This application claims priority from Japanese Patent Application No. 2022-061544 filed on Apr. 1, 2022. The entire content of the priority application is incorporated herein by reference.
Conventionally, an image-forming apparatus has been provided with an internal temperature sensor and an ambient temperature sensor. When the difference between detection results from the internal temperature sensor and detection results from the ambient temperature sensor is greater than or equal to a prescribed temperature, the image-forming apparatus reports that the installation location of the image-forming apparatus is inappropriate.
However, even when installed in a suitable location, the conventional image-forming apparatus may erroneously determine that the installation location is inappropriate if the temperature around the device were to change due to the effects of air conditioning or the like.
In view of the foregoing, it is an object of the present disclosure to provide an image-forming apparatus capable of accurately detecting whether the installation location of the device is inappropriate.
In order to attain the above and other object, according to one aspect, the present disclosure provides an image-forming apparatus including: a main casing; a photosensitive drum; a developing roller; a heater; a first sensor; a second sensor; and a controller. The main casing includes: a first side wall; and a second side wall. The first side wall has an exhaust port. The second side wall is disposed on an opposite side of the first side wall in a prescribed direction. The developing roller is configured to supply toner to the photosensitive drum. The heater is configured to apply heat to a sheet to which toner is transferred from the photosensitive drum to fix the transferred toner to the sheet. The first sensor is disposed near the first side wall on the same side as the exhaust port with respect to the first side wall and is separated from the exhaust port. The first sensor is configured to measure a first temperature and a relative humidity. The second sensor is disposed near the second side wall and is separated from the heater. The second sensor is configured to measure a second temperature. The controller is configured to perform: (a) calculating; (b) determining; and (c) executing. The calculating in (a) calculates an internal temperature on the basis of the second temperature. The internal temperature is an estimated value of a temperature near the developing roller. The calculating includes: when a target temperature of the is set to a printing temperature: (a-1) determining; and (a-2) correcting. The determining in (a-1) determines whether a temperature increase in the first temperature is greater than or equal to a first prescribed value and a humidity increase in an absolute humidity is greater than or equal to a second prescribed value. The temperature increase in the first temperature indicates an amount of increase in a current first temperature relative to a previous first temperature. The current first temperature is the first temperature last measured by the first sensor. The previous first temperature is the first temperature measured by the first sensor a prescribed time before the current first temperature is measured. The absolute humidity is calculated on the basis of the relative humidity. The humidity increase in the absolute humidity indicates an amount of increase in a current absolute humidity relative to a previous absolute humidity. The current absolute humidity is based on a current relative humidity. The previous absolute humidity is based on a previous relative humidity. The current relative humidity is the relative humidity last measured by the first sensor. The previous relative humidity is the relative humidity measured by the first sensor the previous time before the timing at which the current relative humidity is measured. The correcting in (a-2) corrects, in response to determining in (a-1) that the temperature increase in the first temperature is greater than or equal to the first prescribed value and the humidity increase in the absolute humidity is greater than or equal to the second prescribed value, the internal temperature. The determining in (b) determines whether the internal temperature is greater than a first threshold. The executing in (c) executes, in response to determining in (b) that the internal temperature is greater than the first threshold, a cool-down process to reduce a temperature inside the main casing.
In the above structure, the image-forming apparatus corrects the estimated value of the temperature near the developing roller based on not only the temperature increase in the first temperature over the prescribed time but also the humidity increase in the absolute humidity over the prescribed time.
In a case where a printing process is being executed, moisture in a sheet is evaporated when the sheet is heated by the heater.
Therefore, in a case where the image-forming apparatus is installed in an inappropriate location, moisture in the main casing is not exhausted from the main casing and may cause the absolute humidity in the main casing to increase excessively.
When the image-forming apparatus is installed in an appropriate location, on the other hand, moisture in the main casing is properly exhausted from the main casing, thereby suppressing an increase in the absolute humidity in the main casing.
