JP6862151B2 - Image forming device - Google Patents

Description

The present invention relates to an image forming apparatus using electrophotographic technology such as a printer or a copier.

There are various forms of the fixing device mounted on the electrophotographic image forming apparatus, and in many cases, the toner image is heated and fixed on the recording material by heating the toner image formed on the recording material. The fixing temperature of this fixing device is set to a condition in which fixing failure does not occur even if the maximum amount of toner can be set by the device. For example, in an image forming apparatus in which toners of a plurality of colors are laminated to form a toner image, it is set to a condition in which fixing failure does not occur even under the condition of a solid-painted image at the time of maximum lamination. However, the fixing device set to such a fixing temperature has a problem that more power than necessary is consumed in the case of a toner image having a small amount of toner such as only monochromatic characters.

To solve this problem, an image forming apparatus that detects image density information from image data transmitted from a host computer or an image scanner connected to the image forming apparatus to estimate the amount of toner and changes the fixing temperature accordingly. It has been proposed (Patent Document 1). As a result, the power consumption of the fixing process of the recording material can be reduced.

Japanese Unexamined Patent Publication No. 2006-154413

Further reduction in power consumption is required when printing double-sided recording materials. Therefore, an object of the present invention is to reduce the power consumption of the fixing process during double-sided printing.

One aspect of the present invention is an image processing unit that converts image data into pixel data, an image forming unit that forms a toner image on a recording material based on the pixel data, and the toner image formed on the recording material. a fixing unit which is heated to carry out a fixing process for fixing the toner image on a recording material, a temperature detecting section for detecting the temperature of the fixing unit, an acquisition unit that acquires image information of the toner image from the pixel data, For each recording material, the target temperature of the fixing portion is set according to the image information of the toner image formed on the recording material, and the detection temperature of the temperature detection unit becomes the target temperature. A control unit for controlling the power supplied to the fixing unit is provided, and after the recording material on which the toner image is formed on the first surface of the image forming unit is fixed by the fixing unit, the second surface of the recording material is provided. In an image forming apparatus capable of forming the toner image and performing the fixing process at the fixing portion, the target temperature at the time of performing the fixing process on the second surface of the recording material was formed on the first surface of the recording material. The density of the toner image formed on the first surface of the recording material is determined according to both the image information of the toner image and the image information of the toner image formed on the second surface of the recording material. In the first case where the density is 1 and the density of the toner image formed on the second surface of the recording material is the second density, the density of the toner image formed on the first surface of the recording material is The density of the toner image formed on the second surface of the recording material is a third concentration lower than that of the first concentration, and the density of the toner image is 2 of the recording material, as compared with the second case where the density is the second density. The target temperature at the time of fixing the surface is low, and the difference between the target temperature of the second surface in the first case and the target temperature of the second surface in the second case is the second surface. The higher the density of the toner image, the smaller the density .

According to the present invention, it is possible to reduce the power consumption of the fixing process of the recording material in double-sided printing.

The figure which shows the control flow of Example 1. Cross-sectional view of the image forming apparatus The figure which shows the cross section of the fixing device Second surface temperature set value table in Example 1 The graph of the table of FIG. 4 Results of fixation test in Example 1 Result of verification of the effect of Example 1 Control flow diagram of Example 2 Second surface temperature correction value table in Example 2 The figure which showed the relationship between the longitudinal position of the thermistor and the density | concentration detection area A in Example 2. The graph of the table of FIG. The figure which supplementarily explains the difference of the 2nd surface fixing temperature control adjustment value in Example 2. The figure which showed the result of having performed the effect verification of Example 2.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. 1 to 7.

FIG. 1 shows a control flow at the time of determining the fixing conditions in this embodiment. FIG. 2 is a cross-sectional view showing the image forming apparatus in this embodiment, and FIG. 3 is a sectional view of the fixing device F included in the image forming apparatus of FIG. FIG. 4 is a table showing the set values of the target temperature of the second surface with respect to the image density of the first surface, and FIG. 5 is a graph of FIG. FIG. 6 is a summary of the results of the fixing test in this example, and FIG. 7 is a diagram showing the results of verification of the effect of this example.

<Image formation process>
The image forming process by the image forming section in this embodiment will be described with reference to FIG.

In FIG. 2A, 200y, 200m, 200c, and 200k are four image forming stations having different developer colors, and 200y, 200m, 200c, and 200k have the same structure. FIG. 2B shows an enlarged view of one of the stations, the 200y station. Each station has a yellow developer in the first station 200y, a magenta developer in the second station 200m, a cyan developer in the third station 200c, and a black developer in the fourth station 200k. The image forming apparatus of this embodiment makes it possible to form a full-color image by using these. The developer is hereinafter referred to as toner.

In the image forming apparatus of this embodiment shown in FIG. 2A, a toner image is first formed on the photosensitive drum 201 at the station 200y of the first color. This will be described with reference to FIG. 2 (b). In FIG. 2B, 201y is a rotating drum type electrophotographic photosensitive member, a so-called photosensitive drum. The photosensitive drum 201y is rotationally driven around the central support axis in the clockwise direction of arrow d1 at a predetermined peripheral speed. In the process of rotating the photosensitive drum 201y, the photosensitive drum 201y is charged by the charging means 202 and is uniformly charged. After that, an electrostatic latent image is formed on the uniformly charged surface of the photosensitive drum 201y by the laser beam 2y corresponding to the image data. Then, the electrostatic latent image formed on the photosensitive drum 201 by the toner uniformly applied on the developing roller 205a in the developing apparatus 205 is manifested as a toner image. The toner image thus manifested is primarily transferred onto the intermediate transfer belt 21 by the roller member 204ay, which is a transfer means.

