGS. 7A and 7B. As mentioned above, the main power switch 100 is a two-pole, single-throw seesaw switch. Specifically, for example, the main power switch 100 is coupled to a seesaw-shaped operation button 102, a leaf spring-shaped movable contact piece 104, a support member 106 that supports the movable contact piece 104, an input side fixed contact 108, and an input side fixed contact 108. It has an input side terminal 110 , an output side fixed contact 112 , an output side terminal 114 coupled to the output side fixed contact 112 , and a housing 116 . Note that the operation portion of the operation button 102 is exposed to the outside of the housing 116. Further, one end of each of the input terminal 110 and the output terminal 114 is pulled out to the outside of the housing 116. The movable contact piece 104 is always in contact with the output side fixed contact 112. Furthermore, two movable contact pieces 104, two input side fixed contacts 108, two input side terminals 110, two output side fixed contacts 112, and two output side terminals 114 are provided.

The main power switch 100 having such a configuration is turned on/off by manually operating the operation button 102. For example, FIG. 7A shows a state in which main power switch 100 is turned off. When the main power switch 100 is turned off, the movable contact piece 104 is separated from the input fixed contact 108, that is, the input terminal 110 and the output terminal 114 are not connected. FIG. 7B shows a state in which the main power switch 100 is turned on. When the main power switch 100 is turned on, the movable contact piece 104 is in contact with the input fixed contact 108, that is, the input terminal 110 and the output terminal 114 are connected.

The locking mechanism 300 includes a push-type solenoid 302 and a locking member 304. During normal times when the above-mentioned DC detection signal Sdc is not input, the solenoid 302 is in a state where the plunger 302a is accommodated in the main body of the solenoid 302, as shown in FIGS. 7A and 7B. Further, the plunger 302a is provided with a tension spring 302c that biases the plunger 302a in a direction to accommodate the plunger 302a in the main body of the solenoid 302, as shown by an arrow 302b in each of FIGS. 7A and 7B. Furthermore, when the DC detection signal Sdc is input to the solenoid 302 and the solenoid 302 is driven, that is, the plunger 302a is A protruding portion 302d is provided that engages with a locking portion 304a of a locking member 304, which will be described next, when pushed out from within the main body of the locking member 302.

The lock member 304 is a roughly L-shaped member when viewed from the side of the main power switch 100, and one end thereof is a lock portion 304a, and the other end is a lock release operator. 304b. Then, the lock member 304 is opened in a state in which the lock release operator 304b is directed in the same direction as the direction in which the operation button 102 of the main power switch 100 is exposed from the housing 116 (above each of FIGS. 7A and 7B). 304a is inserted into a side wall of the housing 116 of the main power switch 100 (strictly speaking, an insertion hole (not shown) provided in the side wall of the housing 116). Further, the locking member 304 includes a push spring on the outside of the housing 116 that biases the locking member 304 in the direction toward the inside of the housing 116, as shown by an arrow 304c in each of FIGS. 7A and 7B. 304d is provided. In addition, the tip portion 304e of the lock portion 304a is formed to be inclined toward the inside of the housing 116 as the plunger 302a is pushed out (upward in each of FIGS. 7A and 7B), It is formed in a so-called tapered shape.

That is, as shown in FIG. 7B, when the DC detection signal Sdc is input to the solenoid 302 while the main power switch 100 is in the on state, it is determined that the power source power includes DC power. When detected by the DC contamination detection circuit 506, the solenoid 302 is activated. As a result, as shown by an arrow 302e in FIG. 8, the plunger 302a of the solenoid 302 is pushed out from within the main body of the solenoid 302, and accordingly, the operation button 102 of the main power switch 100 is forcibly turned off. Transition to. On the way, the tip of the protrusion 302d of the plunger 302a comes into contact with the tip 304e of the locking portion 304a of the locking member 304, and as shown by an arrow 304f in FIG. Pushed in a direction that opposes the biasing direction.

When the plunger 302a is further pushed out from within the main body of the solenoid 302, the operation button 102 of the main power switch 100 is completely turned off, as shown in FIG. At the same time, the tip portion of the protruding portion 302d of the plunger 302a passes through the tip portion 304e of the locking portion 304a of the locking member 304. Then, as shown by an arrow 304c in FIG. 9, the locking member 304 moves in the direction toward the inside of the housing 116 due to the biasing force of the push spring 304d. As a result, the protruding portion 302d of the plunger 302a and the locking portion 304a of the locking member 304 engage with each other.

