RU2815056C1 - Heating control method and image processing device - Google Patents

Abstract

FIELD: heating; image processing.

SUBSTANCE: present application discloses a heating control method and an image processing device, said heating control method comprising steps of: when the image processing device is in printing mode, determining the time t1 required to increase the current temperature of the fixing unit or the temperature set at a certain moment to a given target temperature, said fixing unit heating start time is determined proceeding from the route from preset position to central position of said fixing unit, printing medium speed and time t1.

EFFECT: in this application, due to the fact that the heating start time of the fixing unit is determined based on the route from the given position to the central position of the fixing unit, as well as the speed of movement of the printing medium and the time t1, during printing, it is possible to determine the exact time of the beginning of heating of the fixing unit in order to prevent wasteful power consumption caused by an excessively long heating period, as well as to reduce power consumption of the fixing unit.

14 cl, 4 dwg

Description

Field of technology

The present application relates to the field of image processing technology and, in particular, to a method for controlling the heating of a fixing unit and an image processing apparatus.

State of the art

In the field of imaging technology, curing refers to the fixing of indelible and indelible toner onto paper by heating the heating elements of the curing unit.

In the previous heating solution using a halogen lamp, due to the slow heating speed of the halogen lamp, the process of controlling the heating start time is difficult, and in order to ensure sufficient fixation of the toner on the paper, it is necessary to preheat the heating elements of the curing unit.

The prior art also uses some heating elements with a faster heating rate. For example, in a heating solution using a ceramic plate, due to the fast heating rate of the ceramic plate, much more energy is consumed if preheating of the heating elements is still required. Therefore, for fixing by heating a ceramic plate, it is necessary to provide a method for accurately determining the heating starting point for fixing.

Disclosure of the invention

To overcome the problems of the prior art, the main objective of the present application is to provide a heat control method to reduce the power consumption of the fixing unit.

To achieve the above goal, this application provides the following technical solutions:

The present application provides a heating control method used for heating a curing unit. Said heating control method comprises the steps of:

when the imaging device is in print mode;

determining a time t1 required to increase the current temperature of said fixing unit or a temperature set at a certain moment to a predetermined target temperature;

determining the start time of heating of said fixing unit based on the route from a given position to the central position of said fixing unit, as well as the speed of movement of the printing medium and time t1.

In some embodiments, in the step of determining the time t1 required to increase the current temperature of said fixing unit or the temperature set at a certain moment to a given target temperature:

determining the heating rate of said fixing unit;

calculating the time t1 based on the heating rate, the current temperature or the temperature set at a certain moment, as well as the set target temperature of the said fixing unit.

In some embodiments, during the step of calculating time t1 based on the heating rate, the current temperature or the temperature set at a certain moment, and the specified target temperature of said fixing unit:

time t1 is calculated using the formula t1=(T1-T0)/X;

where, T1 is the set target temperature of the mentioned fixing unit, T0 is the current temperature or the temperature set at a certain moment of the mentioned fixing unit, X is the heating rate of the mentioned control unit.

In some embodiments, during the step of determining the heating rate of said fixing unit:

when the imaging device is in print mode of the first page of the print media,

calculating the heating rate based on temperature changes during the preheating step of said fixing unit.

In some embodiments, during the step of calculating the heating rate based on temperature changes during the preheating step of said fixing unit:

at the preheating stage;

calculating the heating rate based on the time required for each increase in the temperature of said fixing unit by one degree; or

the heating rate is calculated based on the number of degrees of said fixing unit increased per unit time.

In some embodiments, during the step of determining the heating rate of said fixing unit:

when the image processing device is in the printing mode of the nth page of the printing medium, where n is a natural number and n≥2;

calculating the heating rate based on changes in temperature set during the start of heating of said fixing unit.

In some embodiments, during the step of determining the heating rate of said fixing unit:

when the image processing apparatus is in the printing mode of the n-th page of the printing medium, the heating rate is calculated based on the temperature set in the process of starting heating of the fusing unit and printing the n-1st page of the printing medium, as well as the set target temperature of the said fusing unit, where n is a natural number and n≥2.

In some embodiments, during the step of calculating the heating rate based on changes in the temperature set during the start of heating of said curing unit until the specified target temperature is reached:

at a stage where the temperature set in the heating start process of the fixing unit reaches the set target temperature;

calculating the heating rate based on the time required for each increase in the temperature of said fixing unit by one degree; or

the heating rate is calculated based on the number of degrees of said fixing unit increased per unit time.

