JP6439736B2 - Image forming apparatus - Google Patents

Description

  The present invention relates to an image forming apparatus including a fixing unit that fixes a toner image on a sheet that passes through a nip portion between a fixing member and a pressure member.

  In an image forming apparatus including a fixing unit that fixes a toner image on a sheet that passes through a nip portion between a fixing member and a pressure member, generally, the temperature of the fixing member detected by a temperature sensor becomes a target temperature. Be controlled. However, even if the temperature of the fixing member is controlled to be the target temperature, fixing failure or high temperature offset may occur due to variations in the temperature of the pressure member.

  In order to solve the above problems, an image forming apparatus is known in which the target temperature of the fixing member is switched according to the estimated value of the amount of heat stored in the pressure member (see, for example, Patent Document 1). . In this image forming apparatus, the time when it is detected that the pressure member and the fixing member are rotating and the absence of the sheet at the nip portion is integrated. Then, the accumulated time is regarded as an estimated value of the heat storage amount of the pressure member, and the target temperature of the fixing member is switched according to the accumulated time.

JP-A-8-146814

  However, the rate of increase in the temperature of the pressure member is not constant. For example, the rate of increase in the temperature of the pressure member differs between the state where the detected temperature has reached the target temperature and the state where it has not reached the target temperature. Therefore, the temperature change amount or temperature of the pressurizing member can be accurately determined only by integrating the time when it is detected that the pressurizing member and the fixing member are rotating and the absence of the sheet in the nip portion. Cannot be estimated.

  An object of the present invention is to provide an image forming apparatus capable of controlling a heating unit based on a temperature change amount or temperature of a pressure member estimated with high accuracy.

  An image forming apparatus according to one aspect of the present invention includes an image forming unit, a fixing unit, a temperature detection unit, a heating control unit, an estimation processing unit, and a temperature correction unit. The image forming unit forms a toner image on a sheet. The fixing unit includes a fixing member, a pressure member pressed against the fixing member, and a heating unit that heats the fixing member. The temperature detection unit detects the temperature of the fixing member. The heating control unit controls the heating unit such that a temperature detected by the temperature detection unit becomes a preset target temperature. The estimation processing unit estimates the temperature change amount of the pressure member by multiplying the duration of each of the plurality of operating states of the fixing unit by a coefficient set individually for each of the operating states, and at least During the period in which the fixing member is heated by the heating unit, the temperature change amount can be estimated using a coefficient selected based on the detected temperature among a plurality of predetermined coefficients. The temperature correction unit corrects the target temperature based on the temperature change amount estimated by the estimation processing unit.

  According to the present invention, there is provided an image forming apparatus capable of controlling the heating unit based on the temperature change amount or temperature of the pressure member estimated with high accuracy.

FIG. 1 is a diagram illustrating a configuration of an image forming apparatus according to an embodiment of the present invention. FIG. 2 is a block diagram showing a system configuration of the image forming apparatus according to the embodiment of the present invention. FIG. 3 is a diagram illustrating an example of continuous printing temperature information used in the image forming apparatus according to the embodiment of the present invention. FIG. 4 is a diagram for explaining the operation state of the fixing unit of the image forming apparatus according to the embodiment of the present invention. FIG. 5 is a diagram showing an example of operation history information used in the image forming apparatus according to the embodiment of the present invention. FIG. 6 is a flowchart illustrating an example of a processing procedure of the first estimation process executed by the image forming apparatus according to the embodiment of the present invention. FIG. 7 is a flowchart showing an example of the processing procedure of the second estimation processing executed by the image forming apparatus according to the embodiment of the present invention. FIG. 8 is a flowchart illustrating an example of a processing procedure of a third estimation process executed by the image forming apparatus according to the embodiment of the present invention. FIG. 9 is a diagram illustrating an example of a function for determining a heat radiation coefficient used in the image forming apparatus according to the embodiment of the present invention. FIG. 10 is a flowchart illustrating an example of a temperature correction process performed by the image forming apparatus according to the embodiment of the present invention.

  Embodiments of the present invention will be described below with reference to the drawings as appropriate. In addition, the following embodiment is only an example which actualized this invention, and does not limit the technical scope of this invention.

[Schematic configuration of image forming apparatus]
First, a schematic configuration of an image forming apparatus 1 (an example of an image forming apparatus of the present invention) according to an embodiment of the present invention will be described with reference to FIG.

  An image forming apparatus 1 shown in FIG. 1 is an image forming apparatus having various functions such as a printer, a copying machine, and a facsimile. The image forming apparatus 1 prints an image on a sheet S (an example of a sheet of the present invention) based on input image data. The image forming apparatus 1 includes an image reading unit 10 that reads an image of a document, and an electrophotographic image forming unit 20. In the present embodiment, the image forming apparatus 1 is described as an example of the image forming apparatus of the present invention. However, the present invention is not limited to this, and the present invention is also applied to, for example, a printer, a facsimile machine, and a copying machine. Is possible.

  The image reading unit 10 includes a contact glass 11 that forms a document placement surface, and a document cover 12 that opens and closes the contact glass 11. When the image forming apparatus 1 functions as a copying machine, when a copy start instruction is input from an operation panel (not shown) after a document is set on the contact glass 11 and the document cover 12 is closed, the image reading unit 10 Is started, and the image data of the document is read. The document cover 12 is provided with an ADF (Auto Document Feeder) 13 that automatically feeds a document to be read by the image reading unit 10.

  The image forming unit 20 is an electrophotographic image forming unit that performs image forming processing (printing processing) based on image data read by the image reading unit 10 or image data input from an external information processing apparatus. is there. As shown in FIG. 1, the image forming unit 20 includes a paper feed cassette 21, an image forming unit 22 (an example of the image forming unit of the present invention), a fixing unit 23 (an example of the fixing unit of the present invention), and a discharge unit. 24 etc.