In this way, when the DC mixture detection circuit 506 detects that the power supply includes DC power, the main power switch 100 is forcibly turned off. As a result, input of power from the power source into the multifunction device 10 is stopped. In particular, abnormal overheating of the heater 162 is prevented, and damage to the multifunction device 10 including the heater 162 is prevented.

Furthermore, when the main power switch 100 is turned off, input of the DC detection signal Sdc to the solenoid 302 is stopped. Then, as shown by an arrow 302b in FIG. 9, the plunger 302a attempts to return to the direction in which it is housed within the main body of the solenoid 302 due to the biasing force of the tension spring 302c. However, as described above, since the protruding portion 302d of the plunger 302a and the locking portion 304a of the locking member 304 engage with each other, the main power switch 100 is maintained in an OFF state, and is locked by the locking mechanism 300, so to speak. This prevents the main power switch 100 from being turned on accidentally by manual operation.

That is, according to the first embodiment, when the DC contamination detection circuit 506 detects that the power source power includes DC power, the main power switch 100 is forcibly turned off, and the main power switch 100 is forcibly turned off. The state in which the switch 100 is forcibly turned off is locked by the locking mechanism 300. This reliably prevents inconveniences caused by DC power being included in the power supply.

Note that if the source of source power is switched from a solar power generation system to a commercial power source and the source power no longer includes DC power, the locked state by the locking mechanism 300 is manually released. This manual work is performed by a service person, for example.

To do this, first, as shown in FIG. 10, the cover panel 400 is removed. Then, when the lock release operator 304b of the lock member 304 is operated, the lock member 304 is moved in a direction that opposes the biasing direction of the push spring 304d, as shown by an arrow 304f in FIG. Then, as shown by an arrow 302b in FIG. 10, the plunger 302a returns to the direction in which it is housed within the main body of the solenoid 302 due to the biasing force of the tension spring 302c. Thereby, the locked state by the lock mechanism 300 is released, and the main power switch 100 can be turned on/off by manual operation. Thereafter, the cover panel 400 is attached or returned to its original state.

The main power switch 100 in the first embodiment is an example of a switch according to the present disclosure. The DC mixing detection circuit 506 in the first embodiment is an example of a detection means according to the present disclosure. Further, the solenoid 302 in the first embodiment is an example of a switch-off means according to the present disclosure. Further, the locking mechanism 300 in the first embodiment is an example of a blocking means according to the present disclosure, and more specifically, an example of a first maintaining means according to the present disclosure.

[Second example]
Next, a second example of the present disclosure will be described.

As described above, in the first embodiment, when the DC contamination detection circuit 506 detects that the power source power includes DC power, the main power switch 100 is forcibly turned off, and then, The state in which the main power switch 100 is forcibly turned off is locked by the locking mechanism 300. In contrast, in the second embodiment, when the DC contamination detection circuit 506 detects that the power supply includes DC power, the main power switch 100 is forcibly turned off. , is the same as the first embodiment. In addition, in the second embodiment, the main power switch 100 is not locked in the forcibly turned off state, but the switch cover 200 is in the closed state, which is different from the first embodiment. It is locked by a locking mechanism 600. This prevents the main power switch 100 from being inadvertently turned on by manual operation, and thereby reliably prevents any inconvenience caused by the power source including DC power.

Specifically, as shown in FIG. 11, in the second embodiment, when the DC mixture detection circuit 506 detects that the power source power includes DC power, the main power switch 100 is turned on. An off solenoid 700 for forcibly turning off is provided. A DC detection signal Sdc is inputted to the off solenoid 700 from the DC mixing detection circuit 506. Additionally, a locking mechanism 600 is provided for locking the switch cover 200 in the closed state when the DC contamination detection circuit 506 detects that the power supply includes DC power. A DC detection signal Sdc is input from the DC contamination detection circuit 506 to this locking mechanism 600 as well as to a solenoid 606, which will be described in detail later. Note that the other configurations in the second embodiment are the same as those in the first embodiment, so they are given the same reference numerals as in the first embodiment, and detailed description thereof will be omitted.

The off solenoid 700 is incorporated into the main power switch 100, as shown in FIGS. 12A, 12B, and 12C. Like the solenoid 302 in the first embodiment, the off solenoid 700 is of a push type, and during normal times when the DC detection signal Sdc is not input to it, the plunger 700a is turned off as shown in FIG. 12A. It is housed in the main body of the off solenoid 700. Further, the plunger 700a is provided with a tension spring 700c that biases the plunger 700a in the direction of housing the plunger 700a in the main body of the off solenoid 700, as shown by an arrow 700b in FIG. 12A. Note that the plunger 700a is not provided with a protrusion as in the first embodiment.