In some embodiments, the route from a predetermined position to a central position of said securing unit includes:

a path of movement of said printing medium from a position where the sensor is installed to a central position of said fixing unit.

In some embodiments, the route from a predetermined position to a central position of said securing unit includes:

the path of movement of the image in the image processing device from the forming position to the central position of the fixing unit.

In some embodiments, the start time of heating of said fixing unit corresponds to: the time reached by t1 from said time point, not later than the time when the printing medium reaches the central position of said fixing unit.

In some embodiments, the interval between the time reached by t1 from said time point and the time when the print medium reaches the center position of said fixing unit depends at least on the paper type, the printing mode, the ambient temperature and the duration of use of the equipment.

Accordingly, the present application also provides an image processing apparatus. Said image processing device includes a main body and a fixing unit. For said main body, the heating control method of any one of the embodiments is used to control the heating of said fixing unit.

Accordingly, the present application also provides an image processing apparatus. Said image processing device includes:

a first determination unit configured to determine a time t1 required to increase the current temperature of said fixing unit or a temperature set at a certain moment to a predetermined target temperature;

a second determination unit configured to determine the start of heating of said fixing unit based on the route from a predetermined position to the central position of said fixing unit, as well as the speed of movement of the printing medium and time t1.

Compared with the prior art, the heating control method of the present application comprises the steps of: when the image processing apparatus is in the printing mode, determining the time t1 required to increase the current temperature of said fixing unit or the temperature set at a certain moment to a given target temperature; Because the heating start time of said curing unit is determined based on the route from a predetermined position to the central position of the curing unit, as well as the speed of the printing medium and the time t1, during the printing process, the exact start time of heating of the curing unit can be determined in order to prevent wasteful energy consumption caused by an excessively long heating period, as well as reducing the energy consumption of the curing unit.

Brief description of graphic materials

Fig. 1 is a block diagram of the heating control method presented in an embodiment of the present application.

Fig. 2-wave diagram of temperature changes of the curing unit during the printing process presented in the embodiment of the present application.

Fig. 3 is a block diagram of modules of an image processing device presented in an embodiment of the present application.

Fig. 4 is a schematic diagram of a structure of an image processing apparatus presented in an embodiment of the present application.

Carrying out the invention

For a better understanding of the purpose, technical solution and advantages of the present application, below is a more detailed description of the present application with the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are used only to illustrate the present application and not to limit the present application.

As used herein, the terms “first” and “second” are used for descriptive purposes only and should not be construed as indicating or implying relative importance unless otherwise expressly stated or limited; the term “several” means two or more, the term “several kinds” means two or more kinds, unless otherwise specified or explained; the terms “connection”, “fastening” and other terms should be understood in a broad sense, for example, a “connection” can be a fixed connection, as well as a detachable connection or a permanent connection, or an electrical connection; can be a direct connection, as well as a connection through an intermediate medium. General technical personnel in the art may understand the specific meanings of the above terms in this application depending on the specific conditions.

It should be noted that when the imaging apparatus is turned on or comes out of sleep mode, the curing unit will gradually heat up from the cooled state to the set temperature, and this process is called the preheating process. The process from the start of the printing operation to the completion of the printing operation is called the printing phase. At the stage of printing each page of printed media (for example, paper), it is required to heat the curing unit to a given target temperature (for example, this could be a temperature of 195 ° C, as well as other range of acceptable curing temperatures). This preset target temperature is the temperature of the curing unit required for the curing process. For example, in the process of printing the first page of the printed media, it is required to heat the curing unit to a predetermined target temperature, and then perform the curing operation and then stop heating the curing unit. Next, when printing the second page, you need to continue heating the curing unit to the specified target temperature, and then perform the curing operation and then stop heating the curing unit. Printing other pages of the printed media is done in the same way.

In fig. 1 is a flowchart of a heating control method provided in an embodiment of the present application. Embodiments of the present application provide a heat control method that is used to control the heat of a fixing unit in an image processing apparatus. This heating control method includes the following steps:

in step S11, the time t1 required to increase the current temperature of the fixing unit or the temperature set at a certain time to the set target temperature is determined.

