JP4461653B2 - Image forming apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an image forming apparatus that sequentially transfers toner images formed on a plurality of photoconductors to a transfer target to form an image. More specifically, the present invention relates to an image forming apparatus capable of applying an appropriate transfer voltage to a plurality of transfer units with a small number of power supplies.
[0002]
[Prior art]
  In an electrophotographic image forming apparatus, it is necessary to supply a high transfer voltage to the transfer roller. For this reason, the DC voltage of 24V converted from the commercial power supply is made a desired high voltage using an appropriate boost converter and supplied to the transfer roller. The tandem image forming apparatus forms a color image by superimposing four color toner images of yellow, magenta, cyan, and black on a transfer belt. Therefore, it has four photosensitive drums and four transfer rollers for transferring a toner image from each photosensitive drum onto a transfer belt. Therefore, in the tandem type image forming apparatus, it is necessary to supply the transfer voltage to each of the four transfer rollers. In the case of the configuration in which secondary transfer is performed, the number of secondary transfer rollers is increased by one, so that there are five transfer rollers. As described above, in the tandem type image forming apparatus, a circuit for supplying a high voltage to each transfer roller becomes complicated, and the number of parts increases.
[0003]
  For this reason, there is a demand for simplifying a circuit for supplying a high voltage to a plurality of transfer rollers and reducing the number of parts. Various power supply circuits have been proposed to meet such demands. One example is a high-voltage power supply circuit described in JP-A-11-89226. Here, a high-voltage power supply circuit having a plurality of output terminals for supplying a high voltage is described. This circuit is for supplying a high voltage to each of a plurality of devices in the image forming apparatus. That is, the DC voltage boosted by one DC-DC converter is input to a plurality of voltage doubler rectifier circuits, boosted by each voltage doubler rectifier circuit, and output.
[0004]
[Problems to be solved by the invention]
  However, the circuit described in Japanese Patent Laid-Open No. 11-89226 has a plurality of voltage doubler rectifier circuits although the transformer is one for a DC-DC converter. Also, a control device for each voltage doubler rectifier circuit is required. For this reason, there was a problem that the number of parts could not be reduced comprehensively.
[0005]
  Furthermore, in order to obtain a high-quality image, it is necessary to apply an appropriate transfer voltage corresponding to the resistance change of the transfer roller. For this reason, generally, ATVC control for applying an appropriate transfer voltage to each transfer roller is performed. Accordingly, it is necessary to simplify the circuit for supplying a high voltage to the plurality of transfer rollers and to appropriately perform the ATVC control. In the ATVC control, the voltage applied to the transfer roller during image formation is determined based on the value of the current flowing through the transfer roller when a specified voltage is applied to the transfer roller. Alternatively, the voltage applied to the transfer roller during image formation is determined based on the voltage value applied to the transfer roller when a specified current value is passed through the transfer roller.
[0006]
  Accordingly, the present invention has been made to solve the above-described problems, and simplifies the configuration of a circuit for supplying a transfer voltage to a plurality of transfer means, and makes an appropriate transfer to each transfer means. An object is to provide an image forming apparatus capable of applying a voltage.
[0007]
[Means for Solving the Problems]
  An image forming apparatus according to the present invention, which has been made to solve the above problems, transfers a plurality of image carriers and toner images carried on the plurality of image carriers to a transfer target., Resistance values are equal to each otherA plurality of first transfer means and the toner image transferred to the transfer target are transferred to the recording medium.The resistance value is equal to one of the plurality of first transfer means.A second transfer means, a variable resistance element for connecting the plurality of first transfer means and the second transfer means in the order of transfer, and a resistance control means for controlling the resistance value of the variable resistance element A high voltage generating means for supplying a transfer voltage to the plurality of first transfer means and the second transfer means, and an output for controlling an output value of the high voltage generating means. One end is connected to the control means, the current detection means for detecting the magnitude of the current flowing into the high voltage generating means, and the first transfer means that performs the transfer first, and the other end is grounded With fixed resistance elementA resistance value calculating means for calculating a resistance value of the first transfer means and the second transfer means based on the current value detected by the current detection means;And the output control means includes theResistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means.Determining an output value of the high voltage generating means at the time of image formation, the resistance control means,Resistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means.The resistance value of the variable resistance element at the time of image formation is determined.
[0008]
  In this specification, the image carrier includes a photoconductor and an intermediate transfer belt, and the transfer target includes an intermediate transfer belt, a recording sheet, and the like.For example, if this image forming apparatus performs secondary transfer,The image carrier is a photosensitive member and an intermediate transfer belt, and the transfer member is an intermediate transfer belt and a recording sheet. Further, in this specification, the ground means the ground for the metal part of the image forming apparatus.
[0009]
  In this image forming apparatus, a plurality of toner images carried on a plurality of image carriers are a plurality of toner images.FirstTranscription meansAnd second transfer meansThus, an image is formed by being transferred to the transfer medium. In each transfer unit, the toner image is transferred by the transfer voltage supplied from the high voltage generation unit. Here, the high voltage generating means finally performs transfer.SecondConnected to transfer means. A variable resistance element is connected between the transfer means. When there are two transfer means, there is one variable resistor element, and when there are three or more transfer means, there are two or more variable resistance elements.
[0010]
  As a result, the voltage output from the high voltage generating means is finally transferred.SecondWhile being supplied to the transfer means as it is, it is gradually stepped down by the variable resistance element,FirstSupplied to transfer means. In other words, transfer firstFirstThe smallest transfer voltage is applied to the transfer means, the gradually applied transfer voltage is increased, and finally transfer is performed.SecondThe largest transfer voltage is applied to the transfer means. Thus, the circuit configuration is simplified because the transfer voltage is supplied from one high voltage generating means to a plurality of transfer means.
[0011]
  Then, the output value of the high voltage generating means at the time of image formation is determined based on the current value detected by the current detecting means by the output control means. Further, the resistance value of the variable resistance element at the time of image formation is determined based on the current value detected by the current detection means by the resistance control means.
[0012]
  The image forming apparatus according to the present invention transfers a plurality of image carriers and a toner image carried on the plurality of image carriers to a transfer target., Resistance values are equal to each otherA plurality of transfer means; a variable resistance element that connects adjacent transfer orders among the plurality of transfer means; a resistance control means that controls a resistance value of the variable resistance element; and a plurality of transfer means A high voltage generating means for supplying a transfer voltage to the plurality of transfer means; an output control means for controlling an output value of the high voltage generating means; and Current detecting means for detecting the magnitude of the current flowing into the means, and a fixed resistance element having one end connected to the first transfer means among the plurality of transfer means and the other end groundedA resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means;And the output control means includes theResistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.Determining an output value of the high voltage generating means at the time of image formation, the resistance control means,Resistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.Determine the resistance value of the variable resistance element during image formation,The current detection means includesWhen the output control means outputs a high voltage of a predetermined magnitude from the high voltage generation means, and when the variable resistance element is short-circuited by the resistance control means,in frontThe magnitude of the current flowing into the high voltage generating means may be detected.
[0013]
  From this configuration,This is because the resistance value of each transfer means can be calculated, and the output value of the high voltage generation means and the resistance value of the variable resistance element can be determined based on the resistance value. That is, ATVC control can be performed with high accuracy. As a result, an optimum transfer voltage is applied to each of the plurality of transfer means by one high voltage generating means.When secondary transfer is not performed in this image forming apparatus, the image carrier is a photosensitive member, and the transfer target is a recording sheet.
[0014]
  Here, the reason why the resistance value of each transfer means can be calculated by detecting the magnitude of the current flowing into the high voltage generating means in the above state will be described. In the above state, a constant voltage is applied to each transfer means. For this reason, the current flowing into all the transfer means is the difference between the current flowing into the high voltage generating means and the current flowing through the fixed resistance element whose one end is grounded. If the resistance values of the respective transfer units are considered to be equal, the resistance value of each transfer unit can be calculated from the above-described current relationship.
[0015]
  The image forming apparatus according to the present invention transfers a plurality of image carriers and a toner image carried on the plurality of image carriers to a transfer target., Resistance values are equal to each otherA plurality of first transfer means and the toner image transferred to the transfer target are transferred to the recording medium.The resistance value is equal to one of the plurality of first transfer means.A second voltage transfer unit, a constant voltage element that connects adjacent ones of the plurality of first transfer units, and a second one that performs transfer last among the plurality of first transfer units and the second A variable constant voltage element connecting the transfer means;Constant voltage control means for controlling a constant voltage value of the variable constant voltage element;A high voltage generating means connected to the second transfer means and supplying a transfer voltage to the plurality of first transfer means and the second transfer means; and an output control means for controlling an output value of the high voltage generating means. And a current detecting means for detecting the magnitude of the current flowing into the high voltage generating means, and a fixed one whose one end is connected to the first transferring means among the plurality of first transferring means and whose other end is grounded With resistive elementA resistance value calculating means for calculating a resistance value of the first transfer means and the second transfer means based on the current value detected by the current detection means;And the output control means includes theResistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means.Determines the output value of the high voltage generating means during image formationThe constant voltage control means is stored in advance so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means. Determines the constant voltage value of the variable constant voltage element at the time of image formationIt is characterized byMay.
[0016]
  With this image forming deviceIsThe toner images carried on the plurality of image carriers are transformed into a plurality of first transfer hands.In stepsIs transferred to the transfer target.The toner image transferred to the transfer material is secondarily transferred to the recording material by the second transfer material.As a result, an image is formed. In each transfer unit, the toner image is transferred by the transfer voltage supplied from the high voltage generation unit. Here, the high voltage generating means isThe second2 connected to the transfer means. Also, eachFirstA constant voltage element is connected between the transfer means.A variable constant voltage element is connected between the second transfer means and the first transfer means that performs the last transfer.ing. In addition,FirstWhen there are two transfer means, there is one constant voltage element,FirstWhen there are three or more transfer means, there are two or more constant voltage elements.
[0017]
  As a result, the voltage output from the high voltage generating means isThe second2 While being supplied to the transfer means as it is,Variable voltage element andThe voltage is gradually lowered by the constant voltage element and supplied to each first transfer means. That meansOf the first transfer meansFirst transferthingThe smallest transfer voltage is applied to theSecondaryThe largest transfer voltage is applied to the second transfer means for performing transfer. Thus, the circuit configuration is simplified because the transfer voltage is supplied from one high voltage generating means to a plurality of transfer means.HaveThe
[0018]
  Then, the output value of the high voltage generating means at the time of image formation is determined based on the current value detected by the current detecting means by the output control means.Further, the constant voltage value of the variable constant voltage element at the time of image formation is determined based on the current value detected by the current detection means by the constant voltage control means.
[0019]
  By doing so, the resistance value of each transfer means can be calculated, and the output value of the high voltage generating means can be determined based on the resistance value. That is, ATVC control can be performed with high accuracy. As a result, an optimum transfer voltage is applied to each of the plurality of transfer means by one high voltage generating means.
[0020]
  aboveImage forming apparatus according to the present inventionIn the current detection means, the output control means outputs a high voltage of a predetermined magnitude from the high voltage generation means, and the constant voltage control means causes the variable constant voltage element to be in a specified resistance state. It is desirable to detect the magnitude of current flowing into the high voltage generating means.
[0021]
  With this configuration, the resistance value of each transfer unit can be calculated, and the output value of the high voltage generation unit and the constant voltage value of the variable constant voltage element can be determined based on the resistance value. . That is, ATVC control can be performed with high accuracy. As a result, an optimum transfer voltage is applied to a plurality of transfer means by one high voltage generating means.
[0022]
  In the above-described image forming apparatus, the constant voltage element can be changed to a variable constant voltage element. In this case, the constant voltage value at the time of image formation of the changed variable constant voltage element may be determined by the constant voltage control unit based on the calculated resistance value of the transfer unit. Thereby, ATVC control with higher accuracy becomes possible.
[0023]
  In addition, the image forming apparatus of the present invention includes a plurality of image carriers, a plurality of first transfer units that transfer the toner images carried on the plurality of image carriers to a transfer target, and a transfer to the transfer target. A second transfer means for transferring the toner image to the recording medium, a variable resistance element for connecting the plurality of first transfer means and the second transfer means that are adjacent in the transfer order, and the variable resistance A resistance control means for controlling a resistance value of the element; a high voltage generating means connected to the second transfer means; and supplying a transfer voltage to the plurality of first transfer means and the second transfer means; Output control means for controlling the output value of the voltage generation means, current detection means for detecting the magnitude of the current flowing into the high voltage generation means, and one of the plurality of first transfer means that performs transfer first. Is connected and the other end is grounded. A fixed resistance element, and a resistance value calculating means for calculating a resistance value of the plurality of first transfer means and the second transfer means based on the current value detected by the current detection means, and the output control The means forms an image with a prestored table so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means. An output value of the high voltage generating means at the time, and the resistance control means is suitable for the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means. The resistance value of the variable resistance element at the time of image formation is determined by a pre-stored table so that the transfer voltage can be supplied, and the first transfer means can contact and separate from the image carriers. And the resistance value calculating means is configured so that one of the plurality of first transfer means is in contact with the image carrier and the remaining first transfer means is separated from the image carriers. The detection means detects the magnitude of the current flowing into the high voltage generation means by switching the first transfer means in contact with the image carrier and switching the resistance of each first transfer means. A value may be calculated.
[0024]
  AlsoThe image forming apparatus according to the present invention includes a plurality of image carriers and a plurality of toner images carried on the plurality of image carriers.Roll ofCopying means,in frontMultipleRoll ofConnect copy units that are adjacent in the transfer orderVariable resistanceElement and,in frontVariableresistanceElementalresistanceControl the valueresistanceControl means; andpluralTranscription meansThe last one to be transcribedAnd connected to the pluralityRoll ofSketcherIn stepsHigh voltage generating means for supplying a transfer voltage; output control means for controlling an output value of the high voltage generating means; current detecting means for detecting the magnitude of a current flowing into the high voltage generating means;Roll ofA fixed resistance element having one end connected to the first transfer means to be transferred and the other end grounded;A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means;And the output control means includes theResistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.Determining an output value of the high voltage generating means during image formation;resistanceThe control means isResistance calculationBy means of exitCalculationIssuedresistanceBased on valueIn order to supply an appropriate transfer voltage to the plurality of transfer means, a table stored in advance is used.The variable at the time of image formationresistanceElementalresistanceDetermine the value,The current detection means includesWhen the output control means outputs a high voltage of a predetermined magnitude from the high voltage generation means, and when the variable resistance element is short-circuited by the resistance control means,in frontDetects the magnitude of current flowing into the high voltage generatorThe transfer means can be brought into contact with or separated from the image carriers, and the resistance value calculating means can be configured such that one of the plurality of transfer means comes into contact with the image carrier and the remaining transfer is performed. When the means is separated from each image carrier, the current detector detects the magnitude of the current flowing into the high voltage generator, and the transfer means abutting on the image carrier is switched. To calculate the resistance value of each transfer means.It may be characterized by being put out.