Therefore, in a case where the installation location of the image-forming apparatus is appropriate and the ambient temperature near the image-forming apparatus has increased due to an air conditioner or the like, the humidity increase in the absolute humidity within the main casing will be less than the second prescribed value.
As a result, the controller can accurately detect whether the installation location of the image-forming apparatus is appropriate.
An overview of an image-forming apparatus 1 will be described with reference to
The image-forming apparatus 1 is provided with a main casing 2, a sheet accommodating unit 3, a photosensitive drum 4, a charging device 5, an exposure device 6, a developing cartridge 7, a transfer device 8, and a fixing device 9.
The main casing 2 accommodates the sheet accommodating unit 3, photosensitive drum 4, charging device 5, exposure device 6, developing cartridge 7, transfer device 8, and fixing device 9.
The sheet accommodating unit 3 can accommodate sheets S. The sheets S are sheets of printing paper, for example. The sheets S are conveyed from the sheet accommodating unit 3 toward the photosensitive drum 4.
The photosensitive drum 4 has a cylindrical shape. The photosensitive drum 4 extends in a first direction (see
The charging device 5 electrically charges the surface of the photosensitive drum 4. The charging device 5 is a scorotron charger. Alternatively, the charging device 5 may be a charging roller.
The exposure device 6 exposes the surface of the photosensitive drum 4 that has been charged by the charging device 5. The exposure device 6 is a laser scanning unit. Alternatively, the exposure device 6 may be an LED array.
The developing cartridge 7 can be mounted inside the main casing 2. The developing cartridge 7 supplies toner onto the photosensitive drum 4. Specifically, the developing cartridge 7 supplies toner onto the surface of the photosensitive drum 4 after the surface has been exposed by the exposure device 6. The developing cartridge 7 has a developing housing 71, a developing roller 72, and a thickness regulating blade 73. In other words, the image-forming apparatus 1 has a developing roller 72.
The developing housing 71 can accommodate toner.
The developing roller 72 can supply toner from the developing housing 71 onto the surface of the photosensitive drum 4. The developing roller 72 is in contact with the photosensitive drum 4. The developing roller 72 may also be separated from the photosensitive drum 4 by a prescribed distance. The developing roller 72 has a cylindrical shape. The developing roller 72 extends in the first direction. The developing roller 72 is rotatable about an axis A2. The axis A2 is aligned in the first direction.
The thickness regulating blade 73 regulates the thickness of toner carried on the developing roller 72. When the temperature of the thickness regulating blade 73 rises excessively, toner on the developing roller 72 may melt due to the heat from the thickness regulating blade 73, causing toner to adhere to the thickness regulating blade 73. When the amount of toner adhering to the thickness regulating blade 73 becomes excessive, irregularities may appear in the printed images. Therefore, it is necessary to regulate the temperature of the thickness regulating blade 73.
The transfer device 8 transfers toner from the photosensitive drum 4 onto sheets S. In the present embodiment, the transfer device 8 has a transfer roller 81.
The transfer roller 81 is in contact with the photosensitive drum 4. The transfer roller 81 may also be separated from the photosensitive drum 4 by a prescribed distance. Sheets S in the sheet accommodating unit 3 are conveyed between the photosensitive drum 4 and transfer roller 81 toward the fixing device 9. The transfer roller 81 transfers toner from the photosensitive drum 4 onto a sheet S as the sheet S passes between the photosensitive drum 4 and the transfer roller 81. The transfer roller 81 has a cylindrical shape. The transfer roller 81 extends in the first direction. The transfer roller 81 is rotatable about an axis A3. The axis A3 is aligned in the first direction. Alternatively, the transfer device 8 may be configured with a transfer belt.
The fixing device 9 applies heat and pressure to a sheet S after toner has been transferred to the sheet S from the photosensitive drum 4. The fixing device 9 fixes the toner to the sheet S with heat. After passing through the fixing device 9, the sheet S is discharged onto the top surface of the main casing 2.