In particular, the heating rate of the fixing block, the current temperature or the temperature set at a certain moment, as well as the specified target temperature are first determined, then the time t1 is calculated using the formula t1=(T1-T0)/X, where X is the heating rate of the fixing block, T1 is the set target temperature of the fixing block, T0 is the current temperature or the temperature set at a certain moment of the fixing block. Temperature set at a certain point may refer to the temperature of the equipment set at a certain period of time during the printing process. For example, this could be the period when a print page request is received, or it could also be the period when the controller starts the heater. In this embodiment, this period is not limited to a specific value.

The current temperature refers to the temperature of the curing unit, determined in real time. For example, if during the printing process before heating begins (i.e. in the waiting mode for heating), T0 is used as the current measured temperature of the curing unit, then time t1 is calculated using the formula t1=(T1-T0)/X. Then, according to the moving speed of the paper, the time t6 required to move the paper from the current position to the center position of the fuser unit is calculated (i.e., in the process of paper moving, the time t6 required to move the paper from the current position to the center position of the fuser unit can be calculated in real time or at a specified time interval). Next, a comparative analysis of t6 and t1 is performed. If time t6 is close to time t1, the curing unit is heated. It is preferable if heating is carried out when time t6 is slightly less than or equal to time t1.

Since in the continuous printing process, the rate of increase in the initial temperature of the second page is different from the rate of increase in the temperature of the first page, the degree of increase in temperature of the first page is relatively high, and the degree of subsequent increase and decrease in temperature is relatively smooth. In fig. 2 shows a wave diagram of temperature changes of the curing unit during the printing process presented in the embodiment of the present application. In fig. 2 A refers to the heating process from room temperature T3 when the equipment is switched on in a cold state to preheating temperature T2. The heating rate calculated during this process is used to calculate when to start heating when the first page is printed. B refers to the estimated start time of heating when printing the first page. C refers to the process of increasing the temperature from the heating start time to the set target temperature T1. The speed calculated in this process is used to calculate when to start heating when printing the second page. D refers to the start time of heating when printing the second page.

Therefore, the process of calculating the heating rate of the fixing unit can be divided into two methods:

If the image processing device is in the printing mode of the first page of the printing medium, then the heating rate of the curing unit is calculated based on the temperature changes during the preheating stage of the curing unit. For example, in the preheating stage, the heating rate calculation is performed based on the time required for each one degree increase in temperature, or the heating rate calculation is performed based on the number of degrees of the fixing unit increased per unit time; then, based on this heating rate, the start time of heating of the curing unit when printing the first page of the printing medium is determined.

In this embodiment, the heating rate X is calculated based on the time required to heat the curing unit from the temperature in the cooled state to the temperature in the preheating stage (for example, 150°C, this temperature is usually lower than the predetermined target temperature T1), that is, the heating rate X is calculated by the formula X=(T2-T3)/t, where T2 is the set temperature of the curing unit at the preheating stage, T3 is the temperature of the curing unit in the cooled state, t is the time required to heat the curing unit from T3 to T2. In this embodiment, the heating rate X is calculated based on the time required to heat the equipment from the cooled temperature to the set temperature in the preheating stage. Because the heating rate X calculated by the above formula may vary, for example, different X values may be used each time the equipment is turned on. In addition, different X values may also be used for different equipment in different operating environments. Due to with this, the operating environment of the imaging device and the differences between equipments are taken into account when determining the X value calculated by the above formula. This calculation method has high applicability.

In this embodiment, the heating rate in the preheating stage is calculated every time the equipment is turned on or woken up. For example, the heating rate can be calculated based on the time required to heat up from a temperature set at a certain point after turning on the equipment to 150°C (this could also be another temperature range specified by the imaging device).

In some embodiments, when the imaging device is turned on, the temperature of the fixing unit is already above the set temperature above (eg, the temperature of 150° C. above). For example, if the imaging apparatus was turned off at a relatively high temperature and then restarted, or the imaging apparatus is restarted due to a malfunction or other reasons, then empirical data is used as the heating rate X at that time.

