JP2007263702A - Humidity detection circuit and image forming apparatus with same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a humidity detection circuit which uses a humidity sensor for outputting a humidity detection signal upon the application of AC voltage and prevents the deterioration of a humidity sensor even if a PWM signal for controlling the DC voltage applied to the humidity detection circuit to AC voltage is stopped. <P>SOLUTION: The humidity detection circuit 107 includes transistors TR1, TR2 and TR3 and a humidity sensor HS1. When the AC voltage, wherein the DC voltage supplied from the emitter side of the transistor TR3 by the function of the transistors TR1 and TR2 is controlled on the basis of the PWM signal supplied from the base side of the transistor TR1, is applied to the humidity sensor HS1, the humidity sensor HS1 outputs the humidity detection signal and the PWM signal supplied from the base side of the transistor TR1 is stopped while a reset signal [H] is supplied from the base side of the transistor TR3. Whereupon, the transistor TR3 is turned OFF and the application of DC voltage to the humidity sensor HS1 is cut off. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a humidity detection circuit using a humidity sensor that outputs a humidity detection signal when an AC voltage is applied, and an image forming apparatus having the humidity detection circuit.

Environmental conditions such as humidity are very important factors in controlling the operation of electronic devices. Therefore, conventionally, an invention relating to a humidity detection circuit for detecting humidity and an electronic apparatus having the same has been disclosed. As an example, Patent Document 1 discloses an invention relating to an image forming apparatus having a humidity detection circuit. Has been. According to the present invention, the image forming apparatus takes into consideration the amount of moisture contained in the paper, which is a medium, by applying the applied voltage calculated based on the humidity data acquired from the humidity detection circuit to the transfer roller from the high-voltage power supply. It enables high-quality printing that is not affected by humidity.
JP 2005-43925 A

  By the way, in the humidity detection circuit incorporated in the image forming apparatus or the like, an AC voltage obtained by controlling and converting a DC voltage supplied to the humidity detection circuit using, for example, a PWM (Pulse Width Modulation) signal output from the CPU is applied. In many cases, a humidity sensor that is operated in the same manner is used. However, for example, in an image forming apparatus, when a user opens the cover of the apparatus due to a paper jam or the like, a control unit such as a CPU is stopped by a built-in reset function. Also stop. For this reason, the humidity sensor has a problem in that a direct-current voltage is directly applied to cause deterioration.

  In view of the above problems, an object of the present invention is to control a DC voltage supplied to a humidity detection circuit to an AC voltage in a humidity detection circuit using a humidity sensor that outputs a humidity detection signal when an AC voltage is applied. An object of the present invention is to provide a humidity detection circuit capable of preventing deterioration of the humidity sensor even when the PWM signal is stopped, and an image forming apparatus having the same.

The present invention adopts the following configuration in order to solve the above points.
<Configuration 1>
The humidity detection circuit of the present invention is a humidity detection circuit comprising a conversion circuit that converts a DC voltage into an AC voltage according to an input control signal, and a humidity sensor that outputs a humidity detection signal when the AC voltage is applied. DC voltage cut-off means for cutting off the voltage source of the DC voltage from the humidity sensor at the input of is provided.

<Configuration 2>
An image forming apparatus of the present invention is an image forming apparatus including the humidity detection circuit according to Configuration 1, and outputs an AC voltage to a high voltage supply circuit that supplies a high voltage to a high voltage operation unit and a conversion circuit of the humidity detection circuit. Control the high-voltage supply circuit based on the humidity detection signal received from the humidity detection circuit, and when the reset signal is received, the operation of the high-voltage supply circuit is stopped and the supply of the control signal is stopped. And a shut-off control unit that outputs a shut-off signal to a humidity detection circuit when a reset signal is detected.

<Configuration 3>
A humidity detection circuit according to the present invention includes a conversion circuit that converts a DC voltage into an AC voltage according to an input control signal, and a humidity sensor that outputs a humidity detection signal when the AC voltage is applied. DC voltage drop means for dropping the voltage of the DC voltage at the input of the signal is provided.

<Configuration 4>
An image forming apparatus of the present invention is an image forming apparatus including the humidity detection circuit according to Configuration 3, and outputs an AC voltage to a high voltage supply circuit that supplies a high voltage to the high voltage operation unit and a conversion circuit of the humidity detection circuit. Control the high-voltage supply circuit based on the humidity detection signal received from the humidity detection circuit, and when the reset signal is received, the operation of the high-voltage supply circuit is stopped and the supply of the control signal is stopped. And a descent controller that outputs a descent instruction signal to a humidity detection circuit when a reset signal is detected.

<Configuration 5>
The humidity detection circuit of the present invention switches a first control signal and a second control signal by switching a selection signal and outputs the selected control signal, and converts any DC signal into an AC voltage when receiving either control signal from the selector. A conversion circuit and a humidity sensor that outputs a humidity detection signal when an AC voltage is applied are provided.