Further, the toner remaining on the surface of the photosensitive drum 201y without being transferred in the primary transfer step is removed by the cleaning blade 203ay in the cleaning unit 203, and then stored in the waste toner accommodating portion 203by.

As described above, the toner image is manifested on the photosensitive drum 201y at the station 200y of the first color, and the toner image is manifested at each station of 200m, 200c, and 200k in the same manner as the primary transfer is performed on the intermediate transfer belt 21. It is converted and first transferred.

The intermediate transfer belt 21 has an endless shape and is stretched by three rollers, a drive roller 21a, a tension roller 21b, and an opposing roller 21c. During the image forming process, the intermediate transfer belt 21 is driven in a forward rotation in the direction indicated by the arrow d by a drive roller 21a that is rotationally driven by transmitting the drive from a drive means (not shown). The stations of 200y, 200m, 200c, and 200k are in contact with each other in the forward rotation drive direction of the intermediate transfer belt 21, and as shown above, the primary transfer is sequentially performed at each station to obtain full-color toner on the belt. An image is formed.

Next, a step of transferring a full-color image from the intermediate transfer belt 21 to the recording material S will be described. The recording material S is housed in the paper cassette 206 shown in FIG. 2 (a). The recording material S is fed one by one from the paper cassette 206 by a paper feed roller (not shown), and is conveyed to the secondary transfer unit 23 by the resist roller pair 20 at a predetermined control timing. In the secondary transfer unit 23, the opposing roller 21c is configured together with the secondary transfer roller 23a via the intermediate transfer belt 21. The toner image formed on the intermediate transfer belt 21 is transferred to the recording material S while the recording material S is conveyed by the secondary transfer unit 23. The toner remaining on the intermediate transfer belt 21 without being transferred by the secondary transfer unit 23 is removed by the cleaning device 22.

Next, the fixing process will be described. The recording material S to which the toner image is transferred by the secondary transfer unit 23 is conveyed to the fixing device F, and the toner image is melted and fixed to the recording material. When an image is formed only on the first surface of the recording material, the recording material S fixed by the fixing device F is discharged to the outside of the image forming device by the paper ejection roller pair 501.

When forming a toner image on the second surface following the first surface of the recording material S, after the fixing process of the toner image on the first surface is completed by the fixing device F, the recording material S is removed from the machine by the paper ejection roller pair 501. The paper is conveyed in the discharge direction, and the rotation direction of the paper discharge roller pair 501 is switched in the opposite direction in the middle of the transfer. Then, the recording material S is conveyed to the double-sided transfer roller 401 by the reverse-rotating paper ejection roller pair 501, and then again conveyed to the resist roller pair 20 via the double-sided transfer roller 402. After that, a toner image is formed on the second surface of the recording material S by the secondary transfer unit 23 as on the first surface, the toner image formed on the second surface by the fixing device F is subjected to a constant fixing process, and finally the paper ejection roller. It is discharged to the outside of the image forming apparatus at a ratio of 501.

<Fixing device>
The fixing device (fixing portion) F in this embodiment will be described with reference to FIG. The fixing device F in this embodiment includes a fixing sleeve 304 as a heating rotating body and a heater 301 that comes into contact with the inner surface of the fixing sleeve 304. The fixing device F further has a pressure roller 305 as a pressure member that forms a fixing nip portion (hereinafter, referred to as a nip portion) N together with the heater 301 via the fixing sleeve 304. The heater 301 is supported by the support member 303. The support member 303 also has a function as a guide member for guiding the rotation of the fixing sleeve 304.

The pressurizing roller 305 receives power from a motor (not shown) and rotates clockwise. Then, as the pressure roller 305 rotates, the fixing sleeve 304 also follows and rotates in the arrow direction (counterclockwise).

A thermistor 302 as a temperature detection member (temperature detection unit) is installed on the inner surface of the fixing sleeve 304. Further, the fixing device F is connected to the control unit C. The control unit C controls the electric power supplied to the heater 301 so that the detected temperature detected by the thermistor 302 becomes the target temperature. The control unit C in this embodiment is a CPU (Central Processing Unit).

The fixing process is performed as follows. First, the recording material S carrying the toner image is conveyed in the direction of the arrow and enters the nip portion N. The recording material is heated by the heat of the heater 301 while being conveyed by the nip portion N, and the toner image is fixed to the recording material.

The thermistor 302 may be configured to detect the temperature of the surface of the heater 301 opposite to the surface in contact with the fixing sleeve 304.

In this embodiment, the following configuration is used as the fixing device F. The fixing sleeve 304 has an outer diameter of 24 mm, and has a SUS base layer having a thickness of 30 μm, an elastic layer made of a heat conductive rubber layer having a thickness of 200 μm on the outside thereof, and a release layer made of a PFA tube having a thickness of 20 μm on the outermost layer. There is.