  The sheets S accommodated in the sheet feeding cassette 21 are taken out one by one by a feeding mechanism including a feeding roller. The sheet S is conveyed along a conveyance path in the image forming unit 20, and is discharged to the discharge unit 24 through the image forming unit 22 and the fixing unit 23.

  The image forming unit 22 includes an exposure device, a photosensitive drum, a charging device, a developing device, a transfer roller, a cleaning blade, and a charge eliminating device. The sheet S passes through a nip portion between the photosensitive drum and the transfer roller. A toner image is formed on the surface.

  The fixing unit 23 includes a fixing roller 31 (an example of the fixing member of the present invention), a pressure roller 32 (an example of the pressure member of the present invention), a heater 33 (an example of the heating unit of the present invention), a temperature sensor 34, and A sheet sensor 35 is included.

  The fixing roller 31 transmits heat to the toner image formed on the sheet S and is rotatably supported. The fixing roller 31 is formed in a roller shape with a metal such as cylindrical stainless steel. Therefore, the fixing roller 31 has a small heat capacity and its temperature is raised in a relatively short time. The fixing roller 31 is rotated by a driving force from the driving motor 26 (see FIG. 2).

  The heater 33 heats the fixing roller 31 and is, for example, a halogen lamp. The heater 33 heats the fixing roller 31 from the inside by a resistance heating element such as tungsten. The heating unit of the present invention is not limited to a halogen lamp, and may be a ceramic heater, an induction heater, or the like.

  The pressure roller 32 is disposed in pressure contact with the fixing roller 31 at a position facing the fixing roller 31. The pressure roller 32 includes a cylindrical cored bar such as stainless steel, an elastic layer made of, for example, silicon resin formed on the cored bar, and a release layer made of a fluororesin or the like that covers the surface of the elastic layer. When the fixing roller 31 rotates, a driving force is transmitted from the fixing roller 31 to the pressure roller 32 through the nip portion between the pressure roller 32 and the fixing roller 31, and the pressure roller 32 also rotates.

  The temperature sensor 34 outputs a signal corresponding to the surface temperature of the fixing roller 31 to the control unit 25. The temperature sensor 34 is, for example, a thermistor.

  The control unit 25 includes control devices such as a CPU, a ROM, and a RAM. The CPU is a processor that executes various arithmetic processes. The ROM is a non-volatile storage unit in which information such as a control program for causing the CPU to execute various processes is stored in advance. The RAM is a volatile or nonvolatile storage unit used as a temporary storage memory (working area) for various processes executed by the CPU.

  Specifically, the control unit 25 includes a drive control unit 41, a temperature detection unit 42, a heating control unit 43, an estimation processing unit 44, and a temperature correction unit 45. The control unit 25 functions as each processing unit by executing various processes according to the control program. Further, the control unit 25 may include an electronic circuit that realizes a part or a plurality of processing functions of each processing unit.

  As shown in FIG. 2, the control unit 25 is electrically connected to a drive motor 26, a temperature sensor 34, a heater 33, a sheet sensor 35, a storage unit 27, and the like.

  The drive control unit 41 rotates the fixing roller 31 by controlling the drive motor 26.

  The temperature detector 42 detects the temperature of the fixing roller 31 based on a signal from the temperature sensor 34. In the present embodiment, the temperature detection unit 42 is provided near the surface of the fixing roller 31 at a central position in the axial direction of the fixing roller 31. Note that the temperature detection unit 42 may also be provided at the axial end of the fixing roller 31.

  The heating controller 43 controls the heater 33 so that the temperature detected by the temperature detector 42 becomes a preset target temperature. For example, the heating control unit 43 controls the heater 33 by a PWM method.

  The estimation processing unit 44 estimates the temperature change amount of the pressure roller 32 by multiplying the duration of each of the plurality of operation states of the fixing unit 23 by a coefficient set individually for each of the operation states. The operation state includes, for example, an operation mode of the fixing unit 23 (a warm-up mode, a printing mode, a post-printing state, etc., which will be described later), a relationship between the target temperature and the detected temperature, and the pressure member is driven. Whether or not the sheet S passes through the nip portion between the fixing roller 31 and the pressure roller 32 is distinguished by one or a plurality of combinations of conditions.

  The estimation processing unit 44 can also estimate the temperature of the pressure roller 32 based on the temperature change amount. For example, the estimation processing unit 44 performs the operation state in the duration of each of the plurality of operation states of the fixing unit 23 after the time point with respect to the estimated temperature of the pressure roller 32 calculated at a certain past time point. It is also possible to estimate the temperature of the pressure roller 32 at the present time by adding a temperature change amount estimated by multiplying each by a coefficient set individually.

  By the way, even if the temperature of the fixing roller 31 is controlled so as to become the target temperature, a fixing defect or a high temperature offset may occur due to variations in the temperature of the pressure roller 32. In order to solve such a problem, an image forming apparatus is known in which the target temperature of the fixing member (fixing roller 31) is switched according to the estimated value of the heat storage amount to the pressing member (pressure roller 32). ing. In this image forming apparatus, the time when it is detected that the pressure member and the fixing member are rotating and the absence of the sheet at the nip portion is integrated. Then, the accumulated time is regarded as an estimated value of the heat storage amount of the pressure member, and the target temperature of the fixing member is switched according to the accumulated time. However, the rate of increase in the temperature of the pressure roller 32 is not constant. For example, there is an increase in the state where the temperature detected by the temperature detection unit 42 has reached the target temperature in the heating control unit 43 and the state where it has not reached. The temperature rising speed of the pressure roller 32 is different. Therefore, the amount of change in temperature or the temperature of the pressure roller 32 can be determined simply by integrating the time when it is detected that the fixing roller 31 and the pressure roller 32 are rotating and the absence of the sheet S is present in the nip portion. Cannot be estimated with high accuracy.