<Configuration 6>
An image forming apparatus of the present invention is an image forming apparatus including the humidity detection circuit according to Configuration 5, and outputs an AC voltage to a high voltage supply circuit that supplies a high voltage to the high voltage operation unit and a conversion circuit of the humidity detection circuit. A first control signal is supplied to control the high voltage supply circuit based on the humidity detection signal received from the humidity detection circuit, and when the reset signal is received, the operation of the high voltage supply circuit is stopped, and the first A high-voltage control unit that stops supply of the control signal and a second control signal output unit that outputs a selection signal and a second control signal to the humidity detection circuit when a reset signal is detected are provided.

  In the humidity detection circuit using a humidity sensor that outputs a humidity detection signal when an AC voltage is applied, even if the PWM signal for controlling the DC voltage supplied to the humidity detection circuit to an AC voltage is stopped, Since a DC voltage having a voltage value that causes deterioration of the humidity sensor is not applied to the humidity sensor, it is possible to prevent the humidity sensor from being deteriorated.

  Hereinafter, embodiments of the present invention will be described in detail using examples.

<Configuration of Example 1>
FIG. 1 shows a configuration of an image forming apparatus having a humidity detection circuit according to a first embodiment of the present invention.

  The image forming apparatus 100 includes an apparatus control unit 101 that controls the entire apparatus, a power supply unit 102, an operation unit 103, a reading unit 104, an image memory 105, a signal control unit 106, a humidity detection circuit 107, and an image. A forming unit high voltage supply circuit 108, an image fixing unit high voltage supply circuit 109, a medium conveying unit 110, an image forming unit 111, an image fixing unit 112, a cover open sensor 113, and a reset circuit 114 are provided.

  The apparatus control unit 101 is a processor that controls the entire image forming apparatus 100, and is synchronized with a pulse signal generated by a clock (a circuit including a crystal oscillator for determining time) that is built in the image forming apparatus 100. The entire device is controlled.

  For example, when the power is turned on using a switch provided in the power supply unit 102 of the image forming apparatus 100, the apparatus control unit 101 starts an initialization operation and temporarily stores data (not shown) of the image forming apparatus 100. (Random Access Memory) erases all data held, supplies power to the medium transport unit 110, the image forming unit 111, and the image fixing unit 112, and determines whether these are operating normally. In order to confirm, the operation confirmation is instructed to each unit.

  Upon receiving an operation confirmation instruction, the medium transport unit 110 performs an initial operation. When the medium transport unit 110 operates normally, the medium transport unit 110 generates a normal operation signal and transmits the normal operation signal to the apparatus control unit 101. On the other hand, if the medium transport unit 110 does not operate normally, the medium transport unit 110 generates an abnormal operation signal and transmits the abnormal operation signal to the apparatus control unit 101. Here, the operations performed by the image forming unit 111 and the image fixing unit 112 are the same as the operations of the medium transport unit 110.

  When the device control unit 101 acquires a normal operation signal from each unit, the device control unit 101 generates a signal control operation confirmation signal and transmits the confirmation signal to the signal control unit 106.

  The signal control unit 106 outputs a control signal for controlling a high voltage supplied to the image forming unit 111 and the image fixing unit 112 based on environmental conditions such as humidity. The supply of a high voltage is controlled in synchronization with a pulse signal generated by a clock (not shown) built in the forming apparatus 100.

  Then, when the signal control unit 106 obtains the signal control operation confirmation signal, the signal control unit 106 performs an initial operation. When the signal control unit 106 operates normally, the signal control unit 106 generates a normal operation signal and transmits the normal operation signal to the apparatus control unit 101. On the other hand, if the signal control unit 106 does not operate normally, the signal control unit 106 generates an abnormal operation signal and transmits the abnormal operation signal to the apparatus control unit 101.

  When the signal control unit 106 generates a PWM signal and supplies the PWM signal to the humidity detection circuit 107, the humidity detection circuit 107 controls the humidity sensor HS1 (see FIG. 3) provided in the humidity detection circuit 107 with the PWM signal. Apply the alternating voltage. The humidity sensor HS1 provided in the humidity detection circuit 107 outputs a humidity detection signal based on the humidity when an AC voltage is applied.

  The operation unit 103 includes a key switch for receiving print settings and operation instructions from the user, and a liquid crystal display for displaying a notification screen for notifying the user of the device status and the like.

  Upon acquiring the normal operation signal, the apparatus control unit 101 executes a memory control program (not shown) and displays a printable notification screen on the liquid crystal display provided in the operation unit 103 to notify the user that printing is possible. Display.

  On the other hand, upon acquiring the abnormal operation signal, the device control unit 101 executes a memory control program (not shown) and operates an error notification screen for notifying the user that an error has occurred at the source of the abnormal operation signal. The image is displayed on a liquid crystal display provided in the unit 103, and the medium transport unit 110, the image forming unit 111, and the image fixing unit 112 are temporarily stopped. When the user completes the process corresponding to the notification screen, the apparatus control unit 101 releases the pause state of the medium transport unit 110, the image forming unit 111, and the image fixing unit 112.