The pressure roller 305 has an outer diameter of 25 mm, and has a configuration having an iron core metal having an outer diameter of 19 mm, an elastic layer made of silicone rubber having a thickness of 3 mm, and a release layer made of a PFA tube having a thickness of 40 μm as the outermost layer. did. Further, the heater 301 was printed on an alumina substrate so that the total resistance of the heat generation resistance value was 10Ω, and was insulatingly coated by glass coating. Further, an external voltage of 120 V was input, and the transport speed of the recording material S in the nip portion N was set to 240 mm / sec. Then, a Letter size paper having a basis weight of 75 g / m2 was used as a recording material, and the throughput was set to 40 ppm.

<Control flow for determining the target temperature of the fixing part>
In this embodiment, the target temperature of the fixing portion is changed. Hereinafter, the control flow for determining the target temperature of this embodiment will be described with reference to FIG. The image forming apparatus in this embodiment has a video controller B which is an image processing unit, and when it receives image data from an external device such as a host computer, it transmits a print signal to the control unit C. At the same time, the received image data is converted into pixel data for image formation, here CMYK data. When the end of pixel data conversion in the video controller is detected, the control flow shown in FIG. 1 is started from S101. The control unit C also has a role as an acquisition unit that acquires image density information as image information from pixel data.

Hereinafter, a specific description will be given with reference to FIG. When the print job starts <S101>, it is determined whether the image to be printed is the first side or the second side <S102>. When it is determined to print on the second side, T (D'), Tmin, and D'th are substituted using the value of D'extracted on the first side and the table shown in FIG. 4, and transmitted to the control unit C. <S103>. The image density information in which D'represents the maximum% density value in the printed image, T (D'), Tmin, and D'th will be described below. In this embodiment, as a basic technical idea, a target temperature that does not cause fixing failure is determined under the condition of a solid-painted image at the time of maximum lamination, and the target temperature is lowered so that the amount of toner is estimated to be small as image density information. .. Further, in the configuration of this embodiment, the target temperature T with respect to the image density information D'value is set so that the target temperature T is not lowered below the predetermined density (D'th). Therefore, a region T (D') in which the target temperature T can be changed with respect to the concentration information D'value and a region in which the target temperature Tmin is constant at a concentration lower than that are used separately. The reason why Tmin is used in this way is that the heat of the heater is taken away by something other than toner (recording material S, support member 303, etc.), and it is better to set the lower limit target temperature to heat them as well. Because it is good. How the target temperature and the like in the table shown in FIG. 4 are determined will be described later.

When it is determined that the printing is on the first side, T (D') = 0.15 × D'+180, Tmin = 195 ° C., and D'th = 100 are substituted and transmitted to the control unit C <S103'. >. The details of these decisions will be described later.
Next, the detection (acquisition) of the concentration information by the control unit C is started <S104>. To detect the density information, uses image data converted into pixel data in the video controller. The density data per toner single color is represented in the range of minimum density 0 to maximum density 255. In order to shorten the time for detecting the density information, the printing area (image forming area) to be formed on the recording material S is divided into 18 dots square areas, and this is repeated over the entire area for one page of the recording material without any gaps. Then, the concentration information of 1 point is detected for each area and used as a representative value. As a result, the detection time can be shortened to 1/324 (324 = 18 × 18) as compared with the case where the concentration information on the recording material P is detected one dot at a time. Here, the representative value may be the density information of a preset point (position) in the area, or may be the density information of an arbitrary point in the area. Then, the representative values of each of the Y, M, C, and K colors are added together in each of the divided areas to calculate the composite representative value for each area. The maximum value among the composite representative values calculated for each divided area is extracted as the maximum concentration value (hereinafter referred to as D value) in one page of the recording material S <S105>. The D value is 0 to 1023. <S106> for transmitting the D value to the control unit C.

The range (S1) from S101 to S106 described above is the control flow in the video controller B. Next, the range (S10) from S111 to S116 is the control flow in the control unit C. <S111> which converts the D value transmitted from the video controller B into a value (D') handled as density information by the control unit C. D'is a value obtained by converting D into a% concentration value. Specifically, the minimum density 0 per toner single color is set to 0%, and the maximum density 1023 is set to 400%. This% value (concentration information) correlates with the amount of toner per unit area on the actual recording material P (correlated), and in this embodiment, the amount of toner on the recording material is 0.50 mg / cm2 = 100. It becomes%. Further, in the image forming apparatus of this embodiment, color matching processing is performed in the video controller so that the maximum amount of toner on the recording material S is 1.00 mg / cm2 (equivalent to 200% in D'value). .. It is determined whether or not D'exceeds D'th <S112>, and if D'is equal to or less than D'th, the target temperature T is set to Tmin and printing is performed <S113>. When D'is D'th or more, the target temperature T is calculated and set from T (D'), and printing is performed <S113'>. Whether or not the next page is printed is determined <S114>, and when the next page is printed, the process returns to S102 to detect the density on the next page and determine the target temperature T. Control ends when the print job ends <S115>. As described above, in this embodiment, the target temperature T of the fixing process is determined according to the toner images formed on the first surface and the second surface of each recording material.

<Effect of the present invention>
Hereinafter, the effect of using the present invention and the process of determining each value without detailed explanation at the time of explaining the control flow will be described with reference to FIGS. 4, 5, 6, and 7.