  On the other hand, in the present embodiment, the estimation processing unit 44 is based on the temperature detected by the temperature detection unit 42 among a plurality of predetermined coefficients during at least the period when the fixing roller 31 is heated by the heater 33. The temperature change amount is estimated using a coefficient selected in the above.

  For example, the estimation processing unit 44 determines that the detected temperature becomes the target temperature during the period when the pressure roller 32 is being driven and the sheet S has not passed through the nip portion between the fixing roller 31 and the pressure roller 32. The continuation time of the state that has not been reached is multiplied by +6.0 (an example of the first temperature increase coefficient of the present invention). On the other hand, the estimation processing unit 44 detects the detected temperature at the target temperature during the period when the pressure roller 32 is being driven and the sheet S has not passed through the nip portion between the fixing roller 31 and the pressure roller 32. The continuation time of the reached state is multiplied by +1 (an example of the second temperature increase coefficient of the present invention).

  Thus, in this embodiment, since the temperature change amount of the pressure roller 32 is estimated using the coefficient selected based on the temperature detected by the temperature detection unit 42, the temperature change amount of the pressure roller 32 is increased. The accuracy can be estimated.

  Note that the coefficient used in the estimation processing unit 44 includes a temperature increase coefficient indicating a temperature rising speed of the pressure roller 32 and a heat dissipation coefficient indicating a temperature decreasing speed of the pressure roller 32. For example, when the pressure roller 32 is driven, the estimation processing unit 44 multiplies the duration of the state in which the sheet S does not pass through the nip portion by the temperature increase coefficient to estimate the temperature change amount. The temperature change amount is estimated by multiplying the duration of the state in which S passes through the nip portion by the heat dissipation coefficient.

  The temperature correction unit 45 corrects the target temperature based on the temperature change amount of the pressure roller 32 estimated by the estimation processing unit 44 or the temperature of the pressure roller 32. Thereby, in this embodiment, the heater 33 can be controlled based on the temperature change amount of the pressure roller 32 estimated with high accuracy.

  The sheet sensor 35 is a sensor for detecting the presence or absence of the sheet S, and is provided in the vicinity of the exit side of the nip portion. The estimation processing unit 44 can determine whether or not the sheet S is passing through the nip portion based on a signal from the sheet sensor 35.

  The storage unit 27 is a non-volatile storage unit such as an EEPROM (registered trademark). The storage unit 27 stores various control programs executed by the control unit 25, various data, and the like.

  For example, continuous printing temperature information 50 as shown in FIG. 3 is stored in the storage unit 27. The continuous printing temperature information 50 indicates a correspondence relationship between the type of the sheet S and the temperature of the pressure roller 32 when continuous printing of a predetermined number of sheets S or more is performed. When continuous printing of the sheet S is performed for a long time, the temperature of the pressure roller 32 is saturated to a certain temperature. This temperature (saturation temperature) depends on the type (for example, thickness) of the sheet S, for example. This saturation temperature is obtained in advance by experiment for each type of sheet S and stored as continuous printing temperature information 50. The estimation processing unit 44 can estimate the temperature of the pressure roller 32 based on the continuous printing temperature information 50 when continuous printing of a predetermined number or more sheets S is performed.

  The temperature correction unit 45 may correct the target temperature according to the difference between the temperature of the pressure roller 32 estimated by the estimation processing unit 44 and the temperature acquired from the continuous printing temperature information 50. The temperature correction unit 45 may subtract a correction amount calculated by multiplying the difference by a predetermined correction coefficient (for example, one third) from the target temperature.

[Estimation process]
Next, the estimation process executed by the control unit 25 (estimation processing unit 44) will be described. The estimation process is a process for estimating the temperature of the pressure roller 32.

  In the present embodiment, the operation mode of the fixing unit 23 includes a warm-up mode, a printing mode, and a post-printing mode, as shown in FIG. In the warm-up mode, the target temperature (hereinafter referred to as target temperature Ts) is set to 170 ° C., for example, and the fixing roller 31 is heated. In the printing mode, a fixing operation for fixing the toner image on the sheet S is performed in a state where the temperature of the fixing roller 31 is maintained at a desired temperature (printing temperature). The post-printing mode is an operation mode that is neither the warm-up mode nor the printing mode. In the post-printing mode, for example, by a timer control, the target temperature Ts is set to, for example, 150 ° C. (ready temperature) for a certain period after the printing is finished, and thereafter, the target temperature Ts is set to a stop state and the target temperature Ts is set. For example, it is set to 0 ° C. 4 shows the target temperature Ts, the detected temperature Td (that is, the detected temperature by the temperature detecting unit 42), the actual temperature of the fixing roller 31, and the actual temperature of the pressure roller 32. In order to explain each operation mode of the image forming apparatus 1, only an example of actual measurement values obtained by experiments is shown.

  In the estimation process, the temperature of the pressure roller 32 is estimated based on the operation history information 51 that records the transition of the operation state of the fixing unit 23. For example, as illustrated in FIG. 5, the operation history information 51 includes an operation mode of the fixing unit 23, a target temperature Ts, a detection temperature Td, a state of the drive motor 26, and a detection result of the sheet sensor 35 in time series with time. It is the recorded information. The operation history information 51 may be recorded in the RAM of the control unit 25 or may be recorded in the storage unit 27, for example. The operation history information 51 may be recorded at a constant time interval (for example, every 0.1 second), or when a predetermined condition is satisfied (for example, the operation mode of the fixing unit 23, the state of the drive motor 26). Or when the detected temperature Td reaches the target temperature Ts, etc.).