Next, the image-forming apparatus 1 will be described in greater detail with reference to
As illustrated in
The main casing 2 has two side walls 21A and 21B, and two inner walls 22A and 22B.
The side wall 21A is an outer wall of the main casing 2 on one side in the first direction. That is, the side wall 21A is located on one end portion of the main casing 2 in the first direction. The side wall 21A extends in the up-down direction and a second direction. The second direction crosses both the first direction and the up-down direction. More specifically, the second direction is orthogonal to the first direction and the up-down direction. The side wall 21A has an exhaust port 23.
The side wall 21B is an outer wall of the main casing 2 on the other side of the first direction. That is, the side wall 21B is located on the other end portion of the main casing 2 in the first direction. Hence, the side wall 21B is disposed on the opposite side of the side wall 21A in the first direction, and is separated from the side wall 21A in the first direction. The side wall 21B extends in the up-down direction and in the second direction.
The inner wall 22A is positioned between the side wall 21A and side wall 21B in the first direction. The inner wall 22A is separated from the side wall 21A in the first direction. The inner wall 22A extends in the up-down direction and in the second direction.
The inner wall 22B is positioned between the inner wall 22A and side wall 21B in the first direction. The inner wall 22B is separated from the inner wall 22A in the first direction. The inner wall 22B extends in the up-down direction and in the second direction. The photosensitive drum 4, developing cartridge 7, and fixing device 9 are located between the inner wall 22A and inner wall 22B in the first direction.
The first sensor 11 is positioned near the side wall 21A of the main casing 2 in the first direction. The first sensor 11 is disposed between the side wall 21A and inner wall 22A in the first direction. The first sensor 11 is separated from the fixing device 9 in the second direction. Specifically, the first sensor 11 is positioned on the opposite side of the photosensitive drum 4 from the fixing device 9 in the second direction. The first sensor 11 is also separated from the exhaust port 23 in the second direction. Specifically, the first sensor 11 is positioned on the opposite side of the photosensitive drum 4 from the exhaust port 23. The first sensor 11 can measure a first temperature and the relative humidity.
The second sensor 12 is positioned near the side wall 21B of the main casing 2 in the first direction. The second sensor 12 is disposed between the side wall 21B and inner wall 22B in the first direction. The second sensor 12 is separated from the fixing device 9 in the second direction. The second sensor 12 is at the same position as the developing roller 72 in the second direction. The second sensor 12 can measure a second temperature. The second temperature differs from the temperature of the thickness regulating blade 73, which is in proximity to or in contact with the developing roller 72.
As illustrated in
As illustrated in
As illustrated in
Next, control of the image-forming apparatus 1 will be described with reference to
When the image-forming apparatus 1 is installed in an inappropriate location, the control unit 13 increases the frequency of a cool-down process. One case of the image-forming apparatus 1 being installed inappropriately is when the exhaust port 23 faces a wall.
In the cool-down process, the control unit 13 halts the supply of power to the fixing device 9 and reduces the temperature inside the main casing 2 by setting the target temperature of the fixing device 9 lower than a setting value for printing (hereinafter referred to as “printing temperature”) and preventing the next sheet S from being fed, for example.
When the image-forming apparatus 1 enters an operating state, in S1 of
Next, the control unit 13 executes an inappropriate installation detection process in S2. The inappropriate installation detection process is performed for detecting whether the installation location of the image-forming apparatus 1 is inappropriate.
In S21 at the beginning of
Here, the increase ΔTout in the first temperature indicates an amount of increase in a current first temperature relative to a previous first temperature. The current first temperature is a first temperature last measured by the first sensor 11. The previous first temperature is a first temperature measured by the first sensor 11 a first time before the timing at which the current first temperature is measured. The increase ΔH in the absolute humidity indicates an amount of increase in a current absolute humidity relative to a previous absolute humidity. The current absolute humidity is an absolute humidity based on the current relative humidity last measured by the first sensor 11. The previous absolute humidity is an absolute humidity based on a previous relative humidity measured by the first sensor 11 the first time before the timing at which the current relative humidity is measured.