  When the apparatus control unit 101 receives print data from a host device via an interface (I / F) unit (not shown) of the image forming apparatus 100, the device control unit 101 instructs a rasterization conversion unit (not shown) of the image forming apparatus 100 to perform rasterization conversion. To do. Here, an I / F unit (not shown) of the image forming apparatus 100 is a unit for receiving print data from a higher-level device and notifying the processing result of the received print data, and a serial interface such as a USB (Universal Serial Bus). Or a parallel interface such as IEEE 1284, etc., which is connected to a host device using a predetermined protocol of each interface.

  When receiving a rasterize conversion instruction, a rasterize conversion unit (not shown) of the image forming apparatus 100 converts print data acquired from the host device into image data. When a rasterize conversion unit (not shown) of the image forming apparatus 100 generates image data, the apparatus control unit 101 stores the generated image data in the image memory 105. Here, the host device is a PC (Personal Computer) operated by a user to make a print request to the image forming apparatus 100.

  On the other hand, when a user sets a document on a scanner provided in the reading unit 104, the scanner of the reading unit 104 reads the document and generates image data. When the reading unit 104 generates image data, the apparatus control unit 101 stores the generated image data in the image memory 105.

  When the apparatus control unit 101 stores the image data in the image memory 105, the apparatus control unit 101 causes the signal control unit 106 to output a high voltage based on humidity from the image forming unit high voltage supply circuit 108 and the image fixing unit high voltage supply circuit 109. The output of the high voltage control signal is instructed.

  When receiving an instruction to output a high voltage control signal, the signal control unit 106 includes means for reading the humidity detection signal output from the humidity detection circuit 107 as digital value humidity data. FIG. 2 shows the relationship between the humidity detection signal output from the humidity detection circuit 107 and the PWM signal (cycle is 1 ms) output from the signal control unit 106. Here, the waveform of the humidity detection signal rises every time the PWM signal is inverted, and the signal control unit 106 reads the humidity detection signal immediately before the PWM signal is inverted as digital humidity data.

  When reading the humidity data, the signal control unit 106 generates a high voltage control signal based on the humidity data, and transmits the high voltage control signal to the image forming unit high voltage supply circuit 108 and the image fixing unit high voltage supply circuit 109. .

  When the high voltage control signal is acquired, the image forming unit high voltage supply circuit 108 converts the power supply voltage supplied from the power supply unit 102 into a high voltage controlled by the high voltage control signal and outputs it. That is, the image forming unit high voltage supply circuit 108 supplies the high voltage to the image forming unit 111. Here, the operation performed by the image fixing unit high voltage supply circuit 109 is the same as the operation of the image forming unit high voltage supply circuit 108.

  When a high voltage is supplied, the image forming unit 111 charges the photosensitive drum with a charger (not shown) provided in the image forming unit 111. Next, when the photosensitive drum is charged, the image forming unit 111 irradiates the photosensitive drum with laser light based on image data held in the image memory 105 using a laser provided in the image forming unit 111. Form.

  When a latent image is formed on the photosensitive drum, toner is supplied to the photosensitive drum via a developing roller to form a toner image on the photosensitive drum. On the other hand, the apparatus control unit 101 instructs the medium transport unit 110 to transport the print medium.

  When the medium transport unit 110 receives a print medium transport instruction, the medium transport unit 110 transports the print medium to a transfer roller included in the image forming unit 111 using a transport roller included in the medium transport unit 110.

  When the conveyance roller conveys the print medium to the transfer roller, the image forming unit 111 charges the transfer roller to a high voltage and transfers the toner image on the photosensitive drum onto the print medium.

  When the image forming unit 111 transfers the toner image on the photosensitive drum onto the print medium, the apparatus control unit 101 instructs the image fixing unit 112 to perform fixing.

  When the image fixing unit 112 is supplied with a high voltage from the image fixing unit high-voltage supply circuit 109 and receives a fixing instruction, the image fixing unit 112 includes a fixing roller and a pressure roller provided in the image fixing unit 112 for the toner image on the print medium. Is used to apply heat and pressure to fix the toner image on the print medium.

  When the toner image is fixed on the print medium by the fixing roller and the pressure roller, the apparatus control unit 101 instructs the medium transport unit 110 to discharge the print medium.

  When the medium transport unit 110 receives a print medium discharge instruction, the medium transport unit 110 discharges the print medium from a discharge unit (not illustrated) of the image forming apparatus 100 using a discharge roller provided in the medium transport unit 110.

  The cover open sensor 113 is a sensor for detecting that the cover of the image forming apparatus 100 is opened. When the cover is opened, the cover open sensor 113 generates a cover open signal and transmits the cover open signal to the reset circuit 114. .

  Upon acquiring the cover open signal, the reset circuit 114 generates a reset signal to stop the high voltage output from the image forming unit high voltage supply circuit 108 and the image fixing unit high voltage supply circuit 109 in consideration of the safety of the user. The reset signal is transmitted to the signal control unit 106 and the humidity detection circuit 107. Further, when the reset circuit 114 acquires the cover open signal, the reset circuit 114 transmits the cover open signal to the apparatus control unit 101.