When the image processing apparatus is in the printing mode of the nth page of the printing medium, the heating rate of the curing unit is calculated based on changes in the temperature set in the process of starting heating of the curing unit until the predetermined target temperature is reached. In this embodiment, when the image processing apparatus is in the printing mode of the nth page of the printing medium, the heating rate is calculated based on changes in the temperature set during the start of heating of the curing unit and when printing the n-1th page of the printing medium until the specified target is reached temperature. This heating rate by substitution into the formula is used to calculate the start time of heating of the curing unit when printing the nth page of the printed medium, where n is a natural number and n≥2.

For example, when printing n page of printing media, the heating rate can be calculated based on changes in the temperature set during the process of starting heating of the curing unit and printing the n-1th page of printing media until the predetermined target temperature is reached. For example, when printing the n-1th page of printed media during the heating block stage of the curing unit to a given target temperature, the heating rate calculation is performed based on the time required for each increase in temperature by one degree, or the heating rate calculation is performed based on the number of degrees of the curing unit, increased per unit time; then, based on this heating rate, the start time of heating of the curing unit when printing n page of the printing medium is determined.

In this embodiment, based on the temperature changes in the preheating step of the curing unit, a first heating rate of the curing unit is calculated. Next, the first heating rate is used by substitution into the formula to calculate the start time of heating of the curing unit when printing the first page of the printed medium. In addition, in the process of printing the first page of the printing medium, a second heating rate is calculated based on changes in the temperature set in the process of starting heating of the curing unit until the set target temperature is reached. This second heating rate is used by substitution into the formula to calculate the start time of heating of the curing unit when printing the second page of the printing medium. The start time for heating the curing unit during and after printing the third page of the printed medium is calculated in the same way.

In this embodiment, the heating rate calculated in the preheating step by substitution into the formula is used to calculate the start time of heating of the curing unit when printing the first page of the printing medium. The heating rate calculated when printing the n-1st page of the printed medium, by substitution into the formula, is used to calculate the start time of heating of the curing unit when printing the n-th page of the printed medium, that is, when printing each page of the printed medium, the heating start time can be flexibly changed clamping unit to realize on-demand heating and further reduce energy consumption.

At step S12, based on the route from the predetermined position to the central position of the curing unit, as well as the speed of movement of the printing medium and the time t1, the heating start time of the curing unit is determined.

Specifically, after determining the route from the predetermined position to the central position of the curing unit, the moving speed of the printing medium, the current temperature or the temperature set at a certain time, as well as the predetermined target temperature of the curing unit and the heating speed, the heating start time of the curing unit can be determined by the formula ( S-Vt0)/V≥(T1-T0)/X, that is, the value of t0 is determined,

where S is the route from a given position to the central position of the curing unit, V is the speed of movement of the printed medium, T1 is the specified target temperature of the curing unit, T0 is the current temperature of the curing unit or the temperature set at a certain moment of the curing unit, X is the heating rate of the curing unit , t0 is the start time of heating of the fixing block, t0 is the requested value.

In this embodiment, the path of movement of the printing medium from the position where the sensor is installed to the center position of the fixing unit is the path from the predetermined position to the central position of the fixing unit. For example, during the printing step, it is determined whether an installed media sensor (eg, a paper motion sensor) is triggered. When triggered, it is necessary to divide the distance from this sensor to the fixing unit by the speed of movement of the printed medium to obtain the first moment in time. In addition, it is necessary to subtract the difference of the current temperature or the temperature set at a certain time from the set target temperature of the curing unit, and then divide by the heating rate to obtain the second time point. If the second time is shorter than the first time, then the range of intervals required to match the starting point of heating of the fixing unit is determined. That is, it is required that the fixing unit time reached by t1 from the heating time point be no later than the time when the printing medium reaches the center position of the fixing unit.

For example, it is already known that S is 30 mm, V is 5 mm/s, and the time required to increase the temperature of the curing unit from 25°C to 150°C during the preheating stage before the printing operation is 5 s, then the heating rate X, calculated using the formula X=(150°С-25°С)/5 s will be 25°С/s. If, when printing the first page of printed media is started, the current temperature of the curing unit or the temperature set at a certain moment is 145°C, and the set target temperature of the curing unit is 195°C, then the heating start time t0 of the curing unit when printing the first page of printed media, calculated according to the formula (30-5t0)/5≥ (195-145)/25 will be less than or equal to 4 s. If t3 and t3≥0 are used as the time during which the printing medium reaches a predetermined position, then the time range from t3 to t3+4 s represents the time range for the start of heating of the curing unit when printing the first page of the printing medium, that is, it is required so that the start of heating of the fixing block is no later than t3+4 s. It is preferable that t3+4 s be used as the starting time for heating the curing unit when printing the first page of the printing medium, since the power consumption of the curing unit will be reduced.