When the increase ΔTout is less than a first prescribed value T1 or the increase ΔH is less than a second prescribed value H (S21: NO), the control unit 13 determines that the installation location of the image-forming apparatus 1 is appropriate.
However, when the increase ΔTout is greater than or equal to the first prescribed value T1 and the increase ΔH is greater than or equal to the second prescribed value H (S21: YES), the control unit 13 determines that the installation location of the image-forming apparatus 1 is inappropriate.
The first time is 1500 seconds, for example. The first prescribed value T1 is 4° C., for example. The second prescribed value H is 2 g/cm3, for example.
When the control unit 13 determines that the installation location of the image-forming apparatus 1 is appropriate (S21: NO), in S22 the control unit 13 checks whether the flag is “0”.
When the flag is “1” (S22: NO), in S23 the control unit 13 sets the flag to “0”.
After changing the flag from “1” to “0”, in S23 the control unit 13 also sets an elapsed time TG to “0” and begins measuring the elapsed time TG. The control unit 13 also stores a correction value ΔR at the timing of executing the process in S23 as the correction value ΔR0 immediately before the flag is changed. The control unit 13 also stores an internal temperature TH at the timing of executing the process in S23 as the internal temperature TH0 immediately before the flag is changed. The correction value ΔR is calculated in a subsequent process S26, S27, S32, or S33. Further, the internal temperature TH is calculated in a subsequent process S6, S7, S12, or S13.
On the other hand, the control unit 13 skips the process in S23 when the flag is “0” (S22: YES).
In S24 the control unit 13 removes a displayed message indicating that the installation location of the image-forming apparatus 1 is inappropriate. That is, when a message indicating that the image-forming apparatus 1 is installed in an inappropriate location is currently displayed on the display unit 14 (the case of S22: NO), the control unit 13 removes this message. However, if no such message is displayed on the display unit 14 (the case of S22: YES), the control unit 13 takes no further action.
Thereafter, the control unit 13 calculates the correction value ΔR. The correction value ΔR is used for calculating the internal temperature TH described later.
While the elapsed time TG is no greater than a prescribed time T2 (S25: NO), the control unit 13 executes a first correction value calculation process in S26.
The prescribed time T2 is 20 seconds, for example.
In the first correction value calculation process, the control unit 13 calculates the correction value ΔR using the following formula (1).
Correction value ΔR=correction value ΔR0×(1−elapsed time TG/prescribed time T2) Formula (1):
In other words, the correction value ΔR changes at regular intervals.
However, when the elapsed time TG exceeds the prescribed time T2 (S25: YES), in S27 the control unit 13 sets the correction value ΔR to “0”.
After completing the process for calculating and setting the correction value ΔR of S26 or S27, the control unit 13 ends the inappropriate installation detection process of S2.
When the control unit 13 determines that the installation location of the image-forming apparatus 1 is inappropriate (S21: YES), in S28 the control unit 13 confirms whether the flag is “1”.
If the flag is “0” (S28: NO), in S29 the control unit 13 sets the flag to “1”.
Further, after changing the flag from “0” to “1”, in S29 the control unit 13 also sets an elapsed time TNG to “0” and begins measuring the elapsed time TNG. In S29 the control unit 13 also stores the correction value ΔR at the timing of executing the process in S29 as the correction value ΔR0 immediately before the flag is changed. In S29 the control unit 13 also stores the internal temperature TH at the timing of executing the process in S29 as the internal temperature TH0 immediately before the flag is changed.
On the other hand, when the flag is “1” (S28: YES), the control unit 13 skips the process in S29.