  When the signal control unit 106 acquires the reset signal, the signal control unit 106 stops outputting the PWM signal.

  When the humidity detection circuit 107 acquires the reset signal, the supply of the DC voltage applied to the humidity detection circuit 107 is interrupted as will be described later. Therefore, the output of the humidity detection signal from the humidity sensor HS1 (see FIG. 3) provided in the humidity detection circuit 107 is stopped.

  When acquiring the cover open signal, the apparatus control unit 101 puts the medium transport unit 110, the image forming unit 111, and the image fixing unit 112 into a temporarily stopped state. The apparatus control unit 101 executes a control program (not shown) of the image forming apparatus 100 and includes a cover open notification screen on the operation unit 103 for notifying the user that the cover is open. To display.

  When the cover of the image forming apparatus 100 is closed, the cover open sensor 113 detects that the cover is closed, generates a reset release signal, and transmits the reset release signal to the reset circuit 114.

  When the reset circuit 114 acquires the reset release signal, the reset circuit 114 stops generating the reset signal and transmitting the reset signal to the signal control unit 106 and the humidity detection circuit 107. Further, when the reset circuit 114 acquires the reset release signal, the reset circuit 114 transmits the reset release signal to the device control unit 101.

  When the reset signal is stopped, the signal control unit 106 starts operation and starts outputting the PWM signal. When the PWM signal is supplied, the humidity sensor HS1 provided in the humidity detection circuit 107 outputs a humidity detection signal.

  When the apparatus control unit 101 acquires the reset release signal, the device control unit 101 releases the temporary stop state of the medium conveyance unit 110, the image forming unit 111, and the image fixing unit 112. When the suspension state is released, the apparatus control unit 101 generates an operation confirmation signal and transmits the operation confirmation signal to the medium transport unit 110, the image forming unit 111, and the image fixing unit 112.

  Next, the configuration of the humidity detection circuit 107 will be described. The humidity detection circuit 107 is a circuit that outputs a humidity detection signal based on humidity when a PWM signal is supplied from the signal control unit 106.

  FIG. 3 shows the configuration of the humidity detection circuit 107 according to the first embodiment of the present invention. The humidity detection circuit 107 includes transistors TR1, TR2, and TR3 and a humidity sensor HS1.

  The transistors TR1 and TR2 are provided to apply an AC voltage to the humidity sensor HS1, and when the PWM signal supplied from the base side of TR1 is “H”, TR1 is ON and TR2 is OFF, When the RWM signal is “L”, TR1 is OFF and TR2 is ON. On the other hand, a constant voltage of 5 V is constantly applied to the transistor TR3, and "L" (opposite to the reset signal) is applied to the base thereof, thereby conducting. Therefore, since the DC voltage supplied from the emitter side of TR3 is controlled to the AC voltage based on the PWM signal supplied from the base side of TR1 due to the role of the transistors TR1 and TR2, the humidity sensor HS1 Is applied with an AC voltage.

  FIG. 4 shows the configuration of the humidity sensor HS1 (Hokuriku Electric Co., Ltd.). Here, FIG. 4A shows a view of the humidity sensor HS1 as viewed from the front, and FIG. 4B shows a view of the humidity sensor HS1 as viewed from the side. The humidity sensor HS1 includes an alumina substrate 1, a moisture sensitive film 2, a protective film 3, a comb electrode 4, a silver (palladium) electrode 5, a solder 6, a lead frame 7, and a case 8. The

  Here, the humidity sensor HS1 utilizes the property of increasing or decreasing the electrical conductivity of the ionic polymer in the moisture sensitive film 3 according to a change in humidity. That is, the humidity sensor HS1 detects humidity when the counter ion of the moisture sensitive film 3 takes in water vapor and dissociates to become movable ions, and the impedance value decreases according to the amount of water vapor. However, when a DC voltage is applied to the humidity sensor HS1, the movable ions are biased. Therefore, the humidity sensor HS1 needs to apply an AC voltage.

  The humidity sensor HS1 outputs a humidity detection signal when an AC voltage is applied.

  On the other hand, when the supply of the PWM signal from the base side of the transistor TR1 is stopped and the reset signal “H” is supplied from the base side of TR3, the TR3 is turned OFF. That is, the transistor TR3 cuts off the application of a DC voltage to the humidity sensor HS1.

<Operation of Example 1>
Next, the operation of the image forming apparatus 100 having the humidity detection circuit according to the first embodiment of the present invention will be described with reference to a time chart showing the operation of the humidity detection circuit of FIG.

  When the user confirms the printable notification screen displayed on the display of the operation unit 103 of the image forming apparatus 100, the user sets a document on the scanner provided in the reading unit 104 and uses the key switch of the operation unit 103 to set print settings and A print instruction is issued (step S1).

  When the scanner of the reading unit 104 reads a document and generates image data, the apparatus control unit 101 stores the image data in the image memory 105 (step S2).