[0025]
  In addition, an image forming apparatus according to the present invention includes a plurality of image carriers, a plurality of first transfer units that transfer the toner images carried on the plurality of image carriers to a transfer target, and the transfer target. A second transfer unit that transfers the transferred toner image to a recording medium, a constant voltage element that connects adjacent ones of the plurality of first transfer units, and a plurality of first transfer units. A variable constant voltage element for connecting the last transfer unit and the second transfer unit, a constant voltage control unit for controlling a constant voltage value of the variable constant voltage element, and a second transfer unit. And a high voltage generation means for supplying a transfer voltage to the plurality of first transfer means and the second transfer means, an output control means for controlling an output value of the high voltage generation means, and a flow into the high voltage generation means Current detector that detects the magnitude of the current A fixed resistance element having one end connected to the first transfer means among the plurality of first transfer means, the other end being grounded, and the current value detected by the current detection means. Resistance value calculating means for calculating the resistance value of the first transfer means and the second transfer means, and the output control means is configured to output the plurality of first transfers based on the resistance value calculated by the resistance value calculation means. An output value of the high voltage generating means at the time of image formation is determined by a table stored in advance so that an appropriate transfer voltage can be supplied to the first transfer means and the second transfer means. Based on the resistance value calculated by the value calculation means, the table at the time of image formation is stored by a prestored table so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means. A constant voltage value of a variable voltage element is determined, and each of the transfer units can be brought into contact with and separated from each of the image carriers, and the resistance value calculating unit is one of the plurality of first transfer units. The current detecting means detects the magnitude of the current flowing into the high voltage generating means in a state where one of them is in contact with the image carrier and the remaining first transfer means are separated from the image carriers. The resistance value of each first transfer unit may be calculated by switching the first transfer unit in contact with the carrier and performing the process on each first transfer unit.
[0026]
  This is because the resistance values can be calculated individually for all the transfer means by sequentially changing the transfer means to be brought into contact with the image carrier with such a configuration. Since the resistance value is calculated individually for each transfer unit, the output value of the high voltage generation unit is set by the output control unit, and the resistance value of the variable resistance element is set by the resistance control unit or variable by the constant voltage control unit. The constant voltage value of the constant voltage means is set with higher accuracy.
[0027]
  Also,An image forming apparatus according to the present invention includes:A plurality of image carriers, a plurality of first transfer means for transferring toner images carried on the plurality of image carriers to a transfer target, and a toner image transferred to the transfer target to a recording member. A second transfer means, a variable resistance element for connecting the plurality of first transfer means and the second transfer means in the order of transfer, and a resistance control means for controlling the resistance value of the variable resistance element A high voltage generating means for supplying a transfer voltage to the plurality of first transfer means and the second transfer means, and an output for controlling an output value of the high voltage generating means. One end is connected to the control means, the current detection means for detecting the magnitude of the current flowing into the high voltage generating means, and the first transfer means that performs the transfer first, and the other end is grounded The fixed resistance element and the current A resistance value calculating unit that calculates a resistance value of the first transfer unit and the second transfer unit based on a current value detected by the output unit; and a driving unit that drives the transfer target; Based on the resistance value calculated by the resistance value calculating means, the control means is configured to generate an image using a table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means. An output value of the high voltage generating means at the time of formation is determined, and the resistance control means is appropriate for the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means A resistance value of the variable resistance element at the time of image formation is determined by a table stored in advance so that a transfer voltage can be supplied, and the transferred body is provided with an insulator in part. The resistance value calculating means drives a part to be transferred by the driving means between one of the plurality of first transfer means and the image carrier corresponding thereto, and a part of the object to be transferred A first transfer that causes the insulator to be intruded when the current detecting means detects the magnitude of the current flowing into the high-voltage generating means in the state in which the insulator provided in the The resistance value of each first transfer unit may be calculated by switching the units and performing each first transfer unit.
[0028]
    The image forming apparatus according to the present invention includes a plurality of image carriers, a plurality of transfer units that transfer the toner images carried on the plurality of image carriers to a transfer target, and the plurality of transfer units. A variable resistance element that connects adjacent ones in the transfer order, a resistance control means that controls the resistance value of the variable resistance element, and a plurality of transfer means that are connected to the one that performs the transfer last, A high voltage generating means for supplying a transfer voltage to the plurality of transfer means; an output control means for controlling an output value of the high voltage generating means; and a current detecting means for detecting the magnitude of a current flowing into the high voltage generating means. A fixed resistance element having one end connected to the first transfer unit among the plurality of transfer units, the other end being grounded, and a current value detected by the current detection unit. Calculate resistance value Resistance value calculating means and a driving means for driving the transfer object, and the output control means is configured to transfer transfer voltages suitable for the plurality of transfer means based on the resistance value calculated by the resistance value calculating means. The output value of the high voltage generation means at the time of image formation is determined by a table stored in advance, and the resistance control means is configured to determine the plurality of values based on the resistance value calculated by the resistance value calculation means. A resistance value of the variable resistance element at the time of image formation is determined by a table stored in advance so that an appropriate transfer voltage can be supplied to the transfer means, and the current detection means is configured to output the high voltage by the output control means. When a high voltage of a predetermined magnitude is output from the generating means, and the variable resistance element is short-circuited by the resistance control means, an electric current flowing into the high voltage generating means is output. The transfer object is provided with an insulator in part, and the resistance value calculation means includes one of the plurality of transfer means and the image carrier corresponding thereto. In between, the drive means drives the transferred body to bite an insulator provided in a part of the transferred body, and the current detection means holds the high voltage in the held state. The resistance value of each transfer unit is calculated by detecting the magnitude of the current flowing into the generation unit by switching the transfer unit that engages the insulator with respect to each transfer unit. There may be.
[0029]
  Also,An image forming apparatus according to the present invention includes:A plurality of image carriers, a plurality of first transfer means for transferring toner images carried on the plurality of image carriers to a transfer target, and a toner image transferred to the transfer target to a recording member. A second voltage transfer unit, a constant voltage element that connects adjacent ones of the plurality of first transfer units, and a second one that performs transfer last among the plurality of first transfer units and the second A variable constant voltage element connected to the transfer means, a constant voltage control means for controlling a constant voltage value of the variable constant voltage element, connected to the second transfer means, the plurality of first transfer means, High voltage generation means for supplying a transfer voltage to the second transfer means, output control means for controlling the output value of the high voltage generation means, and current detection means for detecting the magnitude of the current flowing into the high voltage generation means; Among the plurality of first transfer means Based on the fixed resistance element having one end connected to the first transferer and the other end grounded, and the resistance of the first transfer unit and the second transfer unit based on the current value detected by the current detection unit A resistance value calculating unit that calculates a value; and a driving unit that drives the transfer object, wherein the output control unit is configured to perform the plurality of first transfer operations based on the resistance value calculated by the resistance value calculating unit. An output value of the high voltage generating means at the time of image formation is determined by a table stored in advance so that an appropriate transfer voltage can be supplied to the first transfer means and the second transfer means. Based on the resistance value calculated by the value calculating means, a pre-stored table is used to supply an appropriate transfer voltage to the plurality of first transfer means and the second transfer means. A constant voltage value of a variable constant voltage element is determined, the transferred body is provided with an insulator in part, and the resistance value calculating means includes one of the plurality of first transfer means and The transfer member is driven by the driving means between the corresponding image carrier and the insulator provided in a part of the transfer member is engaged, and the engagement is performed in the state where the insulator is engaged. By detecting the magnitude of the current flowing into the high voltage generation means by the current detection means for each first transfer means by switching the first transfer means for engaging the insulator, each first transfer means The resistance value may be calculated.
[0030]
  With such a configuration, the insulator can be sequentially inserted between one of the plurality of transfer units and the corresponding image carrier. Then, by detecting the magnitude of the current flowing into the high voltage generator in each state by the current detection means, the detected current, the current flowing through the fixed resistance element, and the current flowing into the transfer means (individually for each transfer means) (The resistance value is an unknown)) is established for the number of transfer means. Accordingly, the individual resistance values of the respective transfer units can be calculated by solving these relational expressions simultaneously. Therefore, the setting of the output value of the high voltage generating means by the output control means, the setting of the resistance value of the variable resistance element by the resistance control means, or the setting of the constant voltage value of the variable constant voltage means by the constant voltage control means is performed with higher accuracy. Is called.
[0031]
  In addition, an image forming apparatus according to the present invention includes a plurality of image carriers, a plurality of first transfer units that transfer the toner images carried on the plurality of image carriers to a transfer target, and the transfer target. Second transfer means for transferring the transferred toner image to the recording medium, and the plurality of first transfer means and the second transfer means that are adjacent in the transfer orderAnd a first transfer means among the plurality of first transfer means and a grounding pointConnectpluralWith variable resistance element,in frontRecordpluralVariable resistance elementOf childResistance control means for controlling each resistance value, high voltage generating means connected to the second transfer means and supplying transfer voltages to the plurality of first transfer means and the second transfer means, and the high voltage Output control means for controlling the output value of the generating means, and current detecting means for detecting a current value flowing into the high voltage generating means,A resistance value calculating means for calculating a resistance value of the first transfer means and the second transfer means based on the current value detected by the current detection means;And the output control means includes theResistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.Determining an output value of the high voltage generating means at the time of image formation, the resistance control means,Resistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.Determination of the resistance value of the first variable resistance element during image formationThe resistance value calculating means outputs a voltage of a predetermined magnitude from the high voltage generating means by the output control means, and one of the plurality of variable resistance elements by the resistance control means is a specified resistance. When each of the variable resistance elements is switched to a prescribed resistance state, the current detection means detects the magnitude of the current flowing into the high voltage generation means when the other state is short-circuited. By calculating the resistance value of each transfer meansIt is characterized byMay.
[0032]
  Also in this image forming apparatus, an image is formed by transferring toner images carried on a plurality of image carriers to a transfer target by a plurality of first transfer means and second transfer means. In each transfer unit, the toner image is transferred by the transfer voltage supplied from the high voltage generation unit. Here, the high voltage generating means is connected to the second transfer means for performing the transfer last. Also, between each transfer meansYesA variable resistance element is connected. If there are two transfer means,thisIf there is one variable resistance element and there are 3 or more transfer means,thisThere are two or more variable resistance elements.
[0033]
  As a result, the voltage output from the high voltage generating means is supplied to the second transfer means that performs the transfer at the end.YesThe voltage is gradually lowered by the variable resistance element and supplied to each first transfer means. That is, the lowest transfer voltage is applied to the first transfer unit that performs the transfer first, the transfer voltage that is gradually applied increases, and the highest transfer voltage is applied to the second transfer unit that performs the transfer last. Thus, the circuit configuration is simplified because the transfer voltage is supplied from one high voltage generating means to a plurality of transfer means.
[0034]
  Then, the output value of the high voltage generating means at the time of image formation is determined based on the current value detected by the current detecting means by the output control means. It can also be used during image formation.PossibleThe resistance value of the variable resistance element is determined based on the current value detected by the current detection means by the resistance control means.
[0035]
  Here, an image forming apparatus according to the present invention includes a plurality of image carriers, a plurality of transfer units that transfer the toner images carried on the plurality of image carriers to a transfer target, and a plurality of transfer units. Out of which the transfer order is adjacentAnd, among the plurality of transfer means, the first transfer means and the grounding pointConnectpluralWith variable resistance element,in frontRecordpluralVariable resistance elementOf childA resistance control means for controlling each resistance value; a high voltage generating means for supplying a transfer voltage to the plurality of transfer means; and a high voltage generation means connected to the last transfer means among the plurality of transfer means; Output control means for controlling the output value of the generating means, and current detecting means for detecting a current value flowing into the high voltage generating means,A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means;And the output control means includes theResistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.Determining an output value of the high voltage generating means at the time of image formation, the resistance control means,Resistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.The above during image formationpluralDetermine the resistance value of the variable resistance element,The resistance value calculating means includesThe output control means outputs a voltage of a predetermined magnitude from the high voltage generation means, and the resistance control meanspluralVariable resistance elementOf childAmong them, when one is in a specified resistance state and the other is in a short circuit state, the current detection means detects the magnitude of the current flowing into the high voltage generation means.This is performed for each variable resistance element by switching the variable resistance element in the specified resistance state, thereby calculating the resistance value of each transfer means.It may be characterized by that.
[0036]
  This is because the current flowing into each transfer means can be calculated if the current detecting means detects the magnitude of the current flowing into the high voltage generator by sequentially switching the variable resistance elements to be in the specified resistance state. . Since the magnitude of the current flowing into each transfer unit is calculated in this way, the resistance value of each transfer unit can be calculated. Therefore, the setting of the output value of the high voltage generation means by the output control means and the resistance control meansPossibleThe resistance value of the variable resistance element is set with higher accuracy.
[0037]
  In the image forming apparatus described above, the voltage value output from the high voltage generator is controlled during image formation. However, the same effect can be obtained by controlling the current value. In this case, the output voltage may be detected instead of detecting the current flowing into the high voltage generator. Further, instead of detecting the magnitude of the current flowing into the high voltage generating means with the current detecting means, the magnitude of the current flowing out from the high voltage generating means may be detected.