  In the present embodiment, the estimation process is executed at three timings: a timing immediately after the end of the warm-up mode, a timing immediately after the end of the printing mode, and a timing immediately after the start of the warm-up mode. Hereinafter, the estimation process executed at the timing immediately after the end of the warm-up mode is referred to as a first estimation process, the estimation process executed at the timing immediately after the end of the printing mode is referred to as a second estimation process, The estimation process executed at the timing immediately after the start of the warm-up mode is referred to as a third estimation process.

[First estimation process]
First, an example of the procedure of the first estimation process executed by the control unit 25 (estimation processing unit 44) will be described with reference to FIG. Here, steps S1, S2,... Represent processing procedure (step) numbers executed by the control unit 25.

<Step S1>
First, in step S <b> 1, the control unit 25 calculates the duration D <b> 1 based on the operation history information 51. The duration D1 is a duration in a state where the operation mode of the fixing unit 23 is the warm-up mode and the drive motor 26 is off (that is, the drive motor 26 is stopped).

<Step S2>
In step S2, the control unit 25 determines whether the detected temperature Td at the start of the warm-up mode is less than 60 ° C. based on the operation history information 51. And when it is judged that it is less than 60 degreeC (S2: Yes), a process will transfer to step S3. On the other hand, if it is determined that the temperature is 60 ° C. or higher (S2: No), the process proceeds to step S4.

<Step S3>
In step S3, the control unit 25 sets the heat dissipation coefficient Cd to 0. This is because the detected temperature Td at the start of the warm-up mode is less than 60 ° C. because the temperature of the pressure roller 32 is low and it is considered that there is almost no heat radiation from the pressure roller 32.

<Step S4>
In step S4, the control unit 25 sets the heat dissipation coefficient Cd to -3. This is because when the drive motor 26 is off, heat is not transmitted from the fixing roller 31 to the pressure roller 32, and the temperature of the pressure roller 32 is considered to decrease.

<Step S5>
In step S5, the control unit 25 calculates the temperature change amount ΔT1 of the pressure roller 32 based on the duration D1 calculated in step S1 and the heat dissipation coefficient Cd set in step S3 or step S4. presume. Specifically, the control unit 25 calculates the temperature change amount ΔT1 by multiplying the duration D1 by the heat dissipation coefficient Cd.

<Step S6>
In step S <b> 6, the control unit 25 calculates the duration D <b> 2 based on the operation history information 51. The duration D2 is a state in which the operation mode of the fixing unit 23 is the warm-up mode, the drive motor 26 is on (that is, the drive motor 26 is being driven), and the detected temperature Td is less than the target temperature Ts. Is the duration.

<Step S7>
In step S7, the control unit 25 sets the temperature increase coefficient Cu to 9. This is because, in the state where the detected temperature Td is lower than the target temperature Ts, the temperature of the pressure roller 32 is still low, and therefore the temperature rising speed of the pressure roller 32 is considered to be high.

<Step S8>
In step S8, the control unit 25 estimates the temperature change amount ΔT2 of the pressure roller 32 based on the duration D2 calculated in step S6 and the temperature increase coefficient Cu set in step S7. Specifically, the control unit 25 calculates the temperature change amount ΔT2 by multiplying the duration D2 by the temperature increase coefficient Cu (that is, 9).

<Step S9>
In step S <b> 9, the control unit 25 calculates the duration D <b> 3 based on the operation history information 51. The duration D3 is a duration in which the operation mode of the fixing unit 23 is the warm-up mode, the drive motor 26 is on, and the detected temperature Td is equal to or higher than the target temperature Ts.

<Step S10>
In step S10, the control unit 25 sets the temperature increase coefficient Cu to 0.3. This is because, in a state where the detected temperature Td is equal to or higher than the target temperature Ts, the temperature of the pressure roller 32 is also high, and therefore it is considered that the temperature rising speed of the pressure roller 32 is low.

<Step S11>
In step S11, the control unit 25 estimates the temperature change amount ΔT3 of the pressure roller 32 based on the duration time D3 calculated in step S9 and the temperature increase coefficient Cu set in step S10. Specifically, the control unit 25 calculates the temperature change amount ΔT3 by multiplying the duration D3 by the temperature increase coefficient Cu (that is, 0.3).

<Step S12>
In step S12, the control unit 25 applies pressure based on the temperature change amount ΔT1 calculated in step S5, the temperature change amount ΔT2 calculated in step S8, and the temperature change amount ΔT3 calculated in step S11. The temperature of the roller 32 is estimated. Specifically, the control unit 25 calculates the pressurization calculated by the estimation process executed immediately before (that is, the third estimation process executed immediately before) and stored in the RAM or the storage unit 27 or the like. The estimated temperature Tp of the pressure roller 32 is updated by adding the temperature change amount ΔT1, the temperature change amount ΔT2, and the temperature change amount ΔT3 to the estimated temperature Tp of the roller 32. The updated estimated temperature Tp is stored in the RAM or the storage unit 27 or the like. Then, the first estimation process ends.

[Second estimation process]
Next, an example of the procedure of the second estimation process executed by the control unit 25 (estimation processing unit 44) will be described with reference to FIG.

<Step S20>
First, in step S20, the control unit 25 determines whether the number of printed sheets in the printing process executed immediately before is less than 11. If it is determined that the number of printed sheets is less than 11 (S20: Yes), the process proceeds to step S21. On the other hand, if it is determined that the number of printed sheets is 11 or more (S20: No), the process proceeds to step S31.

<Step S21>
In step S <b> 21, the control unit 25 calculates the duration D <b> 4 based on the operation history information 51. In the duration D4, the operation mode of the fixing unit 23 is the printing mode, the sheet sensor 35 is off (that is, the sheet S does not pass through the nip portion), and the detection temperature Td is the target. This is the duration of the state where the temperature Ts has not been reached.