If the temperature at the start of heating the curing unit and printing the first page of the printed medium is 140°C and the set target temperature is 195°C, and the time required to increase the temperature of the curing unit from 140°C to 195°C is 5 s, then the heating rate X, calculated using the formula X=(195°С-145°С)/5 s will be 10°С/s. If, when printing the first page of printed media is started, the current temperature of the curing unit or the temperature set at a certain moment is 168°C, and the set target temperature of the curing unit is 195°C, then the heating start time t0 of the curing unit when printing the first page of printed media, calculated according to the formula (30-5t0)/5≥ (195-165)/10 will be less than or equal to 2 s. If t4 and t4≥0 are used as the time during which the printing medium reaches a predetermined position, then the time range from t4 to t4+2 s represents the time range for the start of heating of the curing unit when printing the second page of the printing medium, that is, it is required so that the start of heating of the fixing block is no later than t4+2 s. It is preferable that t4+2 s be used as the starting time for heating the curing unit when printing the first page of the printed medium, since the energy consumption of the curing unit will be reduced or the amount of energy consumption will be equal to 0. The starting time for heating the curing unit during and after printing the third page is calculated in the same way printed media. Therefore, this information will not be repeated.

In the present application, based on the fact that the time during which the printing medium from a certain position reaches the central position of the curing unit is less than or equal to the time required for heating the curing unit from the initial temperature to the target temperature, then through the formula (S-Vt0)/ V≥(T1-T0)/X determines the exact heating time t0 of the fixing block. This process prevents wasteful energy consumption caused by an excessively long heating period, as well as excessively short heating time of the curing unit and failure to meet the predetermined target temperature, which has a positive effect on the fusing effect of toner on paper.

It should be understood that the interval between the time reached by t1 from the heating time of the curing unit and the time during which the printing medium reaches the center position of the curing unit depends at least on the type of paper, the printing mode, the ambient temperature and the duration of use of the equipment. In other words, the preset heating start time depends on the operating environment or equipment parameters. For example, if the user selects the high quality printing mode, then to ensure sufficient curing effect, it is necessary to pre-set the heating start time (since high quality printing may increase the image concentration, a longer heating period is required to ensure sufficient curing effect).

For example, if the user has selected relatively thick paper (such as envelope paper/letter paper), then the heating start time must be preset.

For example, if a relatively low ambient temperature is detected, the heating start time must also be preset.

For example, if a relatively high ambient temperature is detected, the heating start time must also be preset.

For example, if the equipment has been used for a long period of time and the thermistor detection results or the heating effect of the heater may be different from those expected, it is also necessary to pre-set the heating start time.

Based on the above embodiment, the embodiments of the present application are also disclosed as an image processing apparatus. This image processing device includes a main body and a fixing unit. For the main body, the heating control method of any of the above embodiments is used, which is used to control the heating of the fixing unit.

Based on the above embodiment, the embodiments of the present application are also disclosed as an image processing apparatus. For this image processing apparatus, the heating control method of any of the above embodiments is used to control the heating of the fixing unit. In fig. 3 is a block diagram of modules of an image processing apparatus provided in an embodiment of the present application. This image processing apparatus includes a first determination unit 100 and a second determination unit 200. The first determination unit 100 is used to determine the time t1 required to increase the current temperature of the fixing unit or the temperature set at a certain time to a specified target temperature. The second determination unit 200 is used to determine the start time of heating of the curing unit based on the route from a predetermined position to the central position of the curing unit, as well as the speed of the printing medium and the time t1.

Based on the above embodiment, the present application also discloses an image processing apparatus. A laser color printer is used as an image processing device. For the laser color printer, the heat control method of any of the above embodiments is used to control the heat of the fuser. The difference between this embodiment and the above embodiment is that in this embodiment, the path of the image from the molding position to the central position of the fixing block is specified as the path from the predetermined position to the central position of the fixing block.