  The image forming apparatus according to the present invention includes a plurality of image carriers, a plurality of transfer units that transfer the toner images carried on the plurality of image carriers to a transfer target, and the plurality of transfer units. A variable resistance element that connects adjacent ones in the transfer order, a resistance control means that controls the resistance value of the variable resistance element, and a plurality of transfer means that are connected to the one that performs the transfer last, A high voltage generating means for supplying a transfer voltage to the plurality of transfer means; an output control means for controlling an output value of the high voltage generating means; and a current detecting means for detecting the magnitude of a current flowing into the high voltage generating means. A fixed resistance element having one end connected to the first transfer unit among the plurality of transfer means and the other end grounded;A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means;And the output control means includes theResistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.Determining an output value of the high voltage generating means at the time of image formation, the resistance control means,Resistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.The resistance value of the variable resistance element at the time of image formation is determined, and each of the transfer units can contact and separate from each of the image carriers,The resistance value calculating means includesThe magnitude of the current that the current detection means flows into the high voltage generating means in a state where one of the plurality of transfer means is in contact with the image carrier and the remaining transfer means are separated from the image carriers. DetectThe resistance value of each transfer unit is calculated by switching the transfer unit that contacts the image carrier and switching the transfer unit.It may be characterized by that.
  Alternatively, the image forming apparatus according to the present invention includes a plurality of image carriers, a plurality of transfer units that transfer the toner images carried on the plurality of image carriers to a transfer target, and the plurality of transfer units. A constant voltage element that connects adjacent ones in transfer order, and a high voltage generating means that is connected to one of the plurality of transfer means that performs transfer last and supplies a transfer voltage to the plurality of transfer means Output control means for controlling the output value of the high voltage generation means, current detection means for detecting the magnitude of the current flowing into the high voltage generation means, and first transfer of the plurality of transfer means A fixed resistance element having one end connected to the other end and the other end groundedA resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means;And the output control means includes theResistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.The output value of the high voltage generating means at the time of image formation is determined, and each of the transfer means can contact and separate from each of the image carriers,The resistance value calculating means includesThe magnitude of the current that the current detection means flows into the high voltage generating means in a state where one of the plurality of transfer means is in contact with the image carrier and the remaining transfer means are separated from the image carriers. DetectThe resistance value of each transfer unit is calculated by switching the transfer unit that contacts the image carrier and switching the transfer unit.It may be characterized by that.
  Furthermore, an image forming apparatus according to the present invention includes a plurality of image carriers, a plurality of transfer units that transfer the toner images carried on the plurality of image carriers to a transfer target, and the plurality of transfer units. A variable resistance element that connects adjacent ones in the transfer order, a resistance control means that controls the resistance value of the variable resistance element, and a plurality of transfer means that are connected to the one that performs the transfer last, A high voltage generating means for supplying a transfer voltage to the plurality of transfer means; an output control means for controlling an output value of the high voltage generating means; and a current detecting means for detecting the magnitude of a current flowing into the high voltage generating means. A fixed resistance element having one end connected to the first transfer unit among the plurality of transfer means and the other end grounded;A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means;Drive means for driving the transfer object, and the output control meansResistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.Determining an output value of the high voltage generating means at the time of image formation, the resistance control means,Resistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.Determine the resistance value of the variable resistance element during image formation,The transferred object is provided with an insulator in part, and the resistance value calculating means includes:Between the one of the plurality of transfer units and the image carrier corresponding thereto, the transfer unit is driven by the driving unit and an insulator provided in a part of the transfer unit is engaged. However, the current detecting means detects the magnitude of the current flowing into the high voltage generating means in the state of being bitten.The resistance value of each first transfer unit is calculated by switching the first transfer unit that bites the insulator and switching the first transfer unit.It may be characterized by that.
  Alternatively, the image forming apparatus according to the present invention includes a plurality of image carriers, a plurality of transfer units that transfer the toner images carried on the plurality of image carriers to a transfer target, and the plurality of transfer units. A constant voltage element that connects adjacent ones in transfer order, and a high voltage generating means that is connected to one of the plurality of transfer means that performs transfer last and supplies a transfer voltage to the plurality of transfer means Output control means for controlling the output value of the high voltage generation means, current detection means for detecting the magnitude of the current flowing into the high voltage generation means, and first transfer of the plurality of transfer means A fixed resistance element having one end connected to the other end and the other end groundedA resistance value calculating means for calculating a resistance value of the transfer means based on a current value detected by the current detecting means; and a drive means for driving the transfer object;And the output control means includes theResistance calculationBy means of exitCalculationIssuedresistanceBased on the valueA table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer means.Determine the output value of the high voltage generating means at the time of image formation,The transferred object is provided with an insulator in part, and the resistance value calculating means includes:Between the one of the plurality of transfer units and the image carrier corresponding thereto, the transfer unit is driven by the driving unit and an insulator provided in a part of the transfer unit is engaged. However, the current detecting means detects the magnitude of the current flowing into the high voltage generating means in the state of being bitten.The resistance value of each first transfer unit is calculated by switching the first transfer unit that bites the insulator and switching the first transfer unit.It may be characterized by that.
[0038]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, a most preferred embodiment in which the image forming apparatus of the present invention is embodied will be described in detail with reference to the drawings. In this embodiment, the image forming apparatus according to the present invention is applied to a tandem digital printer that prints a full-color image on recording paper based on an image signal.
[0039]
(First embodiment)
  First, the first embodiment will be described. The main part of the printer according to the first embodiment is shown in FIG. As shown in FIG. 1, this printer is configured around photoconductor drums 11Y, 11M, 11C, and 11K arranged in parallel along the transfer belt 20. Here, YMCK is a color code indicating a reproduced color, Y is yellow, M is magenta, C is cyan, and K is black.
[0040]
  Around the photosensitive drums 11Y, 11M, 11C, and 11K, image forming units 12Y, 12M, 12C, and 12K that form toner images of the respective colors on the photosensitive drums 11Y, 11M, 11C, and 11K, and their toners Transfer rollers 13 </ b> Y, 13 </ b> M, 13 </ b> C, 13 </ b> K and the like for sequentially transferring images onto the transfer belt 20 are disposed. Each color image forming unit includes a known charging charger, an optical system, a developing device, and the like.
[0041]
  The transfer belt 20 travels in the direction of the arrow in the drawing by the rotational drive of the drive roller 21, and is an endless belt wound around the drive roller 21 and the two driven rollers 22 and 23. A secondary transfer roller 14 that performs secondary transfer is disposed to face the roller 22 with the transfer belt 20 interposed therebetween.
[0042]
  Here, a circuit for supplying a transfer voltage to each of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14 will be described. As shown in FIG. 1, this circuit supplies a transfer voltage from one high voltage generator 30 to each of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14. That is, the circuit is simplified without providing a high-voltage power supply for each transfer roller.
[0043]
  Specifically, a variable resistance element 31 is connected between the transfer rollers 13Y and 13M, a variable resistance element 32 is connected between the transfer rollers 13M and 13C, and a variable resistance is connected between the transfer rollers 13C and 13K. An element 33 is connected, and a variable resistance element 34 is connected between the transfer roller 13K and the secondary transfer roller 14. A fixed resistance element 35 whose other end is grounded is also connected to the transfer roller 13Y. One end of the high voltage generator 30 is connected to the secondary transfer roller 14 and the variable resistance element 34. The other end of the high voltage generator 30 is connected to a fixed resistance element 36 having one end grounded via a power source 37. The power source 37 is for generating a negative voltage necessary for performing the cleaning process of the secondary transfer roller 14, and does not supply a transfer voltage. With such a circuit configuration, a transfer voltage is supplied from the high voltage generator 30 to each of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14.
[0044]
  The resistance values of the variable resistance elements 31 to 34 provided in the above-described circuit and the output voltage value from the high voltage generator 30 are controlled by the CPU 40 via the AD converter 41, respectively. . Further, the voltage value at the point A is input to the CPU 40 via the DA converter 42 in order to detect the current I1 flowing into the high voltage generator 30 (current flowing at the point A) I1. As a result, the CPU 40 controls the resistance values of the variable resistance elements 31 to 34 and the output voltage value from the high voltage generator 30 based on the current I1, and as a result, the transfer rollers 13Y, 13M, 13C, 13K, and An appropriate transfer voltage is supplied to the secondary transfer roller 14. Details of the control contents will be described later.
[0045]
  Next, an image forming process in the printer according to the present embodiment will be briefly described. First, the surfaces of the photosensitive drums 11Y, 11M, 11C, and 11K are uniformly charged by the charging chargers provided in the image forming units 12Y, 12M, 12C, and 12K. Next, exposure scanning with laser light controlled in accordance with each reproduction color is performed based on the image signal by each optical system provided in the image forming units 12Y, 12M, 12C, and 12K. By such exposure, electrostatic latent images corresponding to the respective reproduction colors are written on the respective photosensitive drums 11Y, 11M, 11C, and 11K. Subsequently, these electrostatic latent images are developed into toner images of the respective colors by the developing devices provided in the image forming units 12Y, 12M, 12C, and 12K and incorporating the toners of the respective reproduction colors.
[0046]
  These toner images are sequentially transferred onto the transfer belt 20 by transfer rollers 13Y, 13M, 13C, and 13K. Thereafter, the superimposed toner images are transferred to the recording paper 15 by the secondary transfer roller 14. Thereafter, the toner image transferred onto the recording paper 15 is subjected to a fixing process using a heating roller. By this processing, the toner image is melted to be a full color image and fixed on the recording paper 15. Thus, the image formation for one sheet is completed.
[0047]
  Here, in order to obtain a high-quality image, it is necessary that the transfer by the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 be performed satisfactorily. That is, it is necessary to supply an appropriate transfer voltage from the high voltage generator 30 to each of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14. Therefore, in the printer according to the present embodiment, as shown below, the resistance values of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 are calculated, whereby the transfer rollers 13Y, 13M, An appropriate transfer voltage is supplied to 13C, 13K, and the secondary transfer roller 14. A process for calculating the resistance values of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14 will be described in detail with reference to the flowchart shown in FIG. In the present embodiment, the resistance values of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 are all the same.
[0048]
  First, yellow, magenta, cyan, and black image forming units 12Y, 12M, 12C, and 12K, photosensitive drums 11Y, 11M, 11C, and 11K, transfer rollers 13Y, 13M, 13C, and 13K, and a driving roller 21 (transfer) The belt 20) and the secondary transfer roller 14 are driven (S1). At this time, in each of the image forming units 12Y, 12M, 12C, and 12K, the charging charger is turned on, and the entire surface of the photosensitive drum is exposed by the optical system. The developing device is in an off state.
[0049]
  Next, according to a command from the CPU 40, the variable resistance elements 31 to 34 are short-circuited (S2), and a voltage of 2 kV is output from the high voltage generator 30 (S3). At this time, since the variable resistance elements 31 to 34 are short-circuited, a voltage of 2 kV is applied to each of the transfer rollers 13Y, 13M, 13C, and 13K, and the secondary transfer roller 14.
[0050]
  In this state, the following processing is performed to detect the current flowing through point A. First, the sampling timer is reset to sample the voltage value at point A (S4). Then, it is confirmed whether or not the sampling timer is up (S5). At this time, if the sampling timer is not yet up (S5: NO), it waits until it is up. On the other hand, if the sampling timer is up (S5: YES), the process proceeds to S6.
[0051]
  When the sampling timer is up, sampling of the voltage value at point A is started (S6). Note that the sampled data is sequentially stored in a memory provided in the printer. Thereafter, it is determined whether or not the transfer belt 20 has made a round after starting sampling of the voltage value at the point A (S7). If the circuit has made a round (S7: YES), sampling is terminated and the process proceeds to S8. On the other hand, if the circuit has not made one round (S7: NO), the process returns to S4 and sampling of the voltage value is continued.
[0052]
  Then, when the transfer belt 20 makes a round and sampling of the voltage value at the point A is completed, the CPU 40 calculates the average of the sampled voltage values (S8). Then, a current I1 flowing through the point A is calculated from the calculated average voltage value. Since the resistance value of the fixed resistance element 36 provided for current detection is known, the current flowing through the point A can be calculated. If the current flowing through the fixed resistance element 35 is I2 (known), the sum of the currents flowing into the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 is “I1-I2”. . As described above, since the resistance values of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14 are all equal, the transfer rollers 13Y, 13M, 13C, 13K, and The resistance value R of the secondary transfer roller 14 is calculated (S9).
  I1-I2 = 2000 / (R / 5) (1)
The current I2 is I2 = 2000 / R2 when the resistance value of the fixed resistance element 35 is R2.
[0053]
  When the resistance values R of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 are calculated, the image forming units 12Y, 12M, 12C, and 12K and the photosensitive drums 11Y, 11M, 11C, and 11K are calculated. The transfer rollers 13Y, 13M, 13C, and 13K, the drive roller 21 (transfer belt 20), and the secondary transfer roller 14 are stopped (S10). In this way, the circuit configuration is simplified by supplying the transfer voltage from one high voltage generator 30 to each of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14. In addition, the resistance value R of each of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 can be detected.
[0054]
  Then, the calculated resistance value R so that an appropriate transfer voltage can be supplied from the high voltage generator 30 to each of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14 during image formation. Based on the above, the voltage value of the high-voltage generator 30 and the resistance values of the variable resistance elements 31 to 34 are determined. Specifically, first, based on the calculated resistance value R, the voltage value of the high voltage generator 30 is determined by a table stored in advance in the printer. In addition, you may correct | amend with the environmental data (temperature, humidity, etc.) with a well-known method with respect to the voltage value determined here. Next, based on the resistance value R, each resistance value of each of the variable resistance elements 31 to 34 is determined by a table stored in advance in the printer. Note that each resistance value determined here may be corrected by environmental data (temperature, humidity, etc.) or data relating to each transfer roller by a known method.
[0055]
  Thereafter, when an image forming process is performed by the image forming units 12Y, 12M, 12C, and 12K, a full-color image is formed as described above. At this time, the voltage value of the high voltage generator 30 and the resistance values of the variable resistance elements 31 to 34 are set to the values determined as described above. In this state, the voltage output from the high voltage generator 30 is applied to the secondary transfer roller 14, and the respective voltages obtained by stepping down the voltages by the variable resistance elements 34, 33, 32, and 31 are sequentially applied. And applied to the transfer rollers 13K, 13C, 13M, and 13Y. That is, the transfer voltage of the secondary transfer roller 14 is the highest, and the transfer rollers 13K, 13C, 13M, and 13Y decrease in this order. This is because, on the downstream side of the transfer belt 20, it is necessary to sequentially transfer the toner image on the toner image transferred on the upstream side, so that the voltage value required for transfer is increased. is there. As described above, since an appropriate transfer voltage is applied to each of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14, a high-quality image can be obtained.