That is, as shown in FIG. 12A, when the main power switch 100 is in the on state and the DC detection signal Sdc is input to the off solenoid 700, that is, the power source power includes DC power. When this is detected by the DC contamination detection circuit 506, the off solenoid 700 is activated. As a result, as shown by an arrow 700d in FIG. 12B, the plunger 700a of the off solenoid 700 is pushed out of the main body of the off solenoid 700, and accordingly, the operation button 102 of the main power switch 100 is forcibly pressed. Transition to the state where it is turned off. As a result, the input of power into the multifunction device 10 is stopped, and in particular, abnormal overheating of the heater 162 is prevented, and damage to the multifunction device 10 including the heater 162 is prevented.

However, when the main power switch 100 is turned off, the input of the DC detection signal Sdc to the off solenoid 700 is stopped. Then, as shown by an arrow 700b in FIG. 12C, the plunger 700a is returned to the state housed within the main body of the off solenoid 700 by the biasing force of the tension spring 700c. Therefore, the main power switch 100 is in a state where it can be turned on/off. In order to prevent the main power switch 100 from being turned on and off by manual operation, the second embodiment is provided with a locking mechanism 600 that locks the switch cover 200 in the closed state.

That is, as shown in FIGS. 13A and 13B, the casing 16c of the image forming unit 16 is provided with a concave recess 16d having an appropriate shape and size to match the switch cover 200. The main power switch 100 is installed at (the bottom position of) 16d. Further, a circular insertion hole 16f for inserting a lock rod 602i, which will be described later, is provided at an appropriate position in the side wall 16e of the recessed portion 16d, for example, at an appropriate position on the right side when viewed from the front. Further, at a position corresponding to the insertion hole 16f on the recess 16d side in the side surface 200a of the switch cover 200, a circular cover-side insertion hole 200b similar to the insertion hole 16f, that is, a circular cover-side insertion hole 200b for inserting a lock rod 602i to be described later. is provided. Note that the switch cover 200 including the recess 16d including the insertion hole 16f and the cover-side insertion hole 200b constitutes the lock mechanism 600 together with a lock member 602, a guide member 604, and a solenoid 606, which will be described next.

Referring also to FIG. 14, a lock member 602 is provided on the inner surface of the casing 16c of the image forming unit 16. This locking member 602 is a roughly U-shaped member when viewed from the side facing the inner surface of the casing 16c of the image forming unit 16, and the roughly U-shaped opening is directed upward. In this state, it is provided at an appropriate position on the left side of the recessed portion 16d (main power switch 100). Then, a substantially rectangular parallelepiped-shaped sliding member 602b is placed on a portion of the locking member 602 along the horizontal direction, so to speak, a horizontal portion 602a. A generally rectangular plate-shaped guided portion 602c that protrudes downward is provided on the bottom surface of the sliding member 602b. In addition, the guided portion 602c is inserted into the horizontal portion 602a, and the sliding member 602b including the guided portion 602c is inserted in the direction along the inner surface of the casing 16c of the image forming unit 16, that is, in the left-right direction. , an elongated guide hole 602d for guiding is provided.

Further, of the two vertically extending portions 602e and 602f of the locking member 602, the portion 602e on the far side from the recessed portion 16d is a fixing portion for fixing the push spring 602g. One end of the push spring 602g is fixed to the inner surface of the fixed portion 602e, and the other end is in contact with a surface of the sliding member 602b that faces the inner surface of the fixed portion 602e. That is, the push spring 602g is provided so as to urge the sliding member 602b away from the fixed portion 602e, that is, toward the recessed portion 16d, as shown by an arrow 602h in FIG. A round bar-shaped lock rod 602i extending toward the recess 16d is provided on the surface of the sliding member 602b on the recess 16d side.

A portion 602f of the lock member 602 that faces the fixed portion 602e is a guide portion that guides the lock rod 602i. This guide portion 602f is provided with a roughly U-shaped guide groove 602j that slidably supports the lock rod 602i.

In addition, a generally rectangular flat guide member 604 is provided between the guide portion 602f of the lock member 602 and the recessed portion 106d. This guide member 604 is provided on the inner surface of the casing 16c of the image forming unit 16 so as to face the guide portion 602f of the lock member 602. The guide member 604 is provided with a guide insertion hole 604a through which the lock rod 602i is inserted. The insertion hole 16f provided in the recessed portion 16d and the cover-side insertion hole 200b provided in the switch cover 200 allow the lock rod 602i to enter the insertion hole 16f and the cover-side insertion hole 200b, as described later. It is provided at a position through which the lock rod 602i is inserted when the lock rod 602i is moved toward the lock rod.