In fig. 4 is a schematic diagram of a structure of an image processing apparatus presented in this embodiment. A laser color printer is used as this image processing device. The laser color printer includes 10 transfer ribbon 105, secondary transfer roller 106, paper feed tray 107, manual paper feeder 108, paper feed roller 109, paper transport roller 110, laser scanning unit (LSU) 111, heating roller 112, press roller 113, paper unloading roller 114 and paper unloading tray 115, etc. In this case, the group of technological cartridges includes four technological cartridges, and each technological cartridge includes a photodrum 101Y-101K (101Y, 101M, 101C, 101K), a primary charge shaft 102Y-102K (102Y, 102M, 102C, 102K), a developing shaft 103Y-103K (103Y, 103M, 103C, 103K) and 104Y-104K (104Y, 104M, 104C, 104K) toner storage tank.

The Laser Scanning Unit (LSU) 111 is a separate LSU component that includes four optical paths. Four 102Y-102K primary charge shafts are used to charge the surface of four 101Y-101K photoconductors. The four optical paths of the laser scanning unit emit laser beams to form electrostatic latent images on the surface of photo drums 101Y-101K, and the developing roller 103Y-103K is used to develop a single color toner image on the surface of photo drums 101Y-101K. The image processing apparatus 10 adopts a secondary transfer method, that is, four photoconductors 101Y to 101K sequentially transfer a toner image to the transfer ribbon 105, and then the color toner image formed on the transfer ribbon 105 is secondary transferred to paper via the secondary transfer roller 106. Feed Tray Paper 107 is used to store paper, paper feed roller 109 is used to transport the stored paper according to the set route. The paper transfer roller 110 is used to transport the paper to the secondary transfer roller 106.

The secondary transfer roller 106 moves the image paper into a pressure zone formed between the heat roller 112 and the press roller 113. The heat roller 112 and the press roller 113 are used to fix the toner image on the paper. For the heating roller 112, a heating method using a ceramic plate can be used. The heat roller 112 and the press roller 113 move the image-fixed paper to the paper discharge roller 114. The paper discharge roller 114 discharges the paper into the paper discharge tray 115 and stacks the paper.

In this embodiment, after each color of the LSU is irradiated to the photoconductor, a corresponding image is formed. If the image path to the curing unit from the irradiation location of each color LSU to the drum position (heating roller 112 and press roller 113) is designated as S, the printing speed is V, the current temperature of the curing unit or the temperature set at a certain time is T0 , the set target temperature of the curing unit is T1, and the heating rate is X, then the heating start time t0 of the curing unit can be calculated by the formula (S-Vt0)/V≥(T1-T0)/X.

In some embodiments, the image path to the fixing unit from the irradiation location LSU to the photoconductor 101Y is denoted as S, and the image path to the fixing unit from the irradiation location LSU to the photoconductor 101M is also denoted as S; either the image path to the fixing unit from the irradiation location LSU to the photoconductor 101C is designated as S, or the image path to the fixing unit from the irradiation location LSU to the photoconductor 101K is designated as S.

In some embodiments, path S can be designated as the path of the image from the irradiation location of the LSU to the position of the photoconductor, the image on the photoconductor is transferred to the transfer ribbon + the route in which the image on the transfer ribbon is transferred to the paper + the route in which the paper moves from the transfer point printing to the center position of the fixing unit, among which the center position indicates the pressure zone formed between the heating roller 112 and the press roller 113.

In this embodiment, the start time of heating of the curing unit is determined by the signal (TOD signal) used for image forming control. The TOD signal is usually inactive. When forming an image, when the TOD signal is triggered, it is necessary to record the time t5, that is, determine the time range for the start of heating of the curing unit. For example, after calculating the heating start time t0 according to the formula (S-Vt0)/V≥(T1-T0)/X, the time range from t5 to t5+t0 represents the heating start time range of the curing unit when printing the printing medium. It is preferable that t5+t0 be used as the heating start time of the fixing unit.

In the present application, based on the fact that the time during which the image travels the route to the fixing unit from the irradiation site LSU to the position of the photodrum is less than or equal to the time required to heat the fixing unit from the initial temperature to the target temperature, then through the formula (S-Vt0 )/V≥(T1-T0)/X the exact heating time t0 of the fixing block is determined. This process prevents wasteful energy consumption caused by an excessively long heating period, as well as excessively short heating time of the curing unit and failure to meet the predetermined target temperature, which has a positive effect on the fusing effect of toner on paper.