<Step S22>
In step S22, the control unit 25 sets the temperature increase coefficient Cu to 6. This is because, in a state where the detected temperature Td has not reached the target temperature Ts, the amount of heating by the heater 33 is large, so it is considered that the temperature rise rate of the pressure roller 32 is high.

<Step S23>
In step S23, the control unit 25 estimates the temperature change amount ΔT4 of the pressure roller 32 based on the duration D4 calculated in step S21 and the temperature increase coefficient Cu set in step S22. Specifically, the control unit 25 calculates the temperature change amount ΔT4 by multiplying the duration D4 by the temperature increase coefficient Cu (that is, 6).

<Step S24>
In step S <b> 24, the control unit 25 calculates the duration D <b> 5 based on the operation history information 51. The duration D5 is a duration in a state after the operation mode of the fixing unit 23 is the printing mode, the sheet sensor 35 is off, and the detected temperature Td reaches the target temperature Ts.

<Step S25>
In step S25, the control unit 25 sets the temperature increase coefficient Cu to 1. This is because in the state after the detected temperature Td has reached the target temperature Ts, the amount of heating by the heater 33 can be suppressed, so it is considered that the rate of temperature rise of the pressure roller 32 is low.

<Step S26>
In step S26, the control unit 25 estimates the temperature change amount ΔT5 of the pressure roller 32 based on the duration D5 calculated in step S24 and the temperature increase coefficient Cu set in step S25. Specifically, the control unit 25 calculates the temperature change amount ΔT5 by multiplying the duration D5 by the temperature increase coefficient Cu (that is, 1).

<Step S27>
In step S <b> 27, the control unit 25 calculates the duration D <b> 6 based on the operation history information 51. The duration D6 is a duration in a state where the operation mode of the fixing unit 23 is the printing mode and the sheet sensor 35 is on (that is, the sheet S is passing through the nip portion).

<Step S28>
In step S28, the control unit 25 sets the heat dissipation coefficient Cd to −12.8. This is because it is considered that the heat of the pressure roller 32 is taken away by the sheet S passing through the nip portion and the temperature of the pressure roller 32 is lowered.

<Step S29>
In step S29, the control unit 25 estimates the temperature change amount ΔT6 of the pressure roller 32 based on the duration D6 calculated in step S27 and the heat dissipation coefficient Cd set in step S28. Specifically, the control unit 25 calculates the temperature change amount ΔT6 by multiplying the duration D6 by the heat dissipation coefficient Cd (that is, −12.8).

<Step S30>
In step S30, the control unit 25 applies pressure based on the temperature change amount ΔT4 calculated in step S23, the temperature change amount ΔT5 calculated in step S26, and the temperature change amount ΔT6 calculated in step S29. The temperature of the roller 32 is estimated. Specifically, the control unit 25 calculates the pressurization calculated by the estimation process executed immediately before (that is, the first estimation process executed immediately before) and stored in the RAM or the storage unit 27 or the like. The estimated temperature Tp of the pressure roller 32 is updated by adding the temperature change amount ΔT4, the temperature change amount ΔT5, and the temperature change amount ΔT6 to the estimated temperature Tp of the roller 32. The updated estimated temperature Tp is stored in the RAM or the storage unit 27 or the like. Then, the second estimation process ends.

<Step S31>
In step S31, the control unit 25 estimates the temperature of the pressure roller 32 based on the continuous printing temperature information 50 shown in FIG. Specifically, the control unit 25 acquires the saturation temperature of the pressure roller 32 corresponding to the sheet type (thickness and size) in the printing process executed immediately before from the continuous printing temperature information 50. Then, the control unit 25 calculates the pressure roller 32 calculated by the estimation process executed immediately before (that is, the first estimation process executed immediately before) and stored in the RAM or the storage unit 27 or the like. The estimated temperature Tp is updated to the saturation temperature acquired from the continuous printing temperature information 50. The updated estimated temperature Tp is stored in the RAM or the storage unit 27 or the like. Then, the second estimation process ends.

[Third estimation process]
Next, an example of the procedure of the third estimation process executed by the control unit 25 (estimation processing unit 44) will be described with reference to FIG.

<Step S40>
First, in step S40, the control unit 25 determines whether or not the current detected temperature Td (that is, the detected temperature Td at the start of the warm-up mode) is less than 60 ° C. based on the operation history information 51. To do. And if it is judged that it is less than 60 degreeC (S40: Yes), a process will transfer to step S41. On the other hand, if it is determined that the temperature is 60 ° C. or higher (S40: No), the process proceeds to step S42.

<Step S41>
In step S41, the control unit 25 sets the estimated temperature Tp of the pressure roller 32 to the same temperature as the current detected temperature Td. This is because when the detected temperature Td at the start of the warm-up mode is lowered to less than 60 ° C., the temperature of the fixing roller 31 and the temperature of the pressure roller 32 are considered to be substantially the same. Because. The set estimated temperature Tp is stored in the RAM or the storage unit 27 or the like. Then, the third estimation process ends.

<Step S42>
In step S <b> 42, the control unit 25 determines whether or not the estimated temperature Tp of the pressure roller 32 is not set. If it is determined that the estimated temperature Tp is not set (S42: Yes), the process proceeds to step S43. On the other hand, if it is determined that the estimated temperature Tp has been set (S42: No), the process proceeds to step S44. The estimated temperature Tp is not set, for example, when the estimation process has not been executed in the image forming apparatus 1 or when the image forming apparatus 1 is turned off. A case where the estimated temperature Tp stored in the RAM disappears can be considered.