FIG. 5 shows the relationship of the target temperature T with respect to the D'value determined according to the flow chart in this embodiment. FIG. 5A shows the D'value on the horizontal axis and the target temperature T on the vertical axis with respect to the first surface. This target temperature T is determined based on the results of a separately performed fixability test shown in FIG. 6 (a). In FIG. 6A, those having no problem with fixability are marked with ◯, and those having problems with fixability are marked with ×. In the fixability test, an evaluation environment of 15 ° C., 10% RH, and evaluation paper CANON Red Label 80 g / m2 were used. In this test, after 100 sheets were continuously printed, the image forming region was printed at a certain density from the front end to the rear end of the recording material S while avoiding the region passing through the thermistor 302, and the presence or absence of fixing failure was examined. The reason why the printing is performed while avoiding the area passing through the thermistor 302 is that the conditions regarding the fixability are different from those of the other areas. Details will be described with reference to Example 2.

In the fixability test on the first surface performed under the above conditions, when the maximum toner amount per unit area on the recording material S was 1.0 mg / cm2 (equivalent to 200%), fixing defects did not occur at a target temperature of 210 ° C. or higher. .. When the fixability test was sequentially performed by reducing the amount of toner with this 210 ° C. as a guide, the concentration D'and the target temperature satisfying the fixability changed almost linearly. Further, since the toner amount per unit area on the recording material S was 0.50 mg / cm2 (equivalent to 100%), the target temperature was not lowered below 195 ° C. even if the toner amount was further reduced. The target temperature of this lower limit is Tmin. In this embodiment, the first surface is Tmin = 195 ° C. and D'th = 100. When the amount of toner per unit area on the recording material S is 0.50 to 1.00 mg / cm2 (corresponding to 100% to 200%), a substantially linear relationship is established. Therefore, the target temperature was tentatively determined using an equation that linearly interpolates the relationship of 100%: 195 ° C. and 200%: 210 ° C., T (D') = 0.15 × D'+180. When the fixing test was performed while changing the toner amount again using this tentatively determined target temperature, no fixing failure occurred. Therefore, this T (D') is used as the target temperature T according to the image data in this embodiment. With T (D'), Tmin, and D'th determined in this way, in this embodiment, the target temperature is lowered within a range that does not cause image defects with respect to the first surface. That is, in this embodiment, when the density of the toner image formed on the first surface of the recording material is equal to or less than a predetermined value, the density of the toner image formed on the first surface of the recording material is not limited to 1 of the recording material. The target temperature for fixing the surface is the same temperature (lower limit target temperature). When the density of the toner image formed on the first surface of the recording material is higher than a predetermined value, the target temperature is changed according to the density of the toner image formed on the first surface of the recording material.

Next, with respect to the second surface, FIG. 5B shows the D'value at the time of printing on the second surface on the horizontal axis and the target temperature T on the vertical axis. The target temperature T of the second surface changes depending on the target temperature of the fixing process of the first surface. The solid line in FIG. 5B shows the time when the D'value at the time of printing on the first side is 100% or less, and the dotted line shows the time when the D'value at the time of printing on the first side is 200%. Looking at this graph, the target temperature of the second surface differs according to the D'value of the first surface, and the larger the D'value of the first surface (higher concentration), the lower the target temperature T and the smaller the D'th. Understand. This is because the larger the D'value, the higher the target temperature set on the first surface, so that the recording material warms up, and the target temperature for maintaining the fixability at the time of fixing the second surface can be lowered. That is, when the densities of the toner images formed on the first and second surfaces of the recording material are the first density and the second density, respectively, the third density and the second density are lower than the first density. The target temperature of the fixing process on the second surface is set to be lower than that in the case of the concentration of.

Further, the difference in the target temperature T of the second surface caused by the difference in the D'value of the first surface (difference in concentration) becomes smaller as the D'value of the second surface is larger. This is because as the density at the time of printing on the second surface increases, the toner layer on the first surface contributes as thermal resistance and the effect of inhibiting heat transfer to the toner increases. The target temperature T of the second surface having the above tendency is also determined based on the result of the fixability test conducted separately. An image of a constant density was printed on the entire surface of the first surface, and the test was performed while changing the image density of the second surface. The results are shown in FIGS. 6 (b) to 6 (d). 6 (b) shows when the D'value at the time of printing on the first side is 200%, (c) shows when the D'value at the time of printing on the first side is 150%, and (d) shows D'at the time of printing on the first side. It indicates when the value is 100%. Although the values are different in FIGS. 6 (b) to 6 (d), as in the case of the first surface, the concentration D'and the target temperature satisfying the fixability change almost linearly from the target temperature of 200% of the toner loading amount and are constant. The target temperature is not lowered from the amount of toner loaded on the surface. Therefore, on the second surface as well as the first surface, the target temperature when the maximum toner amount per unit area on the recording material S is 1.0 mg / cm2 (equivalent to 200%), the lower limit target temperature, and the toner loading at that time. Using quantities, we created an equation that linearly interpolates between them. When the fixing test was performed by changing the toner amount again while determining the target temperature using this formula, no fixing failure occurred. Further, when the D'value at the time of printing on the first surface was 150%, T (D'), Tmin, and D'th were approximately intermediate values of 200% and 100%. Therefore, using T (D'), Tmin, and D'th at 200% and 100%, T (D') when the D'value at the time of printing on the first surface is 200% to 100%. , Tmin, and D'th were linearly interpolated to create an equation. A summary of these is shown in the table of FIG. When the fixability test of the second surface was performed when the D'value at the time of printing on the first surface was 125% and 175%, using this formula, no fixing failure occurred. Therefore, in this embodiment, the one shown in the table of FIG. 4 is used as the target temperature calculation formula for the second surface, which is changed according to the image density of the first surface. As a result, in this embodiment, the target temperature can be lowered within a range that does not cause image defects even on the second surface.