[0056]
  As described above in detail, in the printer according to the first embodiment, the high voltage generator 30 is connected to the secondary transfer roller 14 that performs transfer last, and a variable resistance is provided between the transfer rollers. Elements 31 to 34 are connected. As a result, the voltage output from the high voltage generator 30 is applied to the secondary transfer roller 14 as it is, and the voltage is gradually lowered by the variable resistance elements 34 to 31 to the transfer rollers 13K, 13C, 13M, and 13Y. Applied. That is, the smallest transfer voltage is applied to the transfer roller 13Y that performs the transfer first, the gradually applied transfer voltage is increased, and the largest transfer voltage is applied to the secondary transfer roller. As described above, the circuit configuration for supplying the transfer voltage from one high voltage generator to a plurality of transfer rollers is simplified.
[0057]
  Further, when a voltage of 2 kV is output from the high voltage generator 30 and all the variable resistance elements 31 to 34 are short-circuited, the current value at the point A is detected. Then, the resistance value R of each transfer roller is calculated from the above equation (1). Then, based on the resistance value R, the output voltage value of the high voltage generator 30 during image formation and the resistance values of the variable resistance elements 31 to 34 are determined, and image formation is performed. Therefore, an optimum transfer voltage is applied from the high voltage generator 30 to each of the plurality of transfer rollers during image formation. As a result, a high quality image is formed.
[0058]
  In the first embodiment, the printer configured to perform the secondary transfer has been described. Of course, the configuration in which the secondary transfer is not performed and the photosensitive drums 11Y, 11M, 11C, and 11K are directly transferred to the recording paper. The present invention can be applied to any printer. In this case, in FIG. 1, the secondary transfer roller 14, the wiring to the secondary transfer roller 14, the cleaning power source 37, and the variable resistance element 34 are unnecessary. As a result, the circuit that supplies the transfer voltage from the high voltage generator 30 to the transfer rollers 13K, 13C, 13M, and 13Y has a circuit configuration as shown in FIG. In the circuit shown in FIG. 3, by performing the above-described control, an appropriate transfer voltage can be supplied from the single high power generation device 30 to each of the transfer rollers 13K, 13C, 13M, and 13Y. The equation (1) for calculating the resistance value R of each transfer roller is the following equation (2).
  I1-I2 = 2000 / (R / 4) (2)
[0059]
(Second Embodiment)
  Next, a second embodiment will be described. The printer according to the second embodiment has substantially the same configuration as the printer according to the first embodiment. However, as shown in FIG. 4, each transfer roller 53Y, 53M, 53C, 53K is transferred. The difference is that each of the photosensitive drums 11Y, 11M, 11C, and 11K can be contacted and separated via the belt 20. In order to simplify the description, the present embodiment exemplifies a printer having a configuration that does not perform secondary transfer. The same components as those in the first embodiment are denoted by the same reference numerals in FIG.
[0060]
  The processing contents for detecting the resistance values of the transfer rollers 53Y, 53M, 53C, and 53K are slightly different with the difference in configuration from the first embodiment. In the present embodiment, each transfer roller 53Y, 53M, 53C, 53K can be brought into contact with or separated from each photoconductor drum 11Y, 11M, 11C, 11K via the transfer belt 20, so that each transfer roller The individual resistance values of 53Y, 53M, 53C, and 53K can be detected.
[0061]
  A process for detecting individual resistance values of the transfer rollers 53Y, 53M, 53C, and 53K will be described with reference to the flowchart shown in FIG. First, the yellow, magenta, cyan, and black image forming units 12Y, 12M, 12C, and 12K, the photosensitive drums 11Y, 11M, 11C, and 11K, the transfer rollers 53Y, 53M, 53C, and 53K, and the drive roller 21 ( The transfer belt 20) is driven (S11). At this time, in each of the image forming units 12Y, 12M, 12C, and 12K, the charging charger is turned on, and the entire surface of the photosensitive drum is exposed by the optical system. The developing device is in an off state.
[0062]
  Next, in response to a command from the CPU 40, the variable resistance elements 31 to 33 are short-circuited (S12), and a voltage of 2 kV is output from the high voltage generator 30 (S13). At this time, since the variable resistance elements 31 to 33 are short-circuited, a voltage of 2 kV is applied to each of the transfer rollers 53Y, 53M, 53C, and 53K.
[0063]
  Then, the transfer rollers 53Y, 53M, and 53C for yellow, magenta, and cyan are separated from the photosensitive drums 12Y, 12M, and 12C. That is, only the black transfer roller 53K is brought into pressure contact with the photosensitive drum 11K via the transfer belt 20 (S14). As a result, current flows only through the transfer roller 53K. In this state, the following processing is performed to detect the current flowing through point A. First, the sampling timer is reset to sample the voltage value at point A (S15). Then, it is confirmed whether or not the sampling timer is up (S16). At this time, if the sampling timer is not yet up (S16: NO), it waits until it is up. On the other hand, if the sampling timer is up (S16: YES), the process proceeds to S17.
[0064]
  When the sampling timer is up, sampling of the voltage value at the point A is started (S17). Note that the sampled data is sequentially stored in a memory provided in the printer. Thereafter, it is determined whether or not the transfer belt 20 has made a round after starting sampling of the voltage value at the point A (S18). If the circuit has made a round (S18: YES), sampling is terminated and the process proceeds to S19. On the other hand, if the circuit has not made one round (S18: NO), the process returns to S15 to continue sampling of the voltage value.
[0065]
  Then, when the transfer belt 20 goes around and sampling of the voltage value at the point A is completed, the CPU 40 calculates the average of the sampled voltage values (S19). Then, a current I1 flowing through the point A is calculated from the calculated average voltage value. Since the resistance value of the fixed resistance element 36 provided for current detection is known, the current flowing through the point A can be calculated. When the current flowing through the fixed resistance element 35 is I2 (known), the current flowing through each transfer roller 53K is “I1-I2”. Accordingly, the resistance value RK of the transfer roller 53K is calculated by the following equation (S20).
  I1-I2 = 2000 / RK (3)
The current I2 is I2 = 2000 / R2 when the resistance value of the fixed resistance element 35 is R2.
[0066]
  Thereafter, it is confirmed whether or not the resistance values of all the transfer rollers have been calculated (S21). If the resistance values of all the transfer rollers have not been calculated (S21: NO), the transfer roller that is in pressure contact with the photosensitive drum via the transfer belt 20 is switched (S22), and the processes of S15 to S20 are performed. repeat. That is, the resistance values RC, RM, and RY of the transfer rollers 53C, 53M, and 53Y are calculated in the order of the transfer rollers 53C, 53M, and 53Y based on the above equation (3). The order in which the transfer roller is pressed against the photosensitive drum via the transfer belt 20 does not matter. Therefore, it may be out of the order described above.
[0067]
  When the resistance values RK, RC, RM, and RY of all the transfer rollers 53Y, 53M, 53C, and 53K are calculated in this way (S21: YES), the image forming units 12Y, 12M, 12C, and 12K, and the respective photosensitive members are detected. The body drums 11Y, 11M, 11C, and 11K, the transfer rollers 53Y, 53M, 53C, and 53K, and the drive roller 21 (transfer belt 20) are stopped (S23). As described above, even if the circuit configuration is simplified by supplying the transfer voltage from one high voltage generator 30 to each of the transfer rollers 53Y, 53M, 53C, and 53K, the transfer rollers 53Y, The individual resistance values RY, RM, RC, and RK of 53M, 53C, and 53K can be detected.
[0068]
  Then, the calculated resistance values RY, RM, RC, RK so that an appropriate transfer voltage can be supplied from the high voltage generator 30 to the transfer rollers 53Y, 53M, 53C, 53K during image formation. Based on the above, the voltage value of the high voltage generator 30 and the resistance values of the variable resistance elements 31 to 33 are determined. Specifically, first, based on the calculated resistance value RK, the voltage value of the high voltage generator 30 is determined by a table stored in advance in the printer. In addition, you may correct | amend with the environmental data (temperature, humidity, etc.) with a well-known method with respect to the voltage value determined here.
[0069]
  Next, based on the resistance values RC, RM, and RY, the resistance values of the variable resistance elements 33, 32, and 31 are determined by a table stored in advance in the printer. That is, the resistance value of the variable resistance element 33 is determined based on the resistance value RC, the resistance value of the variable resistance element 32 is determined based on the resistance value RM, and the resistance value of the variable resistance element 31 is determined based on the resistance value RY. . Note that each resistance value determined here may be corrected by environmental data (temperature, humidity, etc.) or data relating to each transfer roller by a known method.
[0070]
  Thereafter, when an image forming process is performed by the image forming units 12Y, 12M, 12C, and 12K, a full-color image is formed as described above. At this time, the voltage value of the high voltage generator 30 and the resistance values of the variable resistance elements 31 to 33 are set to the values determined as described above. In this state, the voltage output from the high voltage generator 30 is applied as it is to the transfer roller 53K, and the respective voltages obtained by stepping down the voltages in turn by the variable resistance elements 33, 32, 31 are transferred to the transfer roller 53K. Applied to 53C, 53M, and 53Y. That is, the transfer voltage of the transfer roller 53K is the highest, and thereafter the transfer rollers 53C, 53M, and 53Y decrease in this order. This is because, on the downstream side of the transfer belt 20, it is necessary to sequentially transfer the toner image on the toner image transferred on the upstream side, so that the voltage value required for transfer is increased. is there.
[0071]
  Thus, since an appropriate transfer voltage is applied to each of the transfer rollers 53Y, 53M, 53C, and 53K, a high-quality image can be obtained. Furthermore, since individual resistance values of the transfer rollers 53Y, 53M, 53C, and 53K are detected, a more appropriate transfer voltage is applied to each of the transfer rollers 53Y, 53M, 53C, and 53K.
[0072]
  As described above in detail, according to the printer according to the second embodiment, as in the first embodiment, the high voltage generator 30 applies the transfer rollers 53K, 53C, 53M, and 53Y to each of the transfer rollers 53K, 53C, 53M, and 53Y. A transfer voltage is supplied. The transfer rollers 53Y, 53M, 53C, and 53K can be brought into contact with and separated from the photosensitive drums 11Y, 11M, 11C, and 11K via the transfer belt 20. Accordingly, the individual resistance values RK, RC, RM, RY of the transfer rollers 53K, 53C, 53M, 53Y can be calculated based on the above equation (3). Then, based on these resistance values, the output voltage value of the high voltage generator 30 at the time of image formation and the resistance values of the variable resistance elements 31 to 33 are determined, and image formation is performed. Therefore, an optimum transfer voltage is applied from the high voltage generator 30 to each of the plurality of transfer rollers during image formation. As a result, a high quality image is formed.
[0073]
(Third embodiment)
  Next, a third embodiment will be described. The printer according to the third embodiment has substantially the same configuration as the printer according to the first embodiment, but as shown in FIG. Is different. The insulating portion 51 is large enough to electrically insulate the pair of photosensitive drums from the transfer roller. In order to simplify the description, the present embodiment also exemplifies a printer that does not perform secondary transfer. The same components as those in the first embodiment are denoted by the same reference numerals in FIG.
[0074]
  The processing contents for detecting the resistance values of the transfer rollers 13Y, 13M, 13C, and 13K are slightly different with the difference in configuration from the first embodiment. In the present embodiment, the individual resistances of the transfer rollers 13Y, 13M, 13C, and 13K can be detected as in the second embodiment.
[0075]
  A process for detecting individual resistance values of the transfer rollers 13Y, 13M, 13C, and 13K will be described with reference to the flowchart shown in FIG. First, yellow, magenta, cyan, and black image forming units 12Y, 12M, 12C, and 12K, photosensitive drums 11Y, 11M, 11C, and 11K, transfer rollers 13Y, 13M, 13C, and 13K, and a driving roller 21 (transfer) The belt 50) is driven (S31). At this time, in each of the image forming units 12Y, 12M, 12C, and 12K, the charging charger is turned on, and the entire surface of the photosensitive drum is exposed by the optical system. The developing device is in an off state.
[0076]
  Next, the variable resistance elements 31 to 33 are short-circuited by a command from the CPU 40 (S32), and a voltage of 2 kV is output from the high voltage generator 30 (S33). At this time, since the variable resistance elements 31 to 33 are short-circuited, a voltage of 2 kV is applied to each of the transfer rollers 13Y, 13M, 13C, and 13K.
[0077]
  In this state, the insulating portion 51 provided on the transfer belt 50 is engaged between the yellow transfer roller 13Y and the photosensitive drum 11Y (S34). Then, the image forming units 12Y, 12M, 12C, and 12K, the photosensitive drums 11Y, 11M, 11C, and 11K, the transfer rollers 13Y, 13M, 13C, and 13K, and the driving roller 21 (transfer belt 50) are stopped (S35). ). Subsequently, the following processing is performed in order to detect the current flowing through the point A at this time. First, the sampling timer is reset to sample the voltage value at point A (S36). Then, it is confirmed whether or not the sampling timer is up (S37). At this time, if the sampling timer is not yet up (S37: NO), it waits until it is up. On the other hand, if the sampling timer is up (S37: YES), the process proceeds to S38.
[0078]
  When the sampling timer is up, the voltage value at point A is sampled (S38). Then, a current I1 flowing through point A is calculated from the detected voltage value. Since the resistance value of the fixed resistance element 36 provided for current detection is known, the current flowing through the point A can be calculated. Here, if the resistance values of the transfer rollers 13M, 13C, and 13K are RM, RC, and RK, the currents flowing through the transfer rollers 13M, 13C, and 13K are 2000 / RM, 2000 / RC, and 2000 / RK. When the current flowing through the fixed resistance element 35 is I2 (known), the following equation is established.
  I1-I2 = 2000 / RM + 2000 / RC + 2000 / RK (4)
The current I2 is I2 = 2000 / R2 when the resistance value of the fixed resistance element 35 is R2.