In S30 the control unit 13 displays a message indicating that the installation location of the image-forming apparatus 1 is inappropriate. Thus, when the current first temperature has increased by the first prescribed value T1 or greater compared to the previous first temperature the first time ago and the current absolute humidity has increased by the second prescribed value H or greater compared to the previous absolute humidity the first time ago (S21: YES), the control unit 13 displays a message on the display unit 14 indicating that the installation location of the image-forming apparatus 1 is inappropriate. Here, the control unit 13 may also display a message on the display unit 14 indicating that the length of time before executing a cool-down process will be shortened.
Specifically, when a message indicating that the installation location of the image-forming apparatus 1 is inappropriate is not currently displayed on the display unit 14 (the case of S28: NO), the control unit 13 displays a message on the display unit 14 indicating that the installation location of the image-forming apparatus 1 is inappropriate. However, when a message indicating the installation location is inappropriate is already displayed on the display unit 14 (the case of S28: YES), the control unit 13 simply maintains that display.
Thereafter, the control unit 13 calculates the correction value ΔR.
When the elapsed time TNG is less than or equal to the prescribed time T2 (S31: NO), the control unit 13 executes a second correction value calculation process in S32.
In the second correction value calculation process, the control unit 13 calculates the correction value ΔR according to the following formula (2).
Correction value ΔR=2×(elapsed time TNG/prescribed time T2)+correction value ΔR0×(1−elapsed time TNG/prescribed time T2) Formula (2):
On the other hand, when the elapsed time TNG exceeds the prescribed time T2 (S31: YES), in S33 the control unit 13 sets the correction value ΔR to “2”.
After completing the process for calculating and setting the correction value ΔR, the control unit 13 ends the inappropriate installation detection process of S2.
Next, returning to the process of
When the target temperature of the fixing device 9 is set to the printing temperature, i.e., when printing is in progress (S3: YES), in S4 the control unit 13 sets the elapsed time Tm since the target temperature of the fixing device 9 is no longer set to the printing temperature to “0”. In S5 the control unit 13 determines whether the elapsed time Tn since the target temperature of the fixing device 9 is set to the printing temperature is no greater than a prescribed time Tn1. When the elapsed time Tn is greater than the prescribed time Tn1 (S5: NO), the control unit 13 executes a first internal temperature calculation process in S6.
The prescribed time Tn1 is 20 seconds, for example.
In the first internal temperature calculation process of S6, the control unit 13 corrects the internal temperature TH according to the following formula (A). Thus, when the target temperature of the fixing device 9 is set to the printing temperature (S3: YES) and the current first temperature has risen by the first prescribed value T1 or greater compared to the previous first temperature the first time ago while the current absolute humidity has increased by the second prescribed value H or greater compared to the previous absolute humidity the first time ago (S21: YES), the control unit 13 corrects the internal temperature TH according to the formula (A).
Internal temperature TH=a×log(second temperature)2+b×log(second temperature)+c+correction value ΔR Formula (A):
In the above formula (A), “a×log(second temperature)2+b×log(second temperature)+c” indicates the uncorrected internal temperature TH. An internal temperature TH not subjected to correction has been calculated on the basis of the second temperature. Thus, in the correction process the control unit 13 adds the correction value ΔR, which changes at regular intervals, to the uncorrected internal temperature TH. In this way, in the correction process the control unit 13 sets the internal temperature TH higher than the value calculated on the basis of the second temperature. Note that a, b, and c are coefficients found through multiple regression analysis of experimental results.
However, when the elapsed time Tn is less than or equal to the prescribed time Tn1 (S5: YES), the control unit 13 executes a second internal temperature calculation process in S7.
In the second internal temperature calculation process of S7, the control unit 13 corrects the internal temperature TH according to the following formula (B).