Next, FIG. 7 shows the results of power comparison between the case where the technique in this example is used and the case where the technique in the comparative example is used. As the experimental conditions, the evaluation paper CANON Red Label 80 g / m2 was used in an environment of 15 ° C. and 10% RH. After 100 sheets of continuous printing, 20 sheets are printed at the density at which the power is to be compared from the front end to the rear end of the recording material S, avoiding the area of the recording material passing through the thermistor 302, and the average power during printing of 20 sheets is calculated and compared. did. The required powers are compared for each of the five patterns of maximum density combinations in the images on the first and second surfaces. In the comparative example, in order to reduce power consumption while always satisfying the fixability, the relationship between the image density and the target temperature is derived under the most strict fixability condition on the second surface, and the relationship is determined regardless of the density on the first surface. Will be used. In this embodiment, it is when the concentration of the first surface is 100%, and the control of the solid line (concentration of the first surface of 100%) shown in FIG. 5B is used in the technique of the comparative example. The reason why the density of 100% on the first surface is the most severe is that the target temperature of the first surface is the lowest and the temperature of the recording material S during printing on the second surface is the lowest, so that the target temperature during the fixing process of the second surface is increased. Because it is necessary. According to FIG. 7, which shows the result of comparing the technique of the comparative example and the technique of the present example, there is no difference when the concentration of the first surface is 100%, but in all other cases, the technique of the present example is applied. It can be seen that power reduction can be realized with.

In this embodiment described above, the target temperature at the time of fixing the second surface of the recording material is the density information of the toner image formed on the first surface of the recording material and the toner image formed on the second surface of the recording material. It is a technical idea that it is decided according to both the concentration information and the concentration information.

This makes it possible to reduce the power for fixing the second side of the recording material during double-sided printing.

In this embodiment, the target temperature for the image density and the target temperature for the second surface between 100% and 200% of the image density of the first surface are shown by an example for calculation from a linearly interpolated function, but the present invention is limited to this. Instead, it may be held as a table, for example. Further, in this embodiment, an example is shown in which the target temperature of the fixing process on the second side is lowered as the density of the toner image on the first side is higher, but the opposite relationship may occur depending on the printing speed and the fixing device configuration. .. How to define and optimize the relationship between the image density on the first surface and the target temperature on the second surface varies variously, and is not limited to that shown in this embodiment. Further, in the present embodiment, the fixing device includes a fixing sleeve and a heater in contact with the inner surface thereof, but the fixing device is not limited to this. It can also be applied to a configuration in which a halogen heater is provided in the hollow portion of the fixing sleeve or a configuration using a fixing roller.

Further, in this embodiment, image density information (toner loading amount) is used as the image information, but the present invention is not limited to this. As the image information, information such as the presence / absence of a color image, a monochrome image, and a halftone image may be used.

Hereinafter, a second embodiment of the present invention will be described with reference to FIGS. 8 to 13. Since the configurations of the fixing device and the image forming device in this embodiment are the same as those in the first embodiment, the description thereof will be omitted.

FIG. 8 shows a control flow at the time of determining the target temperature in this embodiment, and FIG. 9 shows a table of temperature correction values on the second surface in this embodiment. Further, FIG. 10 shows the relationship between the position of the recording material of the thermistor and the concentration detection region in this embodiment. FIG. 11 is a graph of the table of FIG. 9, FIG. 12 is a diagram for explaining the difference in the amount of decrease in the target temperature on the second surface in this embodiment, and FIG. 13 is a diagram for verifying the effect of this embodiment. It is a figure which shows the result which performed.

This embodiment is different from the first embodiment in that the target temperature changes according to the amount of toner in the region of the recording material passing through the thermistor 302 installed on the inner surface of the fixing sleeve 304. The reason for this will be described below. In the power control in the fixing device in this embodiment, the required input power (supply power) is calculated from the difference between the temperature detected by the thermistor 302 and the target temperature in the control unit C, and the power is supplied from the power source (not shown) to the heater 301. Is done by supplying. However, as the amount of toner in the region of the recording material passing through the thermistor 302 increases, the heat on the surface of the fixing sleeve 304 is taken away, so that the electric power applied to the fixing device increases. On the contrary, the smaller the amount of toner in the region of the recording material passing through the thermistor 302, the less heat is taken from the surface of the fixing sleeve 304, so that the electric power applied to the fixing device becomes smaller. Therefore, when there is no toner in the region of the recording material through which the thermistor 302 passes, it is difficult to supply electric power, so that a situation may occur in which the fixability of the entire image forming region deteriorates. In order to avoid this situation, it is conceivable to set the target temperature higher so that the fixability can be maintained regardless of the presence or absence of toner in the region passing through the thermistor 302. In Example 1, the area of the recording material passing through the thermistor 302 was printed and the fixability test was performed because the above was taken into consideration and priority was given to fixing under any conditions. Therefore, when the toner is present in the region of the recording material passing through the thermistor 302, the target temperature can be lowered as compared with the first embodiment.