Additionally, an insertion hole 602k is provided on the upper surface of the sliding member 602b, into which a tip portion of a plunger 606a, which will be described later, of the solenoid 606 is inserted. This insertion hole 602k is inserted between the sliding member 602b and the guide portion 602f of the locking member 602 at least when the locking rod 602i is not inserted into the cover-side insertion hole 200b of the switch cover 200. The plunger 606a is provided at such a position on the upper surface of the sliding member 602b so that the tip portion of the plunger 606a is inserted into the insertion hole 602k when there is an appropriate distance between the plunger 606a and the insertion hole 602k. As a result, the sliding member 602b is restrained.

The solenoid 606 is of a pull type and has a round bar-shaped plunger 606a. The solenoid 606 is provided above the locking member 602, and more specifically, above the sliding member 602b, with the tip of the plunger 606a facing downward. As described above, the DC detection signal Sdc from the DC mixing detection circuit 506 is also input to this solenoid 606.

Note that a generally rectangular operation window 16g of an appropriate size is provided in the casing 16c of the image forming unit 16 at a position corresponding to the aforementioned guided portion 602c. The operation window 16g is covered by a rectangular flat cover piece 800 on the outer surface of the casing 16c of the image forming section 16. The cover piece 800 is fixed to the casing 16c of the image forming section 16 with an appropriate number of screws 802, 802, for example, two screws. Further, on the inner surface of the casing 16c of the image forming unit 16, two screw hole forming portions 16i are formed, in which two screw holes 16h and 16h (see FIG. 17) are formed, into which the screws 802 and 802 are screwed. and 16i are provided.

That is, in normal times when the DC detection signal Sd from the DC contamination detection circuit 506 is not input to the solenoid 606, the tip of the plunger 606a of the solenoid 606 is inserted into the insertion hole 602k of the sliding member 602b. The sliding member 602b is in a restrained state. At this time, the lock rod 602i is not inserted into at least the cover-side insertion hole 200b of the switch cover 200. Therefore, the switch cover 200 can be opened and closed, especially opened. In addition, the sliding member 602b is located at an appropriate distance from the guide portion 602f of the locking member 602. Further, the sliding member 602b is biased toward the recess 16d (toward the switch cover 200) by the push spring 602g.

In this state, when the DC detection signal Sd from the DC mixture detection circuit 506 is input to the solenoid 606, that is, when the power supply power includes DC power and is detected by the DC mixture detection circuit 506, the solenoid 606 is driven. This causes the plunger 606a of the solenoid 606 to be retracted into the body of the solenoid 606, ie, moved upward, as shown by the arrow 606b in FIGS. 15B and 16. Then, the tip portion of the plunger 606a is pulled out from the insertion hole 602k of the sliding member 602b. Further, the sliding member 602b slides toward the recessed portion 16d due to the biasing force of the push spring 602g and comes into contact with the guide portion 602f. Along with this, the lock rod 602i also moves in the biasing direction of the push spring 602g, and as shown in FIGS. It is inserted. As a result, the switch cover 200 is maintained in a closed state and is locked, so to speak, by the locking mechanism 600. This prevents the main power switch 100 from being turned on accidentally by manual operation.

As described above, according to the second embodiment, when the DC mixture detection circuit 506 detects that the power supply includes DC power, the main power switch 100 is forcibly turned off. Then, the switch cover 200 is locked in the closed state by the locking mechanism 600. Therefore, inconveniences caused by DC power being included in the power supply are reliably prevented.

Note that when the main power switch 100 is turned off, the input of the DC detection signal Sdc to the solenoid 606 of the lock mechanism 600 is stopped. Then, the plunger 606a of the solenoid 606 moves downward due to its own weight and comes into contact with the upper surface of the sliding member 602b. However, the locked state by the lock mechanism 600 is maintained as it is.

To release the locked state by this locking mechanism 600, first, the above-mentioned cover piece 800 is removed. Then, as shown in FIG. 17, it becomes possible to touch the guided portion 602c from the outside of the casing 16c of the image forming section 16 via the operation window 16g. Then, as shown by an arrow 602m in FIG. 17, the guided portion 602c is slowly moved in a direction that opposes the biasing direction of the push spring 602g. In the process, when the insertion hole 602k of the sliding member 602b reaches a position where it hits the tip of the plunger 606a of the solenoid 606, the tip of the plunger 606a is inserted into the insertion hole 602k. As a result, the sliding member 602b is restrained. Then, at least the lock rod 602i is not inserted into the cover-side insertion hole 200b of the switch cover 200. As a result, the locked state by the locking mechanism 600 is released, the switch cover 200 can be opened and closed, and the main power switch 100 can be turned on and off manually.