Internal temperature TH={a×log(second temperature)2+b×log(second temperature)+c+correction value ΔR}×Tn÷Tn1+TH0×(Tn1−Tn)÷Tn1 Formula (B):
Further, when the target temperature of the fixing device 9 is not set to the printing temperature, i.e., when printing is not in progress (S3: NO), in S8 the control unit 13 sets the elapsed time Tn since the target temperature of the fixing device 9 is set to the printing temperature to “0”. In S9 the control unit 13 determines whether the elapsed time Tm since the target temperature of the fixing device 9 is no longer set to the printing temperature is less than or equal to a prescribed time Tm1. When the elapsed time Tm is less than or equal to the prescribed time Tm1 (S9: YES), the control unit 13 executes a third internal temperature calculation process in S10.
The prescribed time Tm1 is 400 seconds, for example.
In the third internal temperature calculation process of S10, the control unit 13 calculates the internal temperature TH according to the following formula (C). The control unit 13 does not use the correction value ΔR to correct the internal temperature TH in the third internal temperature calculation process of S10 and a fourth internal temperature calculation process of S11 described later.
Internal temperature TH=TH0×(Tm1−Tm)÷Tm1+second temperature×Tm÷Tm1 Formula (C):
On the other hand, when the elapsed time Tm is greater than the prescribed time Tm1 (S9: NO), the control unit 13 executes the fourth internal temperature calculation process in S11.
In the fourth internal temperature calculation process of S11, the control unit 13 calculates the internal temperature TH according to the following formula (D).
Internal temperature TH=second temperature Formula (D):
In S12 the control unit 13 determines whether the internal temperature TH calculated above in S10, S11, S6 or S7 exceeds a first threshold value TH1. When the internal temperature TH is greater than the first threshold value TH1 (S12: YES), in S13 the control unit 13 executes a cool-down process and subsequently repeats the inappropriate installation detection process in S2.
The first threshold value TH1 is 42° C., for example.
However, when the internal temperature TH calculated above is less than or equal to the first threshold value TH1 (S12: NO), in S14 the control unit 13 determines whether the internal temperature TH is greater than a second threshold value TH2. When the internal temperature TH is less than or equal to the second threshold value TH2 (S14: NO), in S15 the control unit 13 cancels the cool-down process and subsequently repeats the inappropriate installation detection process in S2.
The second threshold value TH2 is lower than the first threshold value TH1. For example, the second threshold value TH2 is 41° C.
On the other hand, when the internal temperature TH calculated above is less than or equal to the first threshold value TH1 but greater than the second threshold value TH2 (S12: NO, S14: YES), the control unit 13 maintains the cool-down process and repeats the inappropriate installation detection process of S2.
Thus, in the cool-down process of S13, the control unit 13 changes the target temperature for the fixing device 9 to a value less than the printing temperature and maintains this target temperature until the internal temperature TH falls below the second threshold value TH2.
(1) The image-forming apparatus 1 according to the embodiment described above corrects the internal temperature TH (S6, S7) based on not only an increase ΔTout in the first temperature over the first time but also an increase ΔH in the absolute humidity over the first time, as illustrated in
When executing a printing process, moisture in a sheet S is evaporated when the sheet S is heated in the fixing device 9.
Therefore, in a case where the image-forming apparatus 1 is installed in an inappropriate location with the exhaust port 23 facing a wall, for example, moisture in the main casing 2 is not exhausted from the main casing 2 through the exhaust port 23 and may cause the absolute humidity in the main casing 2 to increase excessively.
When the image-forming apparatus 1 is installed in an appropriate location, on the other hand, moisture in the main casing 2 is properly exhausted through the exhaust port 23, thereby suppressing an increase in the absolute humidity in the main casing 2.
Therefore, in a case where the installation location of the image-forming apparatus 1 is appropriate and the ambient temperature near the image-forming apparatus 1 has increased due to an air conditioner or the like, the increase ΔH in the absolute humidity within the main casing 2 will be less than the second prescribed value H.
As a result, the control unit 13 can accurately detect whether the installation location of the image-forming apparatus 1 is appropriate.
(2) According to the image-forming apparatus 1 of the embodiment, the control unit 13 lowers the target temperature of the fixing device 9 in the cool-down process (S13) until the internal temperature TH is reduced to a value lower than or equal to the second threshold value TH2 (S14: NO).