In the second embodiment, the target temperature T1 is tentatively determined first by the same method as in the first embodiment. Then, a correction value that can be lowered from the target temperature T1 is calculated according to the amount of toner in the region of the recording material passing through the thermistor 302 (hereinafter, referred to as a subtraction parameter Ts (Ds')), and the target temperature T is set. Decide and print. The subtraction parameter Ts (Ds') differs between the first surface and the second surface, and the second surface is particularly affected by the image density of the first surface. To change.

<Control flow when determining fixing conditions>
Hereinafter, the control flow related to the determination of the target temperature during the fixing process in this embodiment will be described with reference to FIG. In this embodiment, the parameters T1, Ds, Ds', and Ts (Ds') are added to the first embodiment. The new parameters T1, Ds, Ds'and Ts (Ds') are the tentative target temperature T1, the image data Ds at the thermistor position, the concentration information Ds' at the thermistor position, and the subtraction parameter Ts (Ds'), respectively. Is. The target temperature T1 is a target temperature in the previous stage in which the target temperature is changed according to the amount of toner formed in the region of the recording material passing through the thermistor 302. The subtraction parameter Ts (Ds') is a parameter indicating how much the temperature can be lowered from the target temperature T1 according to the density information Ds' of the toner image formed in the region of the recording material passing through the thermistor 302.

<S201> at which the print job starts and <S202> at which it is determined whether or not to print on the second side. When it is determined to print on the second side, T (D'), Tmin, D'th, and Ts (Ds') are calculated using the value of D'extracted on the first side and the tables shown in FIGS. 4 and 9. Substitute and send to control unit C <S203>. It differs from <S103> of the first embodiment in that the subtraction parameter Ts (Ds') is determined. This Ts (Ds') indicates a correction value of the target temperature that changes according to the concentration information Ds' of the thermistor position, and is a function of Ds'. Since this function changes according to the target temperature of the first surface, it is changed according to the table. The contents of the table in FIG. 9 will be described later.

If it is determined to print on the first side, substitute T (D') = 0.15 × D'+180, Tmin = 195 ° C., D'th = 100, Ts (Ds') = 0.02 × Ds'. , <S203'> to be transmitted to the control unit C. The details of these decisions will be described later. <S204> to start the detection 1 of the concentration information. Here, the same processing as in <S104> of the first embodiment is performed. The entire printing area to be formed on the recording material S is divided into areas, and the representative values of each of the Y, M, C, and K colors are added to calculate the composite representative value for each area. Similar to <S105> of the first embodiment, <S205> which extracts the maximum D value among the composite representative values. <S206> to start the detection 2 of the concentration information. Here, the density data of the region A (hereinafter referred to as s-area-d) is extracted for each color. FIG. 10 shows the relationship between the position of the thermistor 302 and the area A, and the entire print area B to be processed in the first embodiment and S204. The thermistor 302 is arranged at a position displaced by 40 mm from the center of transportation of the recording material S in the width direction of the recording material. The region A is a region having a width of 20 mm centered on the thermistor 302 in the width direction of the recording material. At this time, unlike the D value extracted in S204 and S205 which was the maximum value of the concentration data in the region, the average value in the region A is extracted as the Ds value. Each color and region A are examined one dot at a time, and an average value is calculated from the total value to obtain each color density data (s-area-d). Then, the s-area-d of each color is added together (C (s-area-d) + M (s-area-d) + Y (s-area-d) + K (s-area-d), and the total value is added. Let the Ds value be. The D value and the Ds value are transmitted to the control unit C <S207>. Basically the same as <S111> in the first embodiment, but by the same method as converting the D value to the D'value. <S211> to convert the Ds value to the Ds' value. Here, the tentatively determined target temperature T1 is calculated and set according to the concentration information as in <S112> to <S113'> of the first embodiment (<S212> to <S213'>). No printing is performed at this point. The target temperature T is calculated by T = T1-Ts (Ds') according to the density information of the region A. Then, printing is performed using the calculated target temperature T. <S214>. Whether or not to print the next page is determined <S215>. When there is a print on the next page, the process returns to S202 to detect the density on the next page and determine the target temperature. Completion of the print job. The control is terminated in accordance with <S216>.

The above is the control flow at the time of determining the fixing conditions in this embodiment.