[0079]
  Subsequently, it is confirmed whether or not the insulating portion 51 has been bitten with respect to all the transfer rollers 13Y, 13M, 13C, and 13K (S39). Here, when the process of engaging the insulating portion 51 with respect to all the transfer rollers 13Y, 13M, 13C, and 13K is not completed (S39: NO), the image forming units 12Y, 12M, 12C, and 12K, The photosensitive drums 11Y, 11M, 11C, and 11K, the transfer rollers 13Y, 13M, 13C, and 13K, and the drive roller 21 (transfer belt 50) are driven again (S40). Then, the transfer roller for biting the insulating portion 51 is switched (S41), and the processes of S35 to S38 are repeated. Here, in a state where the insulating portion 51 is engaged between the transfer roller 13M and the photosensitive drum 11M, the following equation is established.
  I1-I2 = 2000 / RY + 2000 / RC + 2000 / RK (5)
Next, in a state where the insulating portion 51 is engaged between the transfer roller 13C and the photosensitive drum 11C, the following equation is established.
  I1-I2 = 2000 / RY + 2000 / RM + 2000 / RK (6)
Further, in a state where the insulating portion 51 is engaged between the transfer roller 13K and the photosensitive drum 11K, the following equation is established.
  I1-I2 = 2000 / RY + 2000 / RM + 2000 / RC (7)
[0080]
  When the process of engaging the insulating portion 51 with all the transfer rollers 13Y, 13M, 13C, and 13K is completed in this manner (S39: YES), the individual resistance values RY, of the transfer rollers 13Y, 13M, 13C, and 13K are completed. RM, RC and RK are calculated (S42). Specifically, the resistance values RY, RM, RC, and RK are calculated by solving the simultaneous equations related to the equations (4) to (7). . Thus, even if the circuit configuration is simplified by supplying a transfer voltage from one high voltage generator 30 to each transfer roller 13Y, 13M, 13C, 13K, each transfer roller 13Y, The individual resistance values RY, RM, RC, and RK of 13M, 13C, and 13K can be detected.
[0081]
  Then, the calculated resistance values RY, RM, RC, RK so that an appropriate transfer voltage can be supplied from the high voltage generator 30 to the transfer rollers 13Y, 13M, 13C, 13K during image formation. Based on the above, the voltage value of the high voltage generator 30 and the resistance values of the variable resistance elements 31 to 33 are determined. Specifically, first, based on the calculated resistance value RK, the voltage value of the high voltage generator 30 is determined by a table stored in advance in the printer. In addition, you may correct | amend with the environmental data (temperature, humidity, etc.) with a well-known method with respect to the voltage value determined here.
[0082]
  Next, based on the resistance values RC, RM, and RY, the resistance values of the variable resistance elements 33, 32, and 31 are determined by a table stored in advance in the printer. That is, the resistance value of the variable resistance element 33 is determined based on the resistance value RC, the resistance value of the variable resistance element 32 is determined based on the resistance value RM, and the resistance value of the variable resistance element 31 is determined based on the resistance value RY. . Note that each set resistance value determined here may be corrected by environmental data (temperature, humidity, etc.) or data relating to each transfer roller by a known method.
[0083]
  Thereafter, when an image forming process is performed by the image forming units 12Y, 12M, 12C, and 12K, a full-color image is formed as described above. At this time, the voltage value of the high voltage generator 30 and the resistance values of the variable resistance elements 31 to 33 are set to the values determined as described above. In this state, the voltage output from the high voltage generator 30 is applied as it is to the transfer roller 13K, and the respective voltages obtained by stepping down the voltage by the variable resistance elements 33, 32, and 31 are transferred to the transfer roller 13K. Applied to 13C, 13M, and 13Y. That is, the transfer voltage of the transfer roller 13K is the highest, and thereafter the transfer rollers 13C, 13M, and 13Y decrease in order. This is because, on the downstream side of the transfer belt 50, it is necessary to sequentially transfer the toner image on the toner image transferred on the upstream side, so that the voltage value required for transfer is increased. is there.
[0084]
  As described above, since an appropriate transfer voltage is applied to each of the transfer rollers 13Y, 13M, 13C, and 13K, a high-quality image can be obtained. Furthermore, since individual resistance values of the transfer rollers 13Y, 13M, 13C, and 13K are detected, a more appropriate transfer voltage is applied to each of the transfer rollers 13Y, 13M, 13C, and 13K.
[0085]
  As described above in detail, according to the printer according to the third embodiment, similarly to the first embodiment, the high voltage generator 30 applies the transfer rollers 13K, 13C, 13M, and 13Y to the transfer rollers 13K, 13C, 13M, and 13Y. A transfer voltage is supplied. Then, by sequentially engaging the insulating portion 51 between the transfer rollers 13Y, 13M, 13C, and 13K and the photosensitive drums 11Y, 11M, 11C, and 11K, the above formulas (4) to (7) are obtained. can get. Accordingly, the individual resistance values RK, RC, RM, RY of the transfer rollers 13K, 13C, 13M, 13Y can be calculated. Then, based on these resistance values, the output voltage value of the high voltage generator 30 at the time of image formation and the resistance values of the variable resistance elements 31 to 33 are determined, and image formation is performed. Therefore, an optimum transfer voltage is applied from the high voltage generator 30 to each of the plurality of transfer rollers during image formation. As a result, a high quality image is formed. In the above-described third embodiment, the drive of each drive unit is temporarily stopped after the insulating unit 51 is engaged with the facing portion between each photoconductor drum and the transfer roller. May be measured while driving without stopping each drive unit.
[0086]
(Fourth embodiment)
  Next, a fourth embodiment will be described. The printer according to the fourth embodiment has substantially the same configuration as the printer according to the first embodiment, but is connected to a transfer roller 13Y that performs transfer first, as shown in FIG. The difference is that the resistance element 38 having one end grounded is a variable resistance element. In addition, about the same thing as 1st Embodiment, the same code | symbol is attached | subjected in FIG. 8, and the description is abbreviate | omitted.
[0087]
  The processing contents for detecting the resistance values of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 are slightly different with the difference in configuration from the first embodiment. In the present embodiment, as in the second and third embodiments, the individual resistances of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller can be detected.
[0088]
  Accordingly, processing for detecting individual resistance values of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller will be described with reference to flowcharts shown in FIGS. First, processing until the resistance value of the secondary transfer roller 14 is calculated will be described using the flowchart shown in FIG. First, yellow, magenta, cyan, and black image forming units 12Y, 12M, 12C, and 12K, photosensitive drums 11Y, 11M, 11C, and 11K, transfer rollers 13Y, 13M, 13C, and 13K, and a driving roller 21 (transfer) The belt 20) and the secondary transfer roller 14 are driven (S51). At this time, in each of the image forming units 12Y, 12M, 12C, and 12K, the charging charger is turned on, and the entire surface of the photosensitive drum is exposed by the optical system. The developing device is in an off state.
[0089]
  Next, according to a command from the CPU 40, the variable resistance elements 31, 32, 33, and 38 are short-circuited, and the variable resistance element 34 is set to a specified resistance state (resistance value R34) (S52). Subsequently, a voltage of 0.5 kV is output from the high voltage generator 30 (S53). At this time, since the variable resistance elements 31, 32, 33, and 38 are in a short circuit state and the variable resistance element 34 is in a specified resistance state, a voltage of 0.5 kV is applied only to the secondary transfer roller 14, and each transfer roller 13Y, 13M, 13C, and 13K are almost at the GND potential. Accordingly, no current flows through the transfer rollers 13Y, 13M, 13C, and 13K.
[0090]
  In this state, the following processing is performed to detect the current flowing through point A. First, the sampling timer is reset to sample the voltage value at point A (S54). Then, it is confirmed whether or not the sampling timer is up (S55). At this time, if the sampling timer is not yet up (S55: NO), it waits until it is up. On the other hand, if the sampling timer is up (S55: YES), the process proceeds to S56.
[0091]
  When the sampling timer is up, sampling of the voltage value at point A is started (S56). Note that the sampled data is sequentially stored in a memory provided in the printer. Thereafter, it is determined whether or not the transfer belt 20 has made a round after starting sampling of the voltage value at the point A (S57). If the circuit has made a round (S57: YES), sampling is terminated and the process proceeds to S58. On the other hand, if the circuit has not made one round (S57: NO), the process returns to S54 to continue sampling of the voltage value.
[0092]
  Then, when the transfer belt 20 makes a round and sampling of the voltage value at the point A ends, the CPU 40 calculates the average of the sampled voltage values (S58). Then, the current I1s flowing through the point A is calculated from the calculated average voltage value. Since the resistance value of the fixed resistance element 36 provided for current detection is known, the current flowing through the point A can be calculated. Since the current flowing through the variable resistance element 34 is 500 / R34, the current IS flowing into the secondary transfer roller 14 is “I1s−500 / R34”. Here, assuming that the resistance value of the secondary transfer roller 14 is RS, the resistance value RS of the secondary transfer roller 14 is calculated by the following equation (S59).
  IS = I1s-500 / R34 = 500 / RS (8)
[0093]
  Next, processing until the resistance value of the K transfer roller 13K is calculated will be described with reference to the flowchart shown in FIG. When the resistance value RS of the secondary transfer roller 14 is calculated, the variable resistance elements 31, 32, 34, and 38 are short-circuited by the command from the CPU 40, and the variable resistance element 33 is in the specified resistance state (resistance value R33). (S60). Subsequently, a voltage of 0.5 kV is output from the high voltage generator 30 (S61). At this time, since the variable resistance elements 31, 32, 34, and 38 are in a short circuit state and the variable resistance element 33 is in a specified resistance state, a voltage of 0.5 kV is applied to the secondary transfer roller 14 and the transfer roller 13K. The other transfer rollers 13Y, 13M, and 13C are almost at the GND potential. Therefore, no current flows through the transfer rollers 13Y, 13M, and 13C.
[0094]
  In this state, the following processing is performed to detect the current flowing through point A. First, the sampling timer is reset to sample the voltage value at point A (S62). Then, it is confirmed whether or not the sampling timer is up (S63). At this time, if the sampling timer is not yet up (S63: NO), it waits until it is up. On the other hand, if the sampling timer is up (S63: YES), the process proceeds to S64.
[0095]
  When the sampling timer is up, sampling of the voltage value at point A is started (S64). Note that the sampled data is sequentially stored in a memory provided in the printer. Thereafter, it is determined whether or not the transfer belt 20 has made a round after starting sampling of the voltage value at the point A (S65). If the circuit has made a round (S65: YES), sampling is terminated and the process proceeds to S66. On the other hand, if the circuit has not made one round (S65: NO), the process returns to S62 and the voltage value is continuously sampled.
[0096]
  Then, when the transfer belt 20 makes a round and sampling of the voltage value at the point A ends, the CPU 40 calculates the average of the sampled voltage values (S66). Then, the current I1k flowing through the point A is calculated from the calculated average voltage value. Since the current flowing through the variable resistance element 33 is 500 / R33, the current flowing through the secondary transfer roller 14 and the transfer roller 13K is “I1k−500 / R33”. At this time, since the above-described current IS flows through the secondary transfer roller 14, assuming that the resistance value of the transfer roller 13K is RK and the current flowing through the transfer roller 13K is IK, the resistance of the transfer roller 13K is expressed by the following equation. A value RK is calculated (S67).
  IK = I1k-500 / R33-IS = 500 / RK (9)
[0097]
  Next, processing until the resistance value of the C transfer roller 13C is calculated will be described with reference to the flowchart shown in FIG. When the resistance value RK of the transfer roller 13K is calculated, the variable resistance elements 31, 33, 34, and 38 are short-circuited and the variable resistance element 32 is set to the specified resistance state (resistance value R32) according to a command from the CPU 40. (S68). Subsequently, a voltage of 0.5 kV is output from the high voltage generator 30 (S69). At this time, since the variable resistance elements 31, 33, 34, and 38 are in a short circuit state and the variable resistance element 32 is in a specified resistance state, a voltage of 0.5 kV is applied to the secondary transfer roller 14 and the transfer rollers 13K and 13C. Then, the other transfer rollers 13Y and 13M are almost at the GND potential. Therefore, no current flows through the transfer rollers 13Y and 13M.
[0098]
  In this state, the following processing is performed to detect the current flowing through point A. First, the sampling timer is reset to sample the voltage value at point A (S70). Then, it is confirmed whether or not the sampling timer is up (S71). At this time, if the sampling timer is not yet up (S71: NO), it waits until it is up. On the other hand, if the sampling timer is up (S71: YES), the process proceeds to S72.
[0099]
  When the sampling timer is up, sampling of the voltage value at point A is started (S72). Note that the sampled data is sequentially stored in a memory provided in the printer. Thereafter, it is determined whether or not the transfer belt 20 has made a round after starting sampling of the voltage value at the point A (S73). If the circuit has made a round (S73: YES), sampling is terminated and the process proceeds to S74. On the other hand, if the circuit has not made one round yet (S73: NO), the process returns to S70 to continue sampling of the voltage value.
[0100]
  Then, when the transfer belt 20 makes a round and sampling of the voltage value at the point A is completed, the CPU 40 calculates the average of the sampled voltage values (S74). Then, the current I1c flowing through the point A is calculated from the calculated average voltage value. Since the current flowing through the variable resistance element 32 is 500 / R32, the current flowing through the secondary transfer roller 14, the transfer roller 13K, and the transfer roller 13C is “I1c−500 / R32”. At this time, the currents IS and IK flow through the secondary transfer roller 14 and the transfer roller 13K. Accordingly, assuming that the resistance value of the transfer roller 13C is RC and the current flowing through the transfer roller 13C is IC, the resistance value RC of the transfer roller 13C is calculated by the following equation (S75).
  IC = I1c-500 / R32-IS-IK = 500 / RC (10)
[0101]
  Next, processing until the resistance value of the M transfer roller 13M is calculated will be described using the flowchart shown in FIG. When the resistance value RC of the transfer roller 13C is calculated, the variable resistance elements 32, 33, 34, and 38 are short-circuited and the variable resistance element 31 is set to the specified resistance state (resistance value R31) according to a command from the CPU 40. (S76). Subsequently, a voltage of 0.5 kV is output from the high voltage generator 30 (S77). At this time, since the variable resistance elements 32, 33, 34, and 38 are in a short circuit state and the variable resistance element 31 is in a specified resistance state, a voltage of 0.5 kV is applied to the secondary transfer roller 14 and the transfer rollers 13K, 13C, and 13M. Is applied, and the transfer roller 13Y is almost at the GND potential. Accordingly, no current flows through the transfer roller 13Y.