<Step S43>
In step S43, the control unit 25 sets the estimated temperature Tp of the pressure roller 32 to 60 ° C. When the estimated temperature Tp of the pressure roller 32 is not set, the estimated temperature Tp of the pressure roller 32 cannot be estimated with high accuracy. Therefore, here, the estimated temperature Tp of the pressure roller 32 is set to be low in order to prevent the target temperature from being excessively corrected by the temperature correction unit 45 and deteriorating the fixability. When the estimated temperature Tp of the pressure roller 32 is 60 ° C., the target temperature is not corrected by the temperature correction unit 45. The set estimated temperature Tp is stored in the RAM or the storage unit 27 or the like. Then, the third estimation process ends.

<Step S44>
In step S <b> 44, the control unit 25 calculates the duration D <b> 7 based on the operation history information 51. The duration time D7 is a duration time in which the operation mode of the fixing unit 23 is the post-printing state and the drive motor 26 is on. After completion of the post-printing state, “post-drive” may be performed in which the drive motor 26 is driven for a predetermined time in order to make the surface temperature of the pressure roller 32 uniform.

<Step S45>
In step S45, the control unit 25 sets the temperature increase coefficient Cu to 6. This is because the heat of the fixing roller 31 is transmitted to the pressure roller 32 during the post drive, and the temperature of the pressure roller 32 rises.

<Step S46>
In step S46, the controller 25 estimates the temperature change amount ΔT7 of the pressure roller 32 based on the duration D7 calculated in step S44 and the temperature increase coefficient Cu set in step S45. Specifically, the control unit 25 calculates the temperature change amount ΔT7 by multiplying the duration D7 by the temperature increase coefficient Cu (that is, 6).

<Step S47>
In step S47, the control unit 25 calculates the duration D8 based on the operation history information 51. The duration D8 is a duration in which the operation mode of the fixing unit 23 is the post-printing state, the drive motor 26 is off, and the target temperature Ts is a temperature other than 0 ° C. (for example, the ready temperature). is there.

<Step S48>
In step S48, the control unit 25 sets the heat dissipation coefficient Cd based on the non-sheet-passing state driving time Tt. The non-sheet-passing state driving time Tt is the cumulative driving time of the driving motor 26 from the time when the detected temperature Td becomes less than 60 ° C. to the current time (the duration of the state in which the driving motor 26 is on). This is the time excluding the time spent passing through the nip portion. Note that the non-sheet-passing state driving time Tt is an accumulation of the driving motor 26 from the later time point when the detected temperature Td becomes less than 60 ° C. or when the power source of the image forming apparatus 1 is turned on. It may be a time obtained by excluding the time during which the sheet S has passed through the nip portion from the driving time.

  Specifically, the control unit 25 determines the heat dissipation coefficient Cd by a function f1 as shown in FIG. 9 based on the non-paper passing state driving time Tt. When the non-sheet-passing state driving time Tt is short, the amount of heat stored in the pressure roller 32 is small, so the low acceleration of the temperature of the pressure roller 32 is fast, but as the non-sheet-passing state driving time Tt becomes longer, the pressure roller 32. Therefore, the low acceleration of the temperature of the pressure roller 32 becomes gentle. Therefore, as the function f1 shown in FIG. 9, the absolute value of the heat dissipation coefficient Cd is set to be smaller as the non-sheet-passing state driving time Tt is longer.

<Step S49>
In step S49, the control unit 25 estimates the temperature change amount ΔT8 of the pressure roller 32 based on the duration D8 calculated in step S47 and the heat dissipation coefficient Cd set in step S48. Specifically, the control unit 25 calculates the temperature change amount ΔT8 by multiplying the duration D8 by the heat dissipation coefficient Cd.

<Step S50>
In step S <b> 50, the control unit 25 calculates the duration D <b> 9 based on the operation history information 51. In the duration D9, the operation mode of the fixing unit 23 is the post-printing state, the drive motor 26 is off, and the target temperature Ts is 0 ° C. (that is, the heating by the heater 33 is completely stopped). This is the duration of the state (that is, the stop state).

<Step S51>
In step S51, the control unit 25 determines the heat dissipation coefficient Cd by a function f2 as shown in FIG. 9 based on the non-paper passing state driving time Tt. When the non-sheet-passing state driving time Tt is short, the amount of heat stored in the pressure roller 32 is small, so the low acceleration of the temperature of the pressure roller 32 is fast, but as the non-sheet-passing state driving time Tt becomes longer, the pressure roller 32. Therefore, the low acceleration of the temperature of the pressure roller 32 becomes gentle. Therefore, as the function f2 shown in FIG. 9, the heat dissipation coefficient Cd is set to be smaller as the non-sheet-passing state driving time Tt is shorter. Further, in the stopped state, the temperature of the pressure roller 32 is lower than that in the ready state, so the low acceleration of the temperature of the pressure roller 32 is gentle. Therefore, the heat dissipation coefficient Cd determined by the function f2 is set so that the absolute value is smaller than the heat dissipation coefficient Cd determined by the function f1.

<Step S52>
In step S52, the controller 25 estimates the temperature change amount ΔT9 of the pressure roller 32 based on the duration time D9 calculated in step S50 and the heat dissipation coefficient Cd set in step S51. Specifically, the control unit 25 calculates the temperature change amount ΔT9 by multiplying the duration D9 by the heat dissipation coefficient Cd.