That is, the guided portion 602c functions as an operator for releasing the locked state by the locking mechanism 600. The work for releasing the locked state by this locking mechanism 600 is also performed by a service person. After this work is completed, the cover piece 800 is attached and returned to its original state.

Note that the locking mechanism 600 in the second embodiment is an example of a blocking means according to the present disclosure, and more specifically, an example of a second maintaining means according to the present disclosure.

[Other application examples]
Each of the embodiments described above is merely a specific example of the present disclosure, and does not limit the technical scope of the present disclosure. That is, the present disclosure can be applied to aspects other than this example.

For example, the locking mechanism 300 in the first embodiment is not limited to the configuration described in the first embodiment. That is, as long as the main power switch 100 can be maintained in an off state, the lock mechanism 300 may be realized by a configuration different from that described in the first embodiment.

Similarly, the locking mechanism 600 in the second embodiment is also not limited to the configuration described in the second embodiment. That is, as long as the switch cover 200 can be maintained in a closed state, the locking mechanism 600 may be realized by a configuration different from that described in the second embodiment.

Furthermore, although a seesaw switch is illustrated as the main power switch 100, the present invention is not limited to this. That is, a switch other than the seesaw switch, such as a toggle switch, a slide switch, or a rotary switch, may be employed as the main power switch 100.

In addition, although the DC contamination detection circuit 506 is provided in the power supply circuit 502, it may be provided in an element other than the power supply circuit 502, such as the control unit 30. In addition, regarding the DC contamination detection circuit 506, a current sensor using a Hall element detects the direction and magnitude of the current component of the power source power, and furthermore, based on the detection result by this current sensor, Although the configuration is such that it is determined whether or not electric power is included, the DC mixing detection circuit 506 may be implemented with a configuration other than this. In any case, the DC contamination detection circuit 506 may have any configuration as long as it can accurately and immediately detect whether or not the power source power includes DC power.

For example, in the first embodiment, the solenoid 302 is driven in response to the input of the DC detection signal Sdc from the DC contamination detection circuit 506, that is, the solenoid 302 is driven using the DC detection signal Sdc as a drive signal. However, the configuration is not limited to this. Although a detailed explanation including illustrations will be omitted, for example, the DC conversion circuit 504 generates a DC voltage Vs as a drive signal for the solenoid 302, and an appropriate switch circuit for inputting this DC voltage Vs to the solenoid 302. may be provided, and this switch circuit may be configured to be turned on/off by the DC detection signal Sdc. That is, during normal times when the power supply does not include DC power, the switch circuit is in an off state. Then, when DC power appears in the power supply, the DC detection signal Sdc is input to the switch circuit, and the switch circuit is turned on. Thereby, the DC voltage Vs as a drive signal for the solenoid 302 is input to the solenoid 302 via the switch circuit, and the solenoid 302 may be driven in response to this. This also applies to the second embodiment.

In each of the embodiments, the multifunction peripheral 10, which is a type of image forming apparatus, has been described as an example, but the invention is not limited thereto. The present disclosure can also be applied to image forming apparatuses other than the multifunction device 10 and electrical devices other than the image forming apparatus.

DESCRIPTION OF SYMBOLS 10... Multifunction device 16a... Fixing device 100... Main power switch 162... Heater 164... Triac 166... Thermostat 200... Switch cover 300... Lock mechanism 500... AC input terminal 502... Power supply circuit 504... DC conversion circuit 506... DC contamination detection circuit 600... Lock mechanism 700... Off solenoid

Claims (6)

An electrical device that operates using AC power as power source,
a switch that manually turns on/off acceptance of input of the power supply;
detection means for detecting whether the power source power includes DC power;
a switch-off means for turning off the switch when the detection means detects that the DC power is included in the power supply;
An electrical appliance, comprising a blocking means for preventing the switch from being turned on by the manual operation when the switch is turned off by the switch-off means. The electrical device according to claim 1, wherein the blocking means includes first maintaining means for maintaining the switch in an off state. further comprising a cover that is configured to be able to transition between a state that covers the switch and a state that exposes the switch to the outside, and that is in a state that covers the switch while the electrical device is in operation;
The electrical device according to claim 1, wherein the blocking means includes a second maintaining means for maintaining the switch covered by the cover. The electrical device according to any one of claims 1 to 3, comprising an alternating current load. The electrical device according to claim 4, wherein the AC load includes a heater and an on/off unit that turns on/off input of the AC power to the heater. The electric device according to claim 5, which is an electrophotographic image forming apparatus including a fixing device having the heater.

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