[0102]
  In this state, the following processing is performed to detect the current flowing through point A. First, the sampling timer is reset to sample the voltage value at point A (S78). Then, it is confirmed whether or not the sampling timer is up (S79). At this time, if the sampling timer is not yet up (S79: NO), it waits until it is up. On the other hand, if the sampling timer is up (S79: YES), the process proceeds to S80.
[0103]
  When the sampling timer is up, sampling of the voltage value at point A is started (S80). Note that the sampled data is sequentially stored in a memory provided in the printer. Thereafter, it is determined whether or not the transfer belt 20 has made a round after starting sampling of the voltage value at the point A (S81). If the circuit has made a round (S81: YES), sampling is terminated and the process proceeds to S82. On the other hand, if the circuit has not made one round yet (S81: NO), the process returns to S78 to continue sampling of the voltage value.
[0104]
  Then, when the transfer belt 20 makes one turn and the sampling of the voltage value at the point A is completed, the CPU 40 calculates the average of the sampled voltage values (S82). Then, the current I1m flowing through the point A is calculated from the calculated average voltage value. Since the current flowing through the variable resistance element 31 is 500 / R31, the current flowing through the secondary transfer roller 14, the transfer roller 13K, the transfer roller 13C, and the transfer roller 13M is “I1m−500 / R31”. At this time, the above-described currents IS, IK, and IC flow through the secondary transfer roller 14, the transfer roller 13K, and the transfer roller 13C. Accordingly, assuming that the resistance value of the transfer roller 13M is RM and the current flowing through the transfer roller 13M is IM, the resistance value RM of the transfer roller 13M is calculated by the following equation (S83).
  IM = I1m−500 / R31−IS−IK−IC = 500 / RM …… (11)
[0105]
  Finally, processing until the resistance value of the Y transfer roller 13Y is calculated will be described with reference to the flowchart shown in FIG. When the resistance value RM of the transfer roller 13M is calculated, the variable resistance elements 31, 32, 33, and 34 are short-circuited and the variable resistance element 38 is set to the specified resistance state (resistance value R38) according to a command from the CPU 40. (S84). Subsequently, a voltage of 0.5 kV is output from the high voltage generator 30 (S85). At this time, since the variable resistance elements 31, 32, 33, and 34 are in a short circuit state and the variable resistance element 38 is in a specified resistance state, a voltage of 0.5 kV is applied to all the transfer rollers.
[0106]
  In this state, the following processing is performed to detect the current flowing through point A. First, the sampling timer is reset to sample the voltage value at point A (S86). Then, it is confirmed whether or not the sampling timer is up (S87). At this time, if the sampling timer is not yet up (S87: NO), it waits until it is up. On the other hand, if the sampling timer is up (S87: YES), the process proceeds to S88.
[0107]
  When the sampling timer is up, sampling of the voltage value at the point A is started (S88). Note that the sampled data is sequentially stored in a memory provided in the printer. Thereafter, it is determined whether or not the transfer belt 20 has made a round after starting sampling of the voltage value at the point A (S89). If the circuit has made a round (S89: YES), sampling is terminated and the process proceeds to S90. On the other hand, if the circuit has not made one round (S89: NO), the process returns to S86 and sampling of the voltage value is continued.
[0108]
  Then, when the transfer belt 20 makes a round and sampling of the voltage value at the point A is completed, the CPU 40 calculates the average of the sampled voltage values (S90). Then, the current I1y flowing through the point A is calculated from the calculated average voltage value. Since the current flowing through the variable resistance element 38 is 500 / R38, the current flowing through the secondary transfer roller 14, the transfer roller 13K, the transfer roller 13C, the transfer roller 13M, and the transfer roller 13Y is “I1y−500 / R38”. Become. At this time, the current IS flows through the secondary transfer roller 14, the current IK flows through the transfer roller 13K, the current IC flows through the transfer roller 13C, and the current flows through the transfer roller 13M. Since IM flows, a current of “I1y-500 / R38-IS-IK-IC-IM” flows through the transfer roller 13Y. Accordingly, assuming that the resistance value of the transfer roller 13Y is RY and the current flowing through the transfer roller 13Y is IY, the resistance value RY of the transfer roller 13Y is calculated by the following equation (S91).
  IY = I1y-500 / R38-IS-IK-IC-IM = 500 / RY (12)
[0109]
  When the resistance values of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 are calculated in this way, the image forming units 12Y, 12M, 12C, and 12K, the photosensitive drums 11Y, 11M, 11C, 11K, the transfer rollers 13Y, 13M, 13C, 13K, the driving roller 21 (transfer belt 20), and the secondary transfer roller 14 are stopped (S92). In this way, the circuit configuration is simplified by supplying the transfer voltage from one high voltage generator 30 to each of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14. In addition, the individual resistance values of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 can be detected.
[0110]
  Then, the calculated resistance values so that an appropriate transfer voltage can be supplied from the high voltage generator 30 to the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14 during image formation. Based on the above, the voltage value of the high voltage generator 30 and the resistance values of the variable resistance elements 31 to 34 are determined. Specifically, first, based on the resistance value RS, the voltage value of the high voltage generator 30 is determined by a table stored in advance in the printer. In addition, you may correct | amend with the environmental data (temperature, humidity, etc.) with a well-known method with respect to the voltage value determined here.
[0111]
  Next, based on the resistance values RK, RC, RM, and RY, the resistance values of the variable resistance elements 34, 33, 32, and 31 are determined by a table stored in advance in the printer. That is, the resistance value of the variable resistance element 34 is determined based on the resistance value RK, the resistance value of the variable resistance element 33 is determined based on the resistance value RC, and the resistance value of the variable resistance element 32 is determined based on the resistance value RM. The resistance value of the variable resistance element 31 is determined based on the resistance value RY. Note that each resistance value determined here may be corrected by environmental data (temperature, humidity, etc.) or data relating to each transfer roller by a known method.
[0112]
  Thereafter, when an image forming process is performed by the image forming units 12Y, 12M, 12C, and 12K, a full-color image is formed as described above. At this time, the voltage value of the high voltage generator 30 and the resistance values of the variable resistance elements 31 to 34 are set to the values determined as described above. In this state, the voltage output from the high voltage generator 30 is applied to the secondary transfer roller 14, and the respective voltages obtained by stepping down the voltages by the variable resistance elements 34, 33, 32, and 31 are sequentially applied. And applied to the transfer rollers 13K, 13C, 13M, and 13Y.
[0113]
  That is, the transfer voltage of the secondary transfer roller 14 is the highest, and the transfer rollers 13K, 13C, 13M, and 13Y decrease in this order. This is because, on the downstream side of the transfer belt 20, it is necessary to sequentially transfer the toner image superimposed on the toner image transferred on the upstream side, so that the voltage value necessary for the transfer is increased. It is. As described above, since an appropriate transfer voltage is applied to each of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14, a high-quality image can be obtained. Furthermore, since the individual resistance values of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 are detected, the transfer rollers 13Y, 13M, 13C, and 13K, and the secondary transfer roller 14 have more resistance. Appropriate transfer voltage is applied.
[0114]
  As described above in detail, according to the printer of the fourth embodiment, the transfer rollers 13K, 13C, 13M, 13Y, and 2 from the high voltage generator 30 are the same as in the first embodiment. A transfer voltage is supplied to the next transfer roller 14. Then, the variable resistance elements to be in the specified resistance state are sequentially switched, and the current I1 flowing into the high voltage generator 30 in each state is detected, whereby the secondary transfer roller 14 and the transfer rollers 13K, 13C, The magnitudes of currents flowing into 13M and 13Y are calculated. Then, the respective resistance values RS, RK, RC, RM, RY of the secondary transfer roller 14 and the transfer rollers 13K, 13C, 13M, 13Y are calculated by the above formulas (8) to (12). Then, based on these resistance values, the output voltage value of the high voltage generator 30 at the time of image formation and the resistance values of the variable resistance elements 31 to 33 are determined, and image formation is performed. Therefore, an optimum transfer voltage is applied from the high voltage generator 30 to each of the plurality of transfer rollers during image formation. As a result, a high quality image is formed.
[0115]
  In the fourth embodiment, the printer configured to perform the secondary transfer has been described. Of course, the configuration is such that the secondary transfer is not performed and the photosensitive drums 11Y, 11M, 11C, and 11K are directly transferred to the recording paper. The present invention can be applied to any printer. In this case, in FIG. 8, the secondary transfer roller 14, the wiring to the secondary transfer roller 14, the cleaning power source 37, and the variable resistance element 34 are unnecessary. As a result, the circuit for supplying the transfer voltage from the high voltage generator 30 to the transfer rollers 13Y, 13M, 13C, and 13K has a circuit configuration as shown in FIG. In the circuit shown in FIG. 14, the above-described control (the processing of S52 to S59 is not necessary) is performed, so that one high power generator 30 can perform appropriate transfer to each transfer roller 13Y, 13M, 13C, 13K. A voltage can be supplied.
[0116]
  Further, since the variable resistance element 38 only needs to be able to switch between two states of a short circuit state or a prescribed resistance state, it can be replaced with a combination of a fixed resistance element and a transistor as shown in FIG.
[0117]
(Fifth embodiment)
  Finally, a fifth embodiment will be described. The printer according to the fifth embodiment has substantially the same configuration as the printer according to the first embodiment. However, as shown in FIG. 16, a variable resistance element is connected between the transfer rollers. Instead, the difference is that the constant voltage elements 61 to 64 are connected. However, a variable constant voltage element 64 is connected between the secondary transfer roller 14 and the transfer roller 13K. Here, the variable constant voltage element 64 includes a transistor 65, a photocoupler 66, and an operational amplifier 67 as shown in FIG. In the variable constant voltage element 64, the photocoupler 66 and the operational amplifier 67 control the Vce of the transistor 65 so that the divided values of the setting signal and the output signal are the same, whereby a constant voltage value (from input to output) ( Voltage drop value) can be set. In addition, the constant voltage value of each constant voltage element 61-63 is 200V. Further, the same components as those in the first embodiment are denoted by the same reference numerals in FIG.
[0118]
  The processing contents for detecting the resistance values of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 are slightly different with the difference in configuration from the first embodiment. In the present embodiment as well, the resistance values of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 are all the same as in the first embodiment.
[0119]
  A process for detecting the resistance values of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14 will be described with reference to the flowchart shown in FIG. First, yellow, magenta, cyan, and black image forming units 12Y, 12M, 12C, and 12K, photosensitive drums 11Y, 11M, 11C, and 11K, transfer rollers 13Y, 13M, 13C, and 13K, and a driving roller 21 (transfer) The belt 20) and the secondary transfer roller 14 are driven (S101). At this time, in each of the image forming units 12Y, 12M, 12C, and 12K, the charging charger is turned on, and the electrostatic latent image is written onto the photosensitive drum by the optical system. The developing device is in an off state.
[0120]
  Next, in response to a command from the CPU 40, the variable constant voltage element 64 is set to a specified voltage state (200V) (S102), and a high voltage generator 30 outputs a voltage of 2 kV (S103). At this time, since the voltage output from the high voltage generator 30 is applied to the secondary transfer roller 14 as it is, a voltage of 2 kV is applied. Further, a voltage output from the high voltage generator 30 is applied to each of the transfer rollers 13K, 13C, 13M, and 13Y via the constant voltage elements 64 to 61 (200V). As a result, the transfer roller 13K has a voltage of 1.8 kV, the transfer roller 13C has a voltage of 1.6 kV, the transfer roller 13M has a voltage of 1.4 kV, and the transfer roller 13Y has a voltage of 1.2 kV. Each is applied.
[0121]
  In this state, the following processing is performed to detect the current flowing through point A. First, the sampling timer is reset to sample the voltage value at point A (S104). Then, it is confirmed whether or not the sampling timer is up (S105). At this time, if the sampling timer is not yet up (S105: NO), it waits until it is up. On the other hand, when the sampling timer is up (S105: YES), the process proceeds to S106.
[0122]
  When the sampling timer is up, sampling of the voltage value at point A is started (S106). Note that the sampled data is sequentially stored in a memory provided in the printer. Thereafter, it is determined whether or not the transfer belt 20 has made a round after starting sampling of the voltage value at the point A (S107). If the circuit has made a round (S107: YES), sampling is terminated and the process proceeds to S108. On the other hand, if the circuit has not made a round yet (S107: NO), the process returns to S104 and sampling of the voltage value is continued.
[0123]
  Then, when the transfer belt 20 makes a round and sampling of the voltage value at the point A is completed, the CPU 40 calculates the average of the sampled voltage values (S108). Then, a current I1 flowing through the point A is calculated from the calculated average voltage value. Since the resistance value of the fixed resistance element 36 provided for current detection is known, the current flowing through the point A can be calculated. If the current flowing through the fixed resistance element 35 is I2 (known), the total of the currents flowing through the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 is “I1-I2”. Further, since the resistance values of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14 are all equal, the transfer rollers 13Y, 13M, 13C, 13K, and the secondary transfer roller 14 are expressed by the following equations. The resistance value R is calculated (S109).
  I1−I2 = 2000 / R + 1800 / R + 1600 / R + 1400 / R + 1200 / R ... (13)
The current I2 is I2 = 1200 / R2 when the resistance value of the fixed resistance element 35 is R2.
[0124]
  When the resistance values R of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 are calculated, the image forming units 12Y, 12M, 12C, and 12K, and the photosensitive drums 11Y, 11M, 11C, and 11K are calculated. The transfer rollers 13Y, 13M, 13C, and 13K, the drive roller 21 (transfer belt 20), and the secondary transfer roller 14 are stopped (S110). In this way, the circuit configuration is simplified by supplying the transfer voltage from one high voltage generator 30 to each of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14. In addition, the resistance value R of each of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14 can be detected.
[0125]
  Then, the calculated resistance value R so that an appropriate transfer voltage can be supplied from the high voltage generator 30 to each of the transfer rollers 13Y, 13M, 13C, 13K and the secondary transfer roller 14 during image formation. Based on the above, the voltage value of the high voltage generator 30 and the constant voltage value of each variable constant voltage element 64 are determined. Specifically, first, based on the calculated resistance value R, the voltage value of the high voltage generator 30 is determined by a table stored in advance in the printer. In addition, you may correct | amend with the environmental data (temperature, humidity, etc.) with a well-known method with respect to the voltage value determined here. Next, based on the resistance value R, the constant voltage value of the variable constant voltage element 64 is determined by a table stored in advance in the printer. The constant voltage value determined here may be corrected by environmental data (temperature, humidity, etc.) and data relating to each transfer roller by a known method.