<Step S53>
In step S53, the control unit 25 applies pressure based on the temperature change amount ΔT7 calculated in step S46, the temperature change amount ΔT8 calculated in step S49, and the temperature change amount ΔT9 calculated in step S52. The temperature of the roller 32 is estimated. Specifically, the control unit 25 calculates the pressurization calculated by the estimation process executed immediately before (that is, the second estimation process executed immediately before) and stored in the RAM, the storage unit 27, or the like. The estimated temperature Tp of the pressure roller 32 is updated by adding the temperature change amount ΔT7, the temperature change amount ΔT8, and the temperature change amount ΔT9 to the estimated temperature Tp of the roller 32. The updated estimated temperature Tp is stored in the RAM or the storage unit 27 or the like. Then, the third estimation process ends.

  As described above, in the present embodiment, the estimated temperature Tp of the pressure roller 32 is updated as needed according to the operation state of the fixing unit 23 while the image forming apparatus 1 is powered on. In particular, in this embodiment, the temperature change amount of the pressure roller 32 is estimated by multiplying the duration of each of the plurality of operation states of the fixing unit 23 by a coefficient set individually for each of the operation states. The amount of temperature change or temperature of the pressure roller 32 can be estimated with high accuracy.

  In the present embodiment, when continuous printing of a predetermined number of sheets (for example, 11 sheets) or more is performed, the estimated temperature Tp of the pressure roller 32 is updated based on the continuous printing temperature information 50. The Therefore, it is possible to prevent the deviation between the estimated temperature Tp of the pressure roller 32 and the actual temperature of the pressure roller 32 from gradually increasing.

  As another method for correcting the deviation between the estimated temperature Tp of the pressure roller 32 and the actual temperature, for example, when the calculated estimated temperature Tp exceeds the detected temperature Td, the estimated temperature Tp is detected temperature. The temperature may be updated to Td or lower. This is because the temperature of the pressure roller 32 basically does not exceed the temperature of the fixing roller 31 that is a heat source for the pressure roller 32.

  As still another method for correcting the deviation between the estimated temperature Tp of the pressure roller 32 and the actual temperature, for example, when a long time has passed in the ready state, the pressure roller 32 is changed according to the elapsed time. The estimated temperature Tp may be updated. When a long time has passed in the ready state, the temperature of the pressure roller 32 is saturated to a certain temperature according to the elapsed time. Therefore, if information on the saturation temperature for each elapsed time is obtained in advance by experiment and stored in the storage unit 27 or the like, the estimation processing unit 44 can determine whether the elapsed time has elapsed for a long time in the ready state. The temperature of the pressure roller 32 can be estimated based on the saturation temperature information.

[Temperature correction processing]
Next, temperature correction processing executed by the control unit 25 (temperature correction unit 45) will be described. The temperature correction process is a process of correcting the target temperature Ts (the printing temperature) during the printing process according to the estimated temperature Tr of the pressure roller 32.

  With reference to FIG. 10, an example of the procedure of the temperature correction process executed by the control unit 25 (temperature correction unit 45) will be described.

<Step S60>
First, in step S60, the control unit 25 obtains the estimated temperature Tp of the pressure roller 32 estimated by the estimation processing unit 44 and the temperature acquired from the continuous printing temperature information 50 according to the type of the sheet S to be printed. Calculate the difference from (saturation temperature). Specifically, the control unit 25 calculates a value obtained by subtracting the saturation temperature from the estimated temperature Tp as the difference. For example, when the estimated temperature Tp is 110 ° C. and the sheet S to be printed is a “normal 1” B5 size sheet S, the difference is calculated based on the continuous printing temperature information 50 shown in FIG. 110 ° C.-95 ° C. = 15 ° C. That is, the difference increases as the estimated temperature Tp increases.

<Step S61>
In step S61, the control unit 25 calculates a temperature correction amount by multiplying the difference calculated in step S60 by a predetermined correction coefficient. The correction coefficient is a coefficient indicating how much the target temperature Ts should be decreased when the temperature of the pressure roller 32 is increased by 1 ° C., and the optimum value varies depending on the configuration of the fixing unit 23. For example, when using the fixing unit 23, which preferably reduces the target temperature Ts by 1 ° C. when the temperature of the pressure roller 32 increases by 3 ° C., the correction coefficient is 1/3 (= 0.333). Is preferably set. For example, when the difference calculated in step S60 is 15, and the correction coefficient is 1/3, the temperature correction amount is 15 ° C./3=5° C. The correction coefficient may be set to a different value depending on the type of the sheet S.

<Step S62>
In step S62, the control unit 25 determines whether or not the sheet S to be printed is the first sheet. When it is determined that the sheet S to be printed is the first sheet S (S62: Yes), the process proceeds to step S63. On the other hand, if it is determined that the sheet S to be printed is the second and subsequent sheets S (S62: No), the process proceeds to step S64.

<Step S63>
In step S63, the control unit 25 corrects the target temperature Ts by subtracting the temperature correction amount calculated in step S61 from the target temperature Ts (printing temperature) set in the heating control unit 43. For example, when the target temperature Ts set in the heating control unit 43 is 180 ° C. and the temperature correction amount calculated in step S61 is 5 ° C., the corrected target temperature Ts is 180 ° C.−5. ° C = 175 ° C.

<Step S64>
In step S64, the control unit 25 subtracts one half of the temperature correction amount calculated in step S61 from the target temperature Ts (printing temperature) set in the heating control unit 43, thereby obtaining the target temperature Ts. Correct. However, the target temperature Ts is corrected so as to be higher than the corrected target temperature Ts for the immediately preceding sheet S by a predetermined minimum rising temperature (for example, 3 ° C.) or more. Therefore, for example, the corrected target temperature Ts for the immediately preceding sheet S is 174 ° C., the target temperature Ts set in the heating control unit 43 is 180 ° C., and the temperature correction amount calculated in step S61 is 5 When it is ° C., the corrected target temperature Ts is 180 ° C .− (5 ° C./2)=177.5° C. Further, the corrected target temperature Ts for the immediately preceding sheet S is 175 ° C., the target temperature Ts set in the heating control unit 43 is 180 ° C., and the temperature correction amount calculated in step S 61 is 5 ° C. In some cases, the corrected target temperature Ts is 175 ° C. + 3 ° C. (minimum rising temperature) = 178 ° C. Thus, the correction amount for the second and subsequent sheets S is made smaller than the correction amount for the first sheet S (that is, the corrected target temperature Ts for the second and subsequent sheets S is set to the first sheet S). By making the temperature higher than the corrected target temperature Ts for the sheet S), it is possible to prevent the fixing temperature from being excessively lowered during continuous printing and the fixing property from being deteriorated.