  After storing the image data in the image memory 105, the device control unit 101 instructs the signal control unit 106 to output a high voltage control signal (step S3).

  When receiving a high voltage control signal output instruction, the signal control unit 106 reads the humidity detection signal output from the humidity detection circuit 107 as digital humidity data. Then, when reading the humidity data, the signal control unit 106 generates a high voltage control signal based on the humidity data, and sends the high voltage control signal to the image forming unit high voltage supply circuit 108 and the image fixing unit high voltage supply circuit 109. Transmit (step S4).

  Here, the operation of the humidity detection circuit 107 in the above state will be described with reference to (Area A) of FIG. When the image forming apparatus 100 is operating normally, a PWM signal is supplied from the signal control unit 106 to the humidity detection circuit 107. For this reason, in the humidity detection circuit 107, the DC voltage is controlled by the operation of the transistors TR1 and TR2, and therefore the AC voltage is applied to the humidity sensor HS1. Therefore, the humidity sensor HS1 outputs a humidity detection signal.

  When the high voltage control signal is acquired, the image forming unit high voltage supply circuit 108 converts the power supply voltage output from the power supply unit 102 into a high voltage controlled by the high voltage control signal and outputs it. When the image forming unit high voltage supply circuit 108 outputs a high voltage, the image forming unit high voltage supply circuit 108 supplies the high voltage to the image forming unit 111.

  Similarly, when the image fixing unit high voltage supply circuit 109 acquires the high voltage control signal, the image fixing unit high voltage supply circuit 109 converts the power supply voltage output from the power supply unit 102 into a high voltage controlled by the high voltage control signal and outputs it. When the image fixing unit high voltage supply circuit 109 outputs a high voltage, the image fixing unit high voltage supply circuit 109 supplies the high voltage to the image fixing unit 112 (step S5).

  Thereafter, in response to a print instruction to the medium transport unit 110, the image forming unit 111, and the image fixing unit 112 of the apparatus control unit 101, each unit starts a printing process based on the image data held in the image memory 105. (Step S6).

  When a paper jam occurs in the medium conveying unit 110, the apparatus control unit 101 temporarily stops the medium conveying unit 110, the image forming unit 111, and the image fixing unit 112 (step S7). Then, the apparatus control unit 101 executes a memory control program (not shown) to display a notification message indicating, for example, “A paper jam has occurred” on the liquid crystal display of the operation unit 103.

  When the user confirms the notification message displayed on the display of the operation unit 103, the user opens the cover of the image forming apparatus 100 to deal with a paper jam. When the cover of the image forming apparatus 100 is opened, the cover open sensor 113 detects that the cover has been opened, generates a cover open signal, and transmits the cover open signal to the reset circuit 114 (step S8).

  When acquiring the cover open signal, the reset circuit 114 generates a reset signal and transmits the reset signal to the signal control unit 106 and the humidity detection circuit 107 (step S9).

  Here, the operation of the humidity detection circuit 107 in the above state will be described with reference to (region B) of FIG. When the signal control unit 106 acquires the reset signal, the signal control unit 106 stops outputting the PWM signal. When the reset signal is supplied, the humidity detection circuit 107 turns off the transistor TR3 and cuts off the application of the DC voltage to the humidity sensor HS1. Therefore, the humidity sensor HS1 stops outputting the humidity detection signal.

  When the humidity detection circuit 107 stops outputting the humidity detection signal, the signal control unit 106 stops outputting the high voltage control signal. When the supply of the high voltage control signal is stopped, the image forming unit high voltage supply circuit 108 stops the output of the high voltage. Similarly, when the supply of the high voltage control signal is stopped, the image fixing unit high voltage supply circuit 109 stops the output of the high voltage (step S10).

  In addition, the reset circuit 114 acquires a cover open signal and generates a reset signal, and transmits the cover open signal to the apparatus control unit 101 (step S11).

  When acquiring the cover open signal, the apparatus control unit 101 temporarily stops the medium conveyance unit 110, the image forming unit 111, and the image fixing unit 112 (step S12). Then, the apparatus control unit 101 executes a control program (not shown) of the image forming apparatus 100 and displays a message indicating, for example, “Cover is open” on the liquid crystal panel provided in the operation unit 103.

  When the user completes the processing for paper jam and closes the cover of the image forming apparatus 100, the cover open sensor 113 detects that the cover is closed, generates a reset release signal, and resets the reset release signal. The data is transmitted to the circuit 114 and the device control unit 101 (step S13).

  When the reset circuit 114 acquires the reset release signal, the reset circuit 114 stops outputting the reset signal to the signal control unit 106. When the reset circuit 114 stops outputting the reset signal, the signal control unit 106 activates the signal control unit 106 and outputs a PWM signal (step S14).