[0126]
  Thereafter, when an image forming process is performed by the image forming units 12Y, 12M, 12C, and 12K, a full-color image is formed as described above. At this time, the voltage value of the high voltage generator 30 and the constant voltage value of the variable constant voltage element 64 are set to the values determined as described above. In this state, the voltage output from the high voltage generator 30 is applied as it is to the secondary transfer roller 14, and the respective voltages obtained by stepping down the voltages in order by the constant voltage elements 64, 63, 62, 61 are obtained. And applied to the transfer rollers 13K, 13C, 13M, and 13Y. That is, the transfer voltage of the secondary transfer roller 14 is the highest, and thereafter the transfer rollers 13K, 13, 13, 13M, and 13Y decrease in order. This is because, on the downstream side of the transfer belt 20, it is necessary to sequentially transfer the toner image superimposed on the toner image transferred on the upstream side, so that the voltage value necessary for the transfer is increased. It is. As described above, since an appropriate transfer voltage is applied to each of the transfer rollers 13Y, 13M, 13C, and 13K and the secondary transfer roller 14, a high-quality image can be obtained.
[0127]
  As described above in detail, according to the printer of the fifth embodiment, the transfer rollers 13K, 13C, 13M, 13Y and 2 from the high voltage generator 30 are the same as in the first embodiment. A transfer voltage is supplied to the next transfer roller 14. Then, when a voltage of 2 kV is output from the high voltage generator 30 and the variable constant voltage element 64 is set to a specified voltage state, a current I1 flowing into the high voltage generator 30 is detected. Then, the resistance value R of the secondary transfer roller 14 and each of the transfer rollers 13K, 13C, 13M, and 13Y is calculated from the above equation (13). Based on the resistance value R, the output voltage value of the high voltage generator 30 and the constant voltage value of the variable constant voltage element 64 during image formation are determined, and image formation is performed. Therefore, an optimum transfer voltage is applied from the high voltage generator 30 to the plurality of transfer rollers during image formation. As a result, a high quality image is formed.
[0128]
  In the fifth embodiment, the printer configured to perform the secondary transfer has been described. Of course, the configuration is such that the secondary transfer is not performed and the photosensitive drums 11Y, 11M, 11C, and 11K are directly transferred to the recording paper. The present invention can be applied to any printer. In this case, in FIG. 16, the wiring to the secondary transfer roller 14, the secondary transfer roller 14, the cleaning power source 37, and the variable constant voltage element 64 are unnecessary. As a result, the circuit that supplies the transfer voltage from the high voltage generator 30 to the transfer rollers 13K, 13C, 13M, and 13Y has a circuit configuration as shown in FIG. In the circuit shown in FIG. 19, by performing the above-described control (the process of S102 is unnecessary), an appropriate transfer voltage is applied to each of the transfer rollers 13K, 13C, 13M, and 13Y by one high power generation device 30. Can be supplied. The equation (13) for calculating the resistance value R of each transfer roller is the following equation (14).
  I1−I2 = 2000 / R + 1800 / R + 1600 / R + 1400 / R …… (14)
[0129]
  In addition, as shown in FIG. 20, the configuration of the second embodiment can be combined with the fifth embodiment described above. That is, the transfer rollers 53Y, 53M, 53C, and 53K can be brought into contact with and separated from the photosensitive drums 11Y, 11M, 11C, and 11K. Furthermore, as shown in FIG. 21, it is possible to combine the third embodiment. That is, the insulating portion 51 can be provided on a part of the transfer belt 50. 20 or 21, the individual resistance value of each transfer roller can be calculated as described in detail in the second or third embodiment. Accordingly, a more appropriate transfer voltage can be supplied from the high voltage generator 30 to each transfer roller. Therefore, a higher quality image can be obtained. Alternatively, the constant voltage elements 61, 62, and 63 may be changed to variable constant voltage elements, and the constant voltage values of these variable constant voltage elements may be changed based on the calculated resistance value R. Thereby, control with higher accuracy is possible.
[0130]
  The first to fifth embodiments described above are merely examples and do not limit the present invention in any way, and various improvements and modifications can be made without departing from the scope of the invention. It is. For example, in the above embodiment, the case where the present invention is applied to a printer has been described. However, the present invention can be applied to a printer, a facsimile, or the like in addition to a printer. Needless to say, the specific numerical values (for example, voltage values) exemplified in the above-described embodiment are merely examples.
[0131]
  Furthermore, as shown in FIG. 22, the variable resistance elements 31 to 34 can be configured by combining transistors and resistors. In this case, the combined resistance value from the input to the output may be set by selecting the conduction of the transistor by the selection signal (turning on each selection signal). Note that the resistor shown in FIG. 22 may be a combination of a Zener diode and a resistor.
[0132]
  Further, as shown in FIG. 23, the variable constant voltage element 64 can be configured by combining a transistor and a Zener diode. In this case, it is only necessary to select the Zener diode to be energized by selecting the conduction of the transistor by the selection signal (turning on each selection signal) and to set the constant voltage value (voltage drop value) from the input to the output. . Note that the Zener diode shown in FIG. 23 may be a combination of a resistor and a Zener diode.
[0133]
【The invention's effect】
  As described above, according to the present invention, the configuration of a circuit for supplying a transfer voltage to a plurality of transfer units can be simplified, and an appropriate transfer voltage can be applied to each transfer unit. Is provided.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a schematic configuration of a main part of a printer according to a first embodiment and a voltage supply circuit to each transfer roller.
FIG. 2 is a flowchart illustrating a process for calculating a resistance value of a transfer roller.
FIG. 3 is a circuit diagram illustrating a voltage supply circuit to each transfer roller when secondary transfer is not performed.
FIG. 4 is a diagram illustrating a schematic configuration of a main part of a printer and a voltage supply circuit to each transfer roller according to a second embodiment.
FIG. 5 is a flowchart illustrating a process of calculating a resistance value of each transfer roller.
FIG. 6 is a diagram illustrating a schematic configuration of a main part of a printer according to a third embodiment and a voltage supply circuit to each transfer roller.
FIG. 7 is a flowchart illustrating a process of calculating a resistance value of each transfer roller.
FIG. 8 is a diagram illustrating a schematic configuration of a main part of a printer and a voltage supply circuit to each transfer roller according to a fourth embodiment.
FIG. 9 is a flowchart illustrating a process of calculating a resistance value of the secondary transfer roller.
FIG. 10 is a flowchart illustrating a process of calculating a resistance value of a K transfer roller.
FIG. 11 is a flowchart illustrating a process of calculating a resistance value of a C transfer roller.
FIG. 12 is a flowchart illustrating a process for calculating a resistance value of an M transfer roller.
FIG. 13 is a flowchart illustrating a process of calculating a resistance value of a Y transfer roller.
FIG. 14 is a circuit diagram illustrating a voltage supply circuit to each transfer roller when secondary transfer is not performed.
FIG. 15 is a circuit diagram showing another configuration of a variable resistance element having one end connected to a Y transfer roller and the other end grounded.
FIG. 16 is a diagram illustrating a schematic configuration of a main part of a printer according to a fifth embodiment and a voltage supply circuit to each transfer roller.
FIG. 17 is a circuit diagram showing a configuration of a variable constant voltage element.
FIG. 18 is a flowchart illustrating a process of calculating a resistance value of a transfer roller.
FIG. 19 is a circuit diagram illustrating a voltage supply circuit to each transfer roller when secondary transfer is not performed.
FIG. 20 is a diagram illustrating a schematic configuration of a main part of a printer and a voltage supply circuit to each transfer roller when the configuration of the second embodiment is combined with the fifth embodiment.
FIG. 21 is a diagram illustrating a schematic configuration of a main part of a printer and a voltage supply circuit to each transfer roller when the configuration of the third embodiment is combined with the fifth embodiment.
FIG. 22 is a circuit diagram showing another configuration of the variable resistance element.
FIG. 23 is a circuit diagram showing another configuration of the variable constant voltage element.
[Explanation of symbols]
  11Y, 11M, 11C, 11K Photosensitive drum
  13Y, 13M, 13C, 13K transfer roller
  14 Secondary transfer roller
  15 Recording paper
  20 Transfer belt
  30 High voltage generator
  31, 32, 33, 34 Variable resistance element
  35, 36 Fixed resistance element
  40 CPU

Claims (16)

A plurality of image carriers;
A plurality of first transfer means for transferring toner images carried on the plurality of image bearing members to a transfer target member, and having a resistance value equal to each other ;
A second transfer unit having a resistance value equal to one of the plurality of first transfer units, which transfers the toner image transferred to the transfer target to a recording medium;
A variable resistance element for connecting adjacent ones of the plurality of first transfer means and the second transfer means in the transfer order;
Resistance control means for controlling the resistance value of the variable resistance element;
A high voltage generating means connected to the second transfer means and supplying a transfer voltage to the plurality of first transfer means and the second transfer means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer means among the plurality of first transfer means and the other end grounded ;
A resistance value calculating means for calculating a resistance value of the first transfer means and the second transfer means based on the current value detected by the current detection means ;
It said output control means, based on the resistance value issued calculated by the resistance calculation detecting means, so that it can supply a proper transfer voltage to said plurality of first transfer means and the second transfer means, is stored in advance The output value of the high voltage generating means at the time of image formation is determined by the table being
It said resistance control means, based on the resistance value issued calculated by the resistance calculation detecting means, so that it can supply a proper transfer voltage to said plurality of first transfer means and the second transfer means, is stored in advance A resistance value of the variable resistance element at the time of image formation is determined by an existing table . A plurality of image carriers;
A plurality of transfer means for transferring the toner images carried on the plurality of image carriers to a transfer medium, and having a resistance value equal to each other ;
A variable resistance element that connects adjacent transfer orders among the plurality of transfer means; and
Resistance control means for controlling the resistance value of the variable resistance element;
A high voltage generating means connected to the last transferring means among the plurality of transferring means and supplying a transfer voltage to the plurality of transferring means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer unit among the plurality of transfer means, and the other end grounded ;
A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means ;
Said output control means, based on the resistance value issued calculated by the resistance calculation detecting means, said plurality of so that it can supply a proper transfer voltage to the transfer means, wherein when the image formed by the table previously stored Determine the output value of the high voltage generation means,
It said resistance control means, based calculated on out resistance value in the resistance value calculation detecting means, so that it can supply a proper transfer voltage to the plurality of transfer means, wherein when the image formed by the table previously stored Determine the resistance value of the variable resistance element,
It said current detecting means with a predetermined magnitude of the high voltage is output from the high voltage generating means by the output control means, when the variable resistive element is short-circuited by the resistance control means, before Symbol An image forming apparatus characterized by detecting the magnitude of a current flowing into a high voltage generating means. A plurality of image carriers;
A plurality of first transfer means for transferring toner images carried on the plurality of image bearing members to a transfer target member, and having a resistance value equal to each other ;
A second transfer unit having a resistance value equal to one of the plurality of first transfer units, which transfers the toner image transferred to the transfer target to a recording medium;
A constant voltage element that connects adjacent ones in the transfer order among the plurality of first transfer means; and
A variable constant voltage element that connects the second transfer means to the last transfer means among the plurality of first transfer means;
Constant voltage control means for controlling a constant voltage value of the variable constant voltage element;
A high voltage generating means connected to the second transfer means and supplying a transfer voltage to the plurality of first transfer means and the second transfer means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer means among the plurality of first transfer means and the other end grounded ;
A resistance value calculating means for calculating a resistance value of the first transfer means and the second transfer means based on the current value detected by the current detection means ;
It said output control means, based on the resistance value issued calculated by the resistance calculation detecting means, so that it can supply a proper transfer voltage to said plurality of first transfer means and the second transfer means, is stored in advance The output value of the high voltage generating means at the time of image formation is determined by the table being
The constant voltage control means, based on the resistance value issued calculated by the resistance calculation detecting means, so that it can supply a proper transfer voltage to said plurality of first transfer means and the second transfer means, stored in advance An image forming apparatus, wherein a constant voltage value of the variable constant voltage element at the time of image formation is determined by a table . The image forming apparatus according to claim 3.