By interrupting the printing process to reduce the target temperature of the fixing device 9, the control unit 13 can lower the temperature near the developing roller 72.
(3) In the first internal temperature calculation process of S6 and second internal temperature calculation process of S7, which are examples of the correcting in (a-2), the control unit 13 in the image-forming apparatus 1 according to the embodiment corrects the internal temperature TH to a higher value than the value calculated on the basis of the second temperature.
In this way, when the first temperature increases by a value greater than or equal to a first prescribed value compared to a value a first time ago and the absolute humidity increases by a value greater than or equal to a second prescribed value compared to a value the first time ago (S21: YES in
Therefore, the control unit 13 executes the cool-down process of S13 when the corrected internal temperature TH exceeds the first threshold value TH1 (S12: YES).
Thus, the control unit 13 can increase the frequency at which the cool-down process is executed.
(4) With the image-forming apparatus 1 according to the embodiment, the control unit 13 adds the correction value ΔR, which changes at regular intervals, to the internal temperature TH in the first internal temperature calculation process of S6 and the second internal temperature calculation process of S7.
By adding the correction value ΔR, which changes at regular intervals, the control unit 13 can gradually increase the internal temperature TH as the first temperature and absolute humidity rise.
As a result, the control unit 13 can suppress abrupt changes in calculated results for the internal temperature TH.
(5) With the image-forming apparatus 1 according to the embodiment, the control unit 13 displays a message on the display unit 14 (see
Through this process, the user can be prompted to change the installation location of the image-forming apparatus 1.
(6) With the image-forming apparatus 1 according to the embodiment, the control unit 13 displays a message on the display unit 14 indicating that the time until a cool-down process is executed will be reduced when the current first temperature has increased by the first prescribed value or greater compared to the previous first temperature a first time ago and the current absolute humidity has increased by the second prescribed value or greater compared to the previous absolute humidity the first time ago, as described with reference to
In this way, the image-forming apparatus 1 can notify the user that the cool-down process will be executed with greater frequency.
In the embodiment described above, the main casing 2 is an example of the claimed main casing. The side wall 21A is an example of the claimed first side wall, and the side wall 21B is the claimed second side wall. The exhaust port 23 is an example of the claimed exhaust port. The photosensitive drum 4 is an example of the claimed photosensitive drum, and the developing roller 72 is an example of the claimed developing roller. The fixing device 9 is an example of the claimed heater. The first sensor 11 is an example of the claimed first sensor, and the second sensor 12 is an example of the claimed second sensor. The control unit 13 is an example of the claimed controller, and the display unit 14 is an example of the claimed display.
The first temperature is an example of the claimed first temperature, and the second temperature is an example of the claimed second temperature. The internal temperature TH is an example of the claimed internal temperature. The increase ΔTout in the first temperature is an example of the claimed temperature increase in the first temperature, and the increase ΔH in the absolute humidity is an example of the claimed humidity increase in the absolute humidity. The first prescribed value T1 is an example of the claimed first prescribed value, and the second prescribed value H is an example of the claimed second prescribed value. The first time is an example of the claimed prescribed time. The first threshold value TH1 is an example of the claimed first threshold, and the second threshold value TH2 is an example of the claimed second threshold.
While the invention has been described in conjunction with various example structures outlined above and illustrated in the figures, various alternatives, modifications, variations, improvements, and/or substantial equivalents, whether known or that may be presently unforeseen, may become apparent to those having at least ordinary skill in the art. Accordingly, the example embodiment of the disclosure, as set forth above, is intended to be illustrative of the invention, and not limiting the invention. Various changes may be made without departing from the spirit and scope of the disclosure. Therefore, the disclosure is intended to embrace all known or later developed alternatives, modifications, variations, improvements, and/or substantial equivalents.
Number | Date | Country | Kind |
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2022-061544 | Apr 2022 | JP | national |