<Effect of this example>
Hereinafter, the effects of this embodiment will be described. FIG. 11 shows the subtraction parameter Ts (Ds') in this embodiment. FIG. 11A shows the thermistor position concentration information Ds'on the horizontal axis and the subtraction parameter Ts (Ds') on the vertical axis with respect to the first surface. This subtraction parameter Ts (Ds') is determined based on a fixability test conducted separately. In the test at this time, after 100 sheets were continuously printed, 200% was printed except for the area A, and the area A was printed at a density at which the fixability was to be examined. Other test conditions are the same as in the first embodiment. When the presence or absence of fixing failure occurred in the entire recording material S while changing the image density of the region A by this method, the target temperature was 206 ° C. when the image density of the region A was 200%, and 210 when the image density of the region A was 0%. It settled without problems at ° C. Further, although detailed results are omitted here, a substantially linear relationship was observed between the image density and the target temperature at which fixing failure occurs between the image density of 200% to 0% in the region A. From the above results, the linear interpolation formula Ts (Ds') = 0.02 × Ds' is tentatively determined, the tentatively determined target temperature T1 is obtained by the method shown above, and the target temperature T = T1-Ts (Ds'). The procedure for calculating is prepared. Then, regardless of the region A, when images having various image densities were printed over the entire recording material S and a fixing test was performed, no fixing failure occurred. Therefore, in this embodiment, the subtraction parameter is determined by this equation Ts (Ds') = 0.02 × Ds' for the first surface. As a result, in this embodiment, regarding the first surface, the target temperature can be lowered within a range that does not cause image defects, considering that the fixability changes depending on the amount of toner at the thermistor position.

Next, FIG. 11B shows the thermistor position concentration information Ds'on the horizontal axis and the subtraction parameter Ts (Ds') on the vertical axis with respect to the second surface. The subtraction parameter Ts (Ds') on the second side changes depending on the printing conditions on the first side. The solid line in FIG. 11B shows the subtraction parameter Ts (Ds') when the D'value at the time of printing on the first side is less than 100%, and the dotted line shows the subtraction parameter Ts (Ds') when the D'value at the time of printing on the first side is 200%. .. Looking at this graph, it can be seen that the larger the D'value of the first surface, the larger the subtraction parameter Ts (Ds') of the second surface. This difference occurs because the larger the D'value of the first surface, the higher the temperature of the recording material S immediately before the fixing process of the second surface. This will be described with reference to FIG. In FIG. 12, the leftmost white arrow indicates the amount of heat that the fixing sleeve 304 is deprived of when there is toner in the area A on the second surface (here, when the average density Ds'values are 50% and 200%). Is shown. This amount of heat is a value that does not depend on the maximum image density D'value on the first surface. This is because the amount of heat taken from the fixing sleeve 304 when there is toner is almost the amount of heat taken by the toner and does not depend on the printing conditions (state of the recording material S) on the first surface. The two white arrows on the right side indicate the amount of heat that the fixing sleeve 304 is deprived of when there is no toner in the area A on the second surface. The value of this amount of heat differs depending on the maximum image density D'value on the first surface, and the larger the D'value, the smaller the amount of heat taken away (here, the times when the D'values are 20% and 200% are shown, and 20%. > 200%). This is because the amount of heat taken from the fixing sleeve 304 when there is no toner in the region A is the amount of heat taken by the recording material S, which is related to the temperature of the recording material S. When the maximum image density D'value of the first surface is small (here, the D'value is 20%), when the D'value is large (here, 200%), the target temperature of the fixing process of the first surface is higher. Second, the temperature of the recording material S immediately before the fixing process on the second surface also rises. Therefore, when the D'value is large (200% in this case), the temperature difference from the fixing sleeve 304 is relatively small, and the amount of heat taken away by the fixing sleeve 304 is also small. It becomes. A diagonal arrow is shown above the two white arrows on the right. This shows the difference in how the amount of heat is deprived when the toner is present in the region A (the average concentration Ds'value is 50% and 200%) and when it is not present.

In this embodiment, the tentative target temperature T1 is first determined in the state where there is no toner in the region A. As shown in Example 1, this target temperature T1 changes depending on the maximum image density D'value of the first surface. The amount of heat taken away by the fixing sleeve 304 when the maximum image density of the first surface is 20% and 200% in the state where there is no toner in the region A is represented by the lengths of the two white arrows on the right side of FIG. 12, respectively. Different to. Then, as the amount of toner in the region A increases, the amount of heat taken from the surface of the fixing sleeve 304 increases and electric power is input, so that the target temperature can be lowered from the provisionally determined target temperature T1 as the amount of toner increases. That is, the temperature (Ts (Ds') value) that can be lowered at this time increases as the difference between the time when the tentatively determined target temperature T1 is determined and the amount of heat that the sleeve is deprived of due to the presence of toner increases. This difference in the amount of heat taken away is the size of the shaded arrow in FIG. 12, as described above. When the average concentration Ds'value in the region A is 50% and 200%, the larger the D'value on the first surface is, the larger the difference is, and the temperature at which the target temperature can be lowered (Ts (Ds)). ') Value) increases. Therefore, the relationship of the subtraction parameters Ts (Ds') is as shown in FIG. 11 (b).

Further, the subtraction parameter Ts (Ds') of the first surface is smaller than that of the second surface for the same reason. That is, the subtraction parameter Ts (Ds') is smaller on the first surface because the temperature of the recording material S is lower.