<Step S65>
In step S65, the control unit 25 determines whether or not the printing process for all sheets S has been completed. When it is determined that the printing process for all sheets S has been completed (S65: Yes), the temperature correction process is completed. On the other hand, if it is determined that there is an unprocessed sheet S (S65: No), the process returns to step S62.

  Note that, for example, an upper limit may be set for the temperature correction amount in order to prevent the fixability from being deteriorated due to excessive correction of the target temperature Ts by the temperature correction processing. Alternatively, an arbitrary correction value may be added to the corrected target temperature Ts as the fixability ensuring correction value. Alternatively, the fixability ensuring correction value may be set to a different value depending on the type of the sheet S.

  The target temperature set by the heating control unit 43 is changed stepwise from a relatively low target temperature (initial temperature) to a relatively high target temperature (final temperature) as the printing process proceeds. Sometimes. In this case, for example, the temperature obtained by subtracting the temperature correction amount from the final temperature may be compared with the initial temperature, and the lower temperature may be adopted as the corrected target temperature. Thereby, even when intermittent printing continues, high temperature offset can be suppressed. Further, in order to suppress fixing failure due to excessive reduction of the target temperature, the lower limit of the corrected target temperature may be set to a temperature lower than the initial temperature by a predetermined temperature (for example, 15 ° C.).

DESCRIPTION OF SYMBOLS 1 Image forming apparatus 20 Image forming part 23 Fixing part 31 Fixing roller 32 Pressure roller 33 Heater 34 Temperature sensor 35 Sheet sensor S Sheet D1-D9 Duration Ts Target temperature Td Detection temperature Cd Heat dissipation coefficient Cu Temperature increase coefficient ΔT1-ΔT9 Temperature Change amount Tp Estimated temperature Tt Non-sheet-passing state drive time

Claims (9)

An image forming unit for forming a toner image on a sheet;
A fixing unit including a fixing member, a pressure member pressed against the fixing member, and a heating unit for heating the fixing member;
A temperature detector for detecting the temperature of the fixing member;
A heating control unit that controls the heating unit such that the temperature detected by the temperature detection unit becomes a preset target temperature;
The temperature change amount of the pressure member can be estimated by multiplying the duration of each of the plurality of operation states of the fixing unit by a coefficient set individually for each of the operation states, and at least the fixing member in a period which is heated by the heating unit, in advance a plurality of said coefficients for each of each of the operation state is set, using a predetermined coefficient which is selected based on the plurality of coefficients sac Chi before Symbol detection temperature An estimation processing unit capable of estimating the temperature change amount and estimating the temperature of the pressure member using the estimated temperature change amount ;
A temperature correction unit that corrects the target temperature based on the temperature of the pressure member estimated by the estimation processing unit;
An image forming apparatus comprising: The estimation processing unit is configured to calculate a first of the plurality of coefficients during a period in which the detected temperature does not reach the target temperature during a period in which the pressure member is being driven and the sheet has not passed. Multiplying by one temperature increase coefficient, and multiplying the duration of the state where the detected temperature reaches the target temperature by a second temperature increase coefficient smaller than the first temperature increase coefficient among the plurality of coefficients, We estimate the amount of temperature change,
The image forming apparatus according to claim 1. The estimation processing unit, to the temperature of the pressure member estimated some time in the past, been estimated by multiplying the coefficient duration of each of the plurality of operating states of the fixing portion in later the time that the temperature variation is added, Ru estimated Teisu the temperature of the pressure member at the present time,
The image forming apparatus according to claim 1. The coefficient includes a temperature increase coefficient indicating a temperature increase rate of the pressure member and a heat dissipation coefficient indicating a temperature decrease rate of the pressure member.
The image forming apparatus according to claim 1. The estimation processing unit multiplies the duration of the state in which the sheet does not pass through the nip portion between the fixing member and the pressure member while driving the pressure member by multiplying the temperature increase coefficient. A temperature change amount is estimated, and the temperature change amount is estimated by multiplying the duration of the state in which the sheet passes through the nip portion by the heat dissipation coefficient,
The image forming apparatus according to claim 4. The estimation processing unit, when continuous printing of a predetermined number of sheets or more, is performed, based on continuous printing temperature information indicating a correspondence relationship between the type of the sheet and the temperature of the pressure member. The temperature of the pressure member can be estimated,
The image forming apparatus according to claim 1. Before SL temperature correction unit, wherein the temperature of the pressurizing member, which is estimated by the estimation processing unit, wherein the sheet type and the pressure member when the continuous printing of a predetermined number or more sheets were made Correcting the target temperature according to the difference from the temperature acquired from the continuous printing temperature information indicating the correspondence relationship with the temperature,
The image forming apparatus according to claim 1. The temperature correction unit subtracts a correction amount calculated by multiplying the difference by a predetermined correction coefficient from the target temperature.
The image forming apparatus according to claim 7. The operation state includes an operation mode of the fixing unit, a relationship between the target temperature and the detected temperature, whether or not the pressure member is driven, and a nip between the fixing member and the pressure member. Divided by any one or a combination of conditions including whether or not passing
The image forming apparatus according to claim 1.

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