The above description represents only preferred embodiments of the present application, however, the scope of protection of the present application is not limited to this description. Changes or substitutions may readily be contemplated by one skilled in the art within the technical scope disclosed herein, which are intended to be included within the scope of protection of this application. Therefore, the scope of protection of the present application should be determined by the scope of protection of the claims.

Claims (38)

1. A heating control method for controlling heating of a fixing unit, comprising the steps of: when the imaging device is in print mode, determining a time t1 required to increase the current temperature of said fixing unit or a temperature set at a certain moment to a predetermined target temperature; determining the start time of heating of said fixing unit based on the route from a given position to the central position of said fixing unit, as well as the speed of movement of the printing medium and time t1. 2. The heating control method according to claim 1, wherein in the step of determining the time t1 required to increase the current temperature of said fixing unit or the temperature set at a certain moment to a given target temperature: determining the heating rate of said fixing unit; calculating the time t1 based on the heating rate, the current temperature or the temperature set at a certain moment, as well as the set target temperature of the said fixing unit. 3. The heating control method according to claim 2, wherein in the step of calculating time t1 based on the heating rate, the current temperature or the temperature set at a certain moment, as well as the set target temperature of said fixing unit: time t1 is calculated using the formula t1=(T1-T0)/X; where T1 is the set target temperature of the mentioned fixing unit, T0 is the current temperature or the temperature set at a certain moment of the mentioned fixing unit, X is the heating rate of the mentioned control unit. 4. The heating control method according to claim 2, in which, at the stage of determining the heating rate of said fixing unit: when the imaging device is in print mode of the first page of the print media, calculating the heating rate based on temperature changes during the preheating step of said fixing unit. 5. The control method according to claim 4, in which, at the stage of calculating the heating rate based on temperature changes during the preheating stage of said fixing unit: during preheating stage calculating the heating rate based on the time required for each increase in the temperature of said fixing unit by one degree; or the heating rate is calculated based on the number of degrees of said fixing unit increased per unit time. 6. The heating control method according to claim 2, in which, at the stage of determining the heating rate of said fixing unit: when the image processing device is in the printing mode of the nth page of the printing medium, where n is a natural number and n≥2, calculating said heating rate based on changes in temperature set during the start of heating of said fixing unit. 7. The heating control method according to claim 6, in which, at the stage of determining the heating rate of said fixing unit: When the image processing apparatus is in the printing mode of the nth page of the printing medium, the heating speed is calculated based on the temperature set in the process of starting heating of the curing unit and printing the n-1th page of the printing medium, as well as the set target temperature of the fixing unit, where n is a natural number and n≥2. 8. The heating control method according to claim 7, wherein at the stage of calculating the heating rate based on changes in the temperature set during the start of heating of the said fixing unit until the specified target temperature is reached: at the stage when the temperature set in the process of starting heating of the fixing unit reaches the set target temperature, calculating the heating rate based on the time required for each increase in the temperature of said fixing unit by one degree; or the heating rate is calculated based on the number of degrees of said fixing unit increased per unit time. 9. The heating control method according to claim 1, wherein the route from a predetermined position to a central position of said fixing unit includes: a path of movement of said printing medium from a position where the sensor is installed to a central position of said fixing unit. 10. The heating control method according to claim 1, wherein the route from a predetermined position to a central position of said fixing unit includes: the path of movement of the image in the image processing device from the forming position to the central position of the fixing unit. 11. Method of heating control according to any one of claims. 1-10, in which the start time of heating of said fixing unit corresponds to: the time reached by t1 from said time point, not later than the time when said printing medium reaches the central position of said fixing unit. 12. The heating control method according to claim 11, in which the interval between the time reached by t1 from said time point and the time when said printing medium reaches the central position of said fixing unit depends at least on the type of paper, the printing mode, the ambient temperature and the duration of use of the equipment. 13. An image processing device comprising a main body and a fixing unit, wherein the heating control method according to any one of claims is used for said main body. 1-12, which is used to control the heating of said fixing unit. 14. An image processing device comprising: a first determination unit (100) configured to determine the time t1 required to increase the current temperature of the fixing unit or the temperature set at a certain moment to a predetermined target temperature; a second determination unit (200) in which the start time of heating of said fixing unit is determined based on the route from a given position to the central position of said fixing unit, as well as the speed of movement of the printing medium and time t1.

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