The subtraction parameter Ts (Ds') on the second surface having the above tendency is also determined based on the fixability test conducted separately. The test method was the same as that of the first surface, and the presence or absence of fixing failure was examined in the entire recording material S while changing the image density of the region A. When the D'value of the first surface was 100%, the target temperature was 200 ° C. when the image density of the region A of the second surface was 200%, and the temperature was fixed at 205 ° C. when the image density of the region A was 0%. Further, when the value of D'on the first surface was 200%, the target temperature was 194 ° C. when the image density of the region A on the second surface was 200%, and the temperature was fixed at 200 ° C. when the image density of the region A was 0%. Although detailed results are omitted, as in the case of the first surface, a substantially linear relationship was observed between the image density and the target temperature at which fixing failure occurs between the image density of 200% to 0% in the region A. From the above, when the first image is 100%, Ts (Ds') = 0.025 × Ds', and when the first image is 200%, Ts (Ds') = 0.03 × Ds' is tentatively determined. .. Ts (Ds') = (0.00005 × D'+ 0.02) × Ds'was tentatively determined for the range between 200% and 100% of the first surface image in a form of linearly interpolating the intervals. Using the above formula, the procedure for determining the target temperature T1 and calculating the target temperature T = T1-Ts (Ds') was prepared as in the case of the first surface. Then, regardless of the first surface, the second surface, and the region A, when images having various image densities were printed over the entire recording material S and a fixing test was performed, no fixing failure occurred. Therefore, in this embodiment, the subtraction parameters are defined by these Ts (Ds') for the second surface. The table shown in FIG. 9 summarizes the results. As a result, in this embodiment, the target temperature can be lowered within a range that does not cause image defects even on the second surface.

FIG. 13 shows the consumption when the technique in this embodiment is used and when the target temperature is lowered so that the fixing failure does not occur regardless of the amount of toner in the region A when the second surface has the same control as the first surface. The result of comparing the electric powers is shown. In this comparative experiment, three patterns of images shown in FIG. 13 were used. In pattern 1, the density of the toner images in the area A (thermistor portion) of the first, second, and second surfaces is all 100%, in pattern 2, they are 200%, 200%, and 100%, respectively, and in pattern 3, they are 200%, 200%, and 100%, respectively. They are all 200%. Looking at the results of this comparison, it can be seen that even greater power reduction can be achieved by applying the technology of this embodiment.

As shown above, according to the present embodiment, in the fixing process at the time of double-sided printing, it is possible to reduce more power while suppressing fixing defects.

In this example, the higher the image density of the first surface, the larger the amount of decrease in the target temperature due to the image density of the region A is shown. However, depending on the printing speed and the configuration of the fixing device, it may be easier to obtain the effect by reducing the temperature reduction width associated with the image density of the region A as the image density of the first surface is higher. How the image density of the first surface and the image density of the region A are reflected in the target temperature of the fixing process on the second side depends on the printing speed and the configuration of the fixing device, and is therefore shown in this embodiment. Not limited to things. Further, the configuration of the fixing device is not limited to that shown in the present embodiment as in the first embodiment.

Further, in this embodiment, image density information (toner loading amount) is used as the image information, but the present invention is not limited to this. As the image information, information such as the presence / absence of a color image, a monochrome image, and a halftone image may be used.

301 Heater 302 Thermistor 304 Fixing sleeve 305 Pressurizing roller B Video controller C Control unit S Recording material

Claims (5)

An image processing unit that converts image data into pixel data,
An image forming unit that forms a toner image on a recording material based on the pixel data,
A fixing portion that heats the toner image formed on the recording material and performs a fixing process for fixing the toner image on the recording material .
A temperature detection unit that detects the temperature of the fixing unit and
An acquisition unit that acquires image information of the toner image from the pixel data, and
For each recording material, the target temperature of the fixing portion is set according to the image information of the toner image formed on the recording material, and the detection temperature of the temperature detection unit is set to the target temperature. A control unit that controls the power supplied to the fixing unit,
With
After the recording material on which the toner image is formed on the first surface of the image forming portion is fixed by the fixing portion, the toner image is formed on the second surface of the recording material and the fixing treatment is performed by the fixing portion. In a possible image forming apparatus
The target temperature when the second surface of the recording material is fixed is the image information of the toner image formed on the first surface of the recording material and the image information of the toner image formed on the second surface of the recording material. If, as determined in accordance with both,
In the first case, the density of the toner image formed on the first surface of the recording material is the first density, and the density of the toner image formed on the second surface of the recording material is the second density. The density of the toner image formed on the first surface of the recording material is a third density lower than the first density, and the density of the toner image formed on the second surface of the recording material is the first density. The target temperature at the time of fixing the second surface of the recording material is lower than that of the second case having a concentration of 2.
The difference between the target temperature of the second surface in the first case and the target temperature of the second surface in the second case becomes smaller as the density of the toner image on the second surface increases. An image forming apparatus as a feature. When the density of the toner image formed on the first surface of the recording material is not more than a predetermined value, the first surface of the recording material is fixed regardless of the density of the toner image formed on the first surface of the recording material. The target temperature when doing is the same temperature,
When the density of the toner image formed on the first surface of the recording material is higher than a predetermined value, the target temperature changes according to the density of the toner image formed on the first surface of the recording material.
The image forming apparatus according to claim 1. The fixing portion includes a heating rotating body and a roller forming a nip portion that conveys a recording material together with the heating rotating body, and the temperature detecting unit detects the temperature of the heating rotating body. The image forming apparatus according to claim 1 or 2. The fixing portion includes a heating rotating body, a heater that heats the heating rotating body, and a roller that forms a nip portion that conveys a recording material together with the heating rotating body, and the temperature detecting unit is the heater. The image forming apparatus according to claim 1 or 2, wherein the temperature of the image forming apparatus is detected. The image forming apparatus according to claim 3 or 4 , wherein the heating rotating body is a sleeve.

Images