The current detection means is configured to output a high voltage of a predetermined magnitude from the high voltage generation means by the output control means, and when the variable constant voltage element is brought into a specified resistance state by the constant voltage control means. an image forming apparatus characterized by detecting the magnitude of current flowing in front Symbol high voltage generating means. A plurality of image carriers;
A plurality of first transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
A second transfer means for transferring the toner image transferred to the transfer medium to a recording medium;
A variable resistance element for connecting adjacent ones of the plurality of first transfer means and the second transfer means in the transfer order;
Resistance control means for controlling the resistance value of the variable resistance element;
A high voltage generating means connected to the second transfer means and supplying a transfer voltage to the plurality of first transfer means and the second transfer means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of the current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer means among the plurality of first transfer means and the other end grounded;
A resistance value calculating means for calculating a resistance value of the plurality of first transfer means and the second transfer means based on the current value detected by the current detection means;
The output control means stores a table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means. To determine the output value of the high voltage generating means during image formation,
A table stored in advance so that the resistance control means can supply an appropriate transfer voltage to the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means. To determine the resistance value of the variable resistance element during image formation ,
Each of the first transfer means can contact and separate from each of the image carriers,
The resistance value calculating means is configured such that one of the plurality of first transfer means is in contact with the image carrier and the remaining first transfer means is separated from each image carrier, and the current detection means is Detecting the magnitude of the current flowing into the high voltage generating means is performed for each first transfer means by switching the first transfer means in contact with the image carrier, thereby calculating the resistance value of each first transfer means. An image forming apparatus. A plurality of image carriers;
A plurality of transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
A variable resistance element connecting the transfer means adjacent to each other among the plurality of transfer means;
Resistance control means for controlling the resistance value of the variable resistance element;
A high voltage generating means connected to the last transferring means among the plurality of transferring means and supplying a transfer voltage to the plurality of transferring means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of the current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer unit among the plurality of transfer means and the other end grounded;
A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means;
The output control unit is configured to use the high voltage at the time of image formation based on a table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer units based on the resistance value calculated by the resistance value calculation unit. Determine the output value of the generating means,
The resistance control unit is configured to use the variable resistor at the time of image formation based on a table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of transfer units based on the resistance value calculated by the resistance value calculation unit. Determine the resistance of the element,
The current detection means outputs a high voltage of a predetermined magnitude from the high voltage generation means by the output control means and when the variable resistance element is short-circuited by the resistance control means. Detect the magnitude of the current flowing into the voltage generation means ,
Each of the transfer means can be contacted and separated from each of the image carriers,
The resistance value calculating means is configured such that the current detecting means generates the high voltage while one of the plurality of transfer means is in contact with the image carrier and the remaining transfer means are separated from the image carriers. An image forming apparatus characterized in that the resistance value of each transfer means is calculated by detecting the magnitude of the current flowing into the means for each transfer means by switching the transfer means in contact with the image carrier . A plurality of image carriers;
A plurality of first transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
A second transfer means for transferring the toner image transferred to the transfer medium to a recording medium;
A constant voltage element that connects adjacent ones in the transfer order among the plurality of first transfer means; and
A variable constant voltage element that connects the second transfer means to the last transfer means among the plurality of first transfer means;
Constant voltage control means for controlling a constant voltage value of the variable constant voltage element;
A high voltage generating means connected to the second transfer means and supplying a transfer voltage to the plurality of first transfer means and the second transfer means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of the current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer means among the plurality of first transfer means and the other end grounded;
A resistance value calculating means for calculating a resistance value of the first transfer means and the second transfer means based on the current value detected by the current detection means;
The output control means stores a table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means. To determine the output value of the high voltage generating means during image formation,
The constant voltage control means is stored in advance so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means. A constant voltage value of the variable constant voltage element at the time of image formation is determined by a table ,
Each of the transfer means can be contacted and separated from each of the image carriers,
The resistance value calculating means is configured such that one of the plurality of first transfer means is in contact with the image carrier and the remaining first transfer means is separated from each image carrier, and the current detection means is Detecting the magnitude of the current flowing into the high voltage generating means is performed for each first transfer means by switching the first transfer means in contact with the image carrier, thereby calculating the resistance value of each first transfer means. An image forming apparatus. A plurality of image carriers;
A plurality of first transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
A second transfer means for transferring the toner image transferred to the transfer medium to a recording medium;
A variable resistance element for connecting adjacent ones of the plurality of first transfer means and the second transfer means in the transfer order;
Resistance control means for controlling the resistance value of the variable resistance element;
A high voltage generating means connected to the second transfer means and supplying a transfer voltage to the plurality of first transfer means and the second transfer means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of the current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer means among the plurality of first transfer means and the other end grounded;
Resistance value calculating means for calculating resistance values of the first transfer means and the second transfer means based on the current value detected by the current detection means;
And a driving means for driving the material to be transferred,
The output control means stores a table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means. To determine the output value of the high voltage generating means during image formation,
A table stored in advance so that the resistance control means can supply an appropriate transfer voltage to the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means. To determine the resistance value of the variable resistance element during image formation ,
The transferred object is provided with an insulator in part,
The resistance value calculating means drives a part to be transferred by the driving means between one of the plurality of first transfer means and the image carrier corresponding thereto, and a part of the object to be transferred The first transfer that causes the insulator to be engaged is detected by detecting the magnitude of the current flowing into the high-voltage generating means in the state where the insulator provided in the insulator is engaged. An image forming apparatus , wherein the resistance value of each first transfer unit is calculated by switching the units and performing the process on each first transfer unit . A plurality of image carriers;
A plurality of transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
A variable resistance element connecting the transfer means adjacent to each other among the plurality of transfer means;
Resistance control means for controlling the resistance value of the variable resistance element;
A high voltage generating means connected to the last transferring means among the plurality of transferring means and supplying a transfer voltage to the plurality of transferring means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of the current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer unit among the plurality of transfer means and the other end grounded;
A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means;
And a driving means for driving the material to be transferred,
The output control means generates the high voltage at the time of image formation by a prestored table so that an appropriate transfer voltage can be supplied to the plurality of transfer means based on the resistance value calculated by the resistance value calculation means. Determine the output value of the means,
The variable resistance element at the time of image formation by a previously stored table so that the resistance control means can supply an appropriate transfer voltage to the plurality of transfer means based on the resistance value calculated by the resistance value calculation means Determine the resistance value of
The current detection means outputs a high voltage of a predetermined magnitude from the high voltage generation means by the output control means and when the variable resistance element is short-circuited by the resistance control means. Detect the magnitude of the current flowing into the voltage generation means ,
The transferred object is provided with an insulator in part,
The resistance value calculating means is provided on a part of the transferred body by driving the transferred body by the driving means between one of the plurality of transfer means and the corresponding image carrier. The current detecting means detects the magnitude of the current flowing into the high voltage generating means in the state where the insulator is bited, and the transfer means for biting the insulator is switched. An image forming apparatus , wherein the resistance value of each transfer unit is calculated by performing each transfer unit . A plurality of image carriers;
A plurality of first transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
A second transfer means for transferring the toner image transferred to the transfer medium to a recording medium;
A constant voltage element that connects adjacent ones in the transfer order among the plurality of first transfer means; and
A variable constant voltage element that connects the second transfer means to the last transfer means among the plurality of first transfer means;
Constant voltage control means for controlling a constant voltage value of the variable constant voltage element;
A high voltage generating means connected to the second transfer means and supplying a transfer voltage to the plurality of first transfer means and the second transfer means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of the current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer means among the plurality of first transfer means and the other end grounded;
Resistance value calculating means for calculating resistance values of the first transfer means and the second transfer means based on the current value detected by the current detection means;
And a driving means for driving the material to be transferred,
The output control means stores a table stored in advance so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means. To determine the output value of the high voltage generating means during image formation,
The constant voltage control means is stored in advance so that an appropriate transfer voltage can be supplied to the plurality of first transfer means and the second transfer means based on the resistance value calculated by the resistance value calculation means. A constant voltage value of the variable constant voltage element at the time of image formation is determined by a table ,
The transferred object is provided with an insulator in part,
The resistance value calculating means drives a part to be transferred by the driving means between one of the plurality of first transfer means and the image carrier corresponding thereto, and a part of the object to be transferred The first transfer that causes the insulator to be engaged is detected by detecting the magnitude of the current flowing into the high-voltage generating means in the state where the insulator provided in the insulator is engaged. An image forming apparatus , wherein the resistance value of each first transfer unit is calculated by switching the units and performing the process on each first transfer unit . A plurality of image carriers;
A plurality of first transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
A second transfer means for transferring the toner image transferred to the transfer medium to a recording medium;
Among the plurality of first transfer units and the second transfer unit, a plurality of transfer units adjacent to each other , and a plurality of first transfer units that perform transfer first and a plurality of ground points are connected . A variable resistance element ;
A resistance control means for controlling the resistance value before Symbol plurality of variable resistors element,
A high voltage generating means connected to the second transfer means and supplying a transfer voltage to the plurality of first transfer means and the second transfer means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting a current value flowing into the high voltage generating means ;
A resistance value calculating means for calculating a resistance value of the first transfer means and the second transfer means based on the current value detected by the current detection means ;
Said output control means, based on the resistance value issued calculated by the resistance calculation detecting means, said plurality of so that it can supply a proper transfer voltage to the transfer means, wherein when the image formed by the table previously stored Determine the output value of the high voltage generation means,
It said resistance control means, based calculated on out resistance value in the resistance value calculation detecting means, so that it can supply a proper transfer voltage to the plurality of transfer means, prior to the time of image formation by the table stored in advance asked to determine the respective resistance values of the variable resistance element,
The resistance value calculating means outputs a voltage of a predetermined magnitude from the high voltage generating means by the output control means, and one of the plurality of variable resistance elements is in a prescribed resistance state by the resistance control means, When the others are in a short circuit state, the current detection means detects the magnitude of the current flowing into the high voltage generation means by switching the variable resistance elements in a specified resistance state for each variable resistance element. To calculate the resistance value of each transfer means . A plurality of image carriers;
A plurality of transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
Among the plurality of transfer means, ones that are adjacent to each other in the transfer order , and a plurality of variable resistance elements that connect a grounding point to the first transfer among the plurality of transfer means ,
A resistance control means for controlling the resistance value before Symbol plurality of variable resistors element,
A high voltage generating means connected to the last transferring means among the plurality of transferring means and supplying a transfer voltage to the plurality of transferring means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting a current value flowing into the high voltage generating means ;
A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means ;
Said output control means, based on the resistance value issued calculated by the resistance calculation detecting means, said plurality of so that it can supply a proper transfer voltage to the transfer means, wherein when the image formed by the table previously stored Determine the output value of the high voltage generation means,
It said resistance control means, based calculated on out resistance value in the resistance value calculation detecting means, so that it can supply a proper transfer voltage to the plurality of transfer means, wherein when the image formed by the table previously stored Determine each resistance value of multiple variable resistance elements,
The resistance calculation means with a predetermined magnitude voltage is output from the high voltage generating means by the output control means, said plurality of variable resistors element by the resistance control means, one of prescribed resistance states In addition, when the others are short-circuited, the current detecting means detects the magnitude of the current flowing into the high voltage generating means by switching the variable resistance elements to be in a prescribed resistance state for each variable resistance element. Thus, the resistance value of each transfer unit is calculated . A plurality of image carriers;
A plurality of transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
A variable resistance element that connects adjacent transfer orders among the plurality of transfer means; and
Resistance control means for controlling the resistance value of the variable resistance element;
A high voltage generating means connected to the last transferring means among the plurality of transferring means and supplying a transfer voltage to the plurality of transferring means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer unit among the plurality of transfer means, and the other end grounded ;
A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means ;
Said output control means, based on the resistance value issued calculated by the resistance calculation detecting means, said plurality of so that it can supply a proper transfer voltage to the transfer means, wherein when the image formed by the table previously stored Determine the output value of the high voltage generation means,
It said resistance control means, based calculated on out resistance value in the resistance value calculation detecting means, so that it can supply a proper transfer voltage to the plurality of transfer means, wherein when the image formed by the table previously stored Determine the resistance value of the variable resistance element,
Each of the transfer means can be contacted and separated from each of the image carriers,
The resistance value calculating means is configured such that the current detecting means generates the high voltage while one of the plurality of transfer means is in contact with the image carrier and the remaining transfer means are separated from the image carriers. An image forming apparatus characterized in that the resistance value of each transfer means is calculated by detecting the magnitude of the current flowing into the means for each transfer means by switching the transfer means in contact with the image carrier . A plurality of image carriers;
A plurality of transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
A constant voltage element for connecting the transfer means adjacent to each other among the plurality of transfer means; and
A high voltage generating means connected to the last transferring means among the plurality of transferring means and supplying a transfer voltage to the plurality of transferring means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer unit among the plurality of transfer means, and the other end grounded ;
A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means ;
Said output control means, based on the resistance value issued calculated by the resistance calculation detecting means, said plurality of so that it can supply a proper transfer voltage to the transfer means, wherein when the image formed by the table previously stored Determine the output value of the high voltage generation means,
Each of the transfer means can be contacted and separated from each of the image carriers,
The resistance value calculating means is configured such that the current detecting means generates the high voltage while one of the plurality of transfer means is in contact with the image carrier and the remaining transfer means are separated from the image carriers. An image forming apparatus characterized in that the resistance value of each transfer means is calculated by detecting the magnitude of the current flowing into the means for each transfer means by switching the transfer means in contact with the image carrier . A plurality of image carriers;
A plurality of transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
A variable resistance element that connects adjacent transfer orders among the plurality of transfer means; and
Resistance control means for controlling the resistance value of the variable resistance element;
A high voltage generating means connected to the last transferring means among the plurality of transferring means and supplying a transfer voltage to the plurality of transferring means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer unit among the plurality of transfer means and the other end grounded;
A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means;
Driving means for driving the transfer object;
Said output control means, based on the resistance value issued calculated by the resistance calculation detecting means, said plurality of so that it can supply a proper transfer voltage to the transfer means, wherein when the image formed by the table previously stored Determine the output value of the high voltage generation means,
It said resistance control means, based calculated on out resistance value in the resistance value calculation detecting means, so that it can supply a proper transfer voltage to the plurality of transfer means, wherein when the image formed by the table previously stored Determine the resistance value of the variable resistance element,
The transferred object is provided with an insulator in part,
The resistance value calculating means is provided on a part of the transferred body by driving the transferred body by the driving means between one of the plurality of transfer means and the corresponding image carrier. A first transfer means for biting the insulator to detect that the current detecting means detects the magnitude of the current flowing into the high voltage generating means in the state of being bitten; An image forming apparatus , wherein the resistance value of each first transfer unit is calculated by switching and performing each first transfer unit . A plurality of image carriers;
A plurality of transfer means for transferring the toner images carried on the plurality of image carriers to a transfer target;
A constant voltage element for connecting the transfer means adjacent to each other among the plurality of transfer means; and
A high voltage generating means connected to the last transferring means among the plurality of transferring means and supplying a transfer voltage to the plurality of transferring means;
Output control means for controlling the output value of the high voltage generating means;
Current detecting means for detecting the magnitude of current flowing into the high voltage generating means;
A fixed resistance element having one end connected to the first transfer unit among the plurality of transfer means, and the other end grounded ;
A resistance value calculating means for calculating a resistance value of the transfer means based on the current value detected by the current detecting means;
Driving means for driving the transfer object ;
Said output control means, based on the resistance value issued calculated by the resistance calculation detecting means, said plurality of so that it can supply a proper transfer voltage to the transfer means, wherein when the image formed by the table previously stored Determine the output value of the high voltage generation means,
The transferred object is provided with an insulator in part,
The resistance value calculating means is provided on a part of the transferred body by driving the transferred body by the driving means between one of the plurality of transfer means and the corresponding image carrier. A first transfer means for biting the insulator to detect that the current detecting means detects the magnitude of the current flowing into the high voltage generating means in the state of being bitten; An image forming apparatus , wherein the resistance value of each first transfer unit is calculated by switching and performing each first transfer unit .

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