  Here, the operation of the humidity detection circuit 107 in the above state will be described with reference to (region C) in FIG. When the signal control unit 106 outputs a PWM signal, the PWM signal is supplied to the humidity detection circuit 107. On the other hand, when the reset signal is stopped, “L” is applied to the base of the transistor TR3 to start the operation. Therefore, since the transistor TR3 is turned on in the humidity detection circuit 107, the DC voltage from the emitter side of TR3 is controlled by the operation of TR1 and TR2, and the AC voltage is applied to the humidity sensor HS1. Therefore, the humidity sensor HS1 outputs a humidity detection signal. At this time, the humidity sensor HS1 has a problem of responsiveness of the humidity sensor HS1, and the output of the humidity detection signal may not be stable for an initial few seconds when the AC voltage is applied.

  When acquiring the reset release signal, the apparatus control unit 101 releases the temporary stop of the medium transport unit 110, the image forming unit 111, and the image fixing unit 112 (step S15). When the suspension is released, the apparatus control unit 101 generates an operation confirmation signal, and transmits the operation confirmation signal to the medium transport unit 110, the image forming unit 111, and the image fixing unit 112 (step S16). .

  Further, when the apparatus control unit 101 acquires normal operation signals from the medium conveyance unit 110, the image forming unit 111, and the image fixing unit 112, the apparatus control unit 101 generates a signal control operation confirmation signal, and the signal control unit It transmits to 106 (step S17).

  When the signal control unit 106 acquires the confirmation signal, the signal control unit 106 erases all the data held in the RAM (not shown) of the signal control unit 106, and when the initial operation is performed, generates a normal operation signal and transmits the normal operation signal to the device. It transmits to the control part 101 (step S18).

  When acquiring the normal operation signal, the apparatus control unit 101 resumes the printing process based on the image data held in the image memory 105 (step S19).

<Effect of Example 1>
According to the image forming apparatus 100 having the humidity detection circuit 107 of the first embodiment, when the cover of the image forming apparatus 100 is opened, the signal control unit 106 is stopped and the supply of the PWM signal to the humidity detection circuit is stopped. Then, since the supply of the DC voltage to the humidity detection circuit 107 is cut off, it is possible to prevent the humidity sensor HS1 from being deteriorated due to the application of the DC voltage.

<Configuration of Example 2>
The humidity detection circuit according to the second embodiment of the present invention is a humidity detection circuit 107a in which a Zener diode (constant voltage diode) is added instead of the humidity detection circuit 107 in the image forming apparatus 100 of FIG.

  The configuration of the humidity detection circuit 107a according to the second embodiment of the present invention will be described with reference to FIG. The humidity detection circuit 107 includes transistors TR1, TR2, and TR3, a humidity sensor HS1, and a Zener diode D1.

  The Zener diode D1 has a characteristic of generating a Zener voltage (constant voltage) Vz when a voltage is applied from the cathode side to the anode side (reverse direction).

  When the PWM signal is supplied to the base side of the transistor TR1, the humidity sensor HS1 outputs a humidity detection signal as in the humidity detection circuit of the first embodiment.

  On the other hand, when the supply of the PWM signal is stopped from the base side of the transistor TR1 and the reset signal “H” is supplied from the base side of TR3, the TR3 is turned off. The Zener diode D1 generates a Zener voltage Vz when a reverse voltage of 5V is applied from the cathode side, and applies a DC voltage of 5V−Vz (5V> Vz) to the humidity sensor HS1. Here, 5V-Vz applied to the humidity sensor HS1 is equal to or less than a direct-current voltage value causing deterioration of the humidity sensor HS1.

<Operation of Example 2>
Next, the operation of the humidity detection circuit 107a in the image forming apparatus having the humidity detection circuit according to the second embodiment of the present invention will be described with reference to a time chart showing the operation of the humidity detection circuit in FIG. Here, the operation of the image forming apparatus of the second embodiment is the same as that of the image forming apparatus 100 of the first embodiment except for the operation in the humidity detection circuit 107a.

  When the PWM signal is supplied from the signal control unit 106 in the state of (region D) in FIG. 7, the DC voltage 5V is controlled by the operation of the transistors TR1 and TR2, and therefore the AC voltage is applied to the humidity sensor HS1. Is done. Therefore, the humidity sensor HS1 outputs a humidity detection signal.

  7 (region E), when the supply of the PWM signal from the signal control unit 106 is stopped and the reset signal “H” is supplied from the reset circuit 114, the transistor TR3 is turned off. Then, since a reverse voltage of 5 V is applied from the cathode side, the Zener diode D1 generates a Zener voltage Vz and applies a DC voltage of 5 V-Vz (5 V> Vz) to the humidity sensor HS1. Therefore, the humidity sensor HS1 stops outputting the humidity detection signal.

  Further, when the PWM signal is supplied from the signal control unit 106 in response to the stop of the reset signal from the reset circuit 114 in the state of (region F) in FIG. 7, “L” is applied to the base side of the transistor TR3. Is done. Thereby, in the humidity detection circuit 107a, the transistor TR3 is turned on, so that the DC voltage from the emitter side of TR3 is controlled by the operation of TR1 and TR2, and the AC voltage is applied to the humidity sensor HS1. Therefore, the humidity sensor HS1 outputs a humidity detection signal again. At this time, the humidity sensor HS1 outputs a stable humidity detection signal instantaneously after the application of the AC voltage is started.

<Effect of Example 2>
According to the image forming apparatus having the humidity detection circuit 107a of the second embodiment, when the signal control unit 106 is stopped and the supply of the PWM signal to the humidity detection circuit is stopped by opening the cover of the image forming apparatus, Since only a direct current voltage equal to or lower than the voltage value causing the deterioration of the humidity sensor HS1 is applied to the humidity sensor HS1, the deterioration of the humidity sensor HS1 can be prevented.

  Further, according to the image forming apparatus, since the application of the DC voltage is not interrupted in the humidity detection circuit 107a, when the supply of the PWM signal is resumed by the activation of the signal control unit 106, the humidity sensor HS1 instantaneously and stably detects the humidity. A signal can be output.

<Configuration of Example 3>
FIG. 8 shows a configuration of an image forming apparatus 100b having a humidity detection circuit according to the third embodiment of the present invention. The image forming apparatus 100b according to the third embodiment deletes the transistor TR3 of the humidity detection circuit 107 instead of the humidity detection circuit 107 according to the first embodiment, and controls and converts a DC voltage from two PWM signals to an AC voltage. A humidity detection circuit 107b to which a selector for selecting the control signal is added, and a device control unit 101b that supplies the second PWM signal to the humidity detection circuit 107b instead of the device control unit 101 of the first embodiment. The other configuration of the image forming apparatus 100b according to the third embodiment is the same as that of the image forming apparatus 100 according to the first embodiment.

  The apparatus control unit 101b is a processor that controls the entire image forming apparatus 100b, and controls the entire apparatus in synchronization with a pulse signal generated by a clock (not shown) built in the image forming apparatus 100b. In the present embodiment, when receiving the cover open signal, the device control unit 101b generates a second PWM signal and outputs the second PWM signal to the humidity detection circuit 107b.

  When the PWM signal and the second PWM signal are supplied, the humidity detection circuit 107b applies an AC voltage controlled by the PWM signal to the humidity sensor HS1 provided in the humidity detection circuit 107b. The humidity sensor HS1 provided in the humidity detection circuit 107b outputs a humidity detection signal based on the humidity when an AC voltage is applied.

  The configuration of the humidity detection circuit 107b according to the third embodiment of the present invention will be described with reference to FIG. The humidity detection circuit 107b includes transistors TR1 and TR2, a humidity sensor HS1, and a selector IC1.

  The selector IC1 selects the PWM signal supplied from the signal control unit 106 as a control signal for controlling and converting the DC voltage 5V to the AC voltage in the reset signal “L”.

  On the other hand, when the reset signal is switched to “H”, the selector IC1 selects the second PWM signal supplied from the device control unit 101b as a DC voltage control signal.

  Therefore, even if the supply of the PWM signal from the signal control unit 106 is stopped, the AC voltage is applied to the humidity sensor HS1 by the supply of the second PWM signal to the base side of the transistor TR1, and therefore the humidity sensor HS1 Continuously outputs a humidity detection signal.

<Operation of Example 3>
Next, the operation of the humidity detection circuit 107b in the image forming apparatus 100b having the humidity detection circuit according to the third embodiment of the present invention will be described with reference to a time chart showing the operation of the humidity detection circuit in FIG. Here, the operation of the image forming apparatus 100b according to the third embodiment is the same as that of the image forming apparatus 100 according to the first embodiment except for the operations in the apparatus control unit 101b and the humidity detection circuit 107b.

  In the state of (region G) in FIG. 10, when a PWM signal is supplied from the signal control unit 106, the selector IC1 selects the PWM signal as a control signal. When a PWM signal is supplied from the base side of the transistor TR1, the DC voltage 5V is controlled by the operation of the transistors TR1 and TR2, and therefore an AC voltage is applied to the humidity sensor HS1. Therefore, the humidity sensor HS1 outputs a humidity detection signal.

  10 (region H), the reset signal “H” is supplied from the reset circuit 114, the second PWM signal is supplied from the device control unit 101b, and the PWM signal is supplied from the signal control unit 106. When stopped, the selector IC1 selects the second PWM signal as a control signal. Then, when the second PWM signal is supplied from the base side of the transistor TR1, the DC voltage 5V is controlled by the operation of the transistors TR1 and TR2, so that an AC voltage is applied to the humidity sensor HS1. Therefore, the humidity sensor HS1 continuously outputs a humidity detection signal.

  Further, in the state of (region I) in FIG. 10, when the signal control unit 106 outputs a PWM signal by stopping the reset signal, the PWM signal is supplied to the humidity detection circuit 107b. Then, when the PWM signal is supplied, the selector IC1 selects the PWM signal as a control signal as described above. Accordingly, an AC voltage is applied to the humidity sensor HS1. Therefore, since the application of the AC voltage is not interrupted to the humidity sensor HS1, the humidity sensor HS1 continues to output a stable humidity detection signal and is not destroyed.

<Effect of Example 3>
According to the image forming apparatus 100b having the humidity detection circuit 107b of the third embodiment, the signal control unit 106 is stopped by stopping the cover of the image forming apparatus 100b, and the supply of the PWM signal to the humidity detection circuit is stopped. Then, since the second PWM signal output from the device control unit 101b is used as a control signal for controlling and converting the DC voltage into the AC voltage, the application of the AC voltage to the humidity sensor HS1 is continued, so that the humidity detection sensor HS1 is deteriorated. Can be prevented.

  Further, according to the image forming apparatus 100b, since the application of the AC voltage to the humidity sensor HS1 is not interrupted in the humidity detection circuit 107b, the humidity sensor HS1 can always output a stable humidity detection signal.

  In the above-described embodiments, the example in which the image forming apparatus having the humidity detection circuit of the present invention is applied as a printer has been described. However, the present invention is not limited to this, and can be applied to, for example, a multifunction machine.

1 is a block diagram illustrating a configuration of an image forming apparatus having a humidity detection circuit according to a first embodiment of the present invention. It is a figure which shows the relationship between the PWM signal which concerns on this invention, and a humidity detection signal. It is a humidity detection circuit diagram of Example 1 concerning the present invention. It is a figure which shows the structure of the humidity sensor which concerns on this invention. It is a time chart which shows operation | movement of the humidity detection circuit of Example 1 which concerns on this invention. It is a humidity detection circuit diagram of Example 2 concerning the present invention. It is a time chart which shows operation | movement of the humidity detection circuit of Example 2 which concerns on this invention. It is a block diagram which shows the structure of the image forming apparatus which has a humidity detection circuit of Example 3 which concerns on this invention. It is a humidity detection circuit diagram of Example 3 concerning the present invention. It is a time chart which shows operation | movement of the humidity detection circuit of Example 3 which concerns on this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Image forming apparatus 101 Apparatus control part 102 Power supply part 103 Operation part 104 Reading part 105 Image memory 106 Signal control part 107 Humidity detection circuit 108 Image formation part High voltage supply circuit 109 Image fixing part High voltage supply circuit 110 Medium conveyance part 111 Image formation part 112 Image fixing unit 113 Cover open sensor 114 Reset circuit

Claims (6)

In a humidity detection circuit comprising a conversion circuit that converts a DC voltage into an AC voltage according to an input control signal, and a humidity sensor that outputs a humidity detection signal when the AC voltage is applied,
A humidity detection circuit comprising: a DC voltage blocking means for blocking the voltage source of the DC voltage from the humidity sensor upon input of a blocking signal. An image forming apparatus comprising the humidity detection circuit according to claim 1,
A high-voltage supply circuit for supplying a high voltage to the high-voltage operating unit;
The control signal for outputting the AC voltage to the conversion circuit of the humidity detection circuit is supplied, the high-voltage supply circuit is controlled based on the humidity detection signal received from the humidity detection circuit, and a reset signal is received And a high voltage control unit that stops the operation of the high voltage supply circuit and stops the supply of the control signal,
An image forming apparatus comprising: a cutoff control unit that outputs the cutoff signal to the humidity detection circuit when detecting the reset signal. In a humidity detection circuit comprising a conversion circuit that converts a DC voltage into an AC voltage according to an input control signal, and a humidity sensor that outputs a humidity detection signal when the AC voltage is applied,
A humidity detection circuit comprising DC voltage drop means for dropping the DC voltage upon input of a drop instruction signal. An image forming apparatus comprising the humidity detection circuit according to claim 3,
A high-voltage supply circuit for supplying a high voltage to the high-voltage operating unit;
The control signal for outputting the AC voltage to the conversion circuit of the humidity detection circuit is supplied, the high-voltage supply circuit is controlled based on the humidity detection signal received from the humidity detection circuit, and a reset signal is received And a high voltage control unit that stops the operation of the high voltage supply circuit and stops the supply of the control signal,
An image forming apparatus comprising: a descent control unit that outputs the descent instruction signal to the humidity detection circuit when the reset signal is detected.   A selector that switches and outputs a first control signal and a second control signal by an input of a selection signal, a conversion circuit that converts a DC voltage into an AC voltage when receiving one of the control signals from the selector, and the AC voltage And a humidity sensor that outputs a humidity detection signal when applied. An image forming apparatus comprising the humidity detection circuit according to claim 5,
A high-voltage supply circuit for supplying a high voltage to the high-voltage operation unit;
Supplying the first control signal for outputting the AC voltage to the conversion circuit of the humidity detection circuit, controlling the high-voltage supply circuit based on the humidity detection signal received from the humidity detection circuit, and resetting A high-voltage control unit that stops the operation of the high-voltage supply circuit when receiving a signal, and stops the supply of the first control signal;
An image forming apparatus comprising: a second control signal output unit that outputs the selection signal and the second control signal to the humidity detection circuit when the reset signal is detected.

Images