KR20210112745A - Fan control based on sensing current of coil - Google Patents

Abstract

Disclosed is an image forming device. The image forming device comprises: a print engine that forms an image; a fan for generating airflow in the image forming device; an electrical component including a coil; a driving circuit that provides driving power to the fan and senses a current flowing through the coil; and a processor that estimates temperature around the coil based on the current flowing through the coil and controls an operation of the fan based on estimated temperature.

Description

Fan control using coil sensing current {FAN CONTROL BASED ON SENSING CURRENT OF COIL}

An image forming apparatus is an apparatus for generating, printing, receiving, and transmitting image data, and representative examples include a printer, a scanner, a copier, a fax machine, and a multifunction device that integrates these functions.

In such an image forming apparatus, a fan is used so that the internal temperature does not rise above a certain level.

1 is a block diagram illustrating a simplified configuration of an image forming apparatus according to an embodiment of the present disclosure;
2 is a block diagram illustrating a detailed configuration of an image forming apparatus according to an embodiment of the present disclosure;
3 is a view for explaining an example of a fan control method using a sensing current of a coil;
4 is a diagram for explaining the relationship between temperature and coil resistance;
5 is a view showing an example of a sensing circuit when the coil component is a motor;
6 is a view showing an example of a sensing circuit when the coil component is a solenoid;
7 is a view showing an example of a sensing circuit when the coil component is a transformer;
8 is a view showing an example of a change in a sensed current value when a fan is driven;
9 is a flowchart for explaining an embodiment of an image forming method of the present disclosure.

Hereinafter, various embodiments will be described in detail with reference to the drawings. The embodiments described below may be modified and implemented in various other forms. In order to more clearly describe the features of the embodiments, detailed descriptions of matters widely known to those of ordinary skill in the art to which the following embodiments belong will be omitted.

On the other hand, in the present specification, when a component is "connected" with another component, it includes not only a case of 'directly connected', but also a case of 'connected with another component interposed therebetween'. In addition, when a component "includes" another component, this means that other components may be further included, rather than excluding other components, unless otherwise stated.

As used herein, the term “image forming job” may mean various jobs (eg print, scan, or fax) related to an image, such as forming an image or creating/storing/transmitting an image file, and “job ( job)” not only means an image forming job, but may also include all a series of processes for performing the image forming job.

In addition, the term "image forming apparatus" refers to a device that prints print data generated by a terminal device such as a computer on a recording paper. Examples of such an image forming apparatus include a copier, a printer, a facsimile, or a multi-function printer (MFP) that complexly implements these functions through one device.

Also, “print data” may mean data converted into a printable format by a printer. On the other hand, if the printer supports direct printing, the file itself may be print data.

Also, the term “user” may mean a person who performs an operation related to an image forming operation using an image forming apparatus or a device connected to the image forming apparatus by wire or wireless.

1 is a block diagram illustrating a simplified configuration of an image forming apparatus according to an exemplary embodiment of the present disclosure.

Referring to FIG. 1 , the image forming apparatus 100 may include a print engine 110 , an electrical component 120 , a fan 130 , a driving circuit 140 , and a processor 150 .

The print engine 110 performs an image forming job. For example, the print engine 110 may include a photosensitive drum, a charger, an exposure machine, a developer, a transfer machine, and the like, and may perform a printing operation using a laser method.

The electrical component 120 includes a coil and is a component provided inside the image forming apparatus 100 , and may be a motor such as a DC motor, a step motor, a solenoid, a clutch, a transformer, or the like. Here, a DC motor, a step motor, a clutch, a solenoid, etc. may be used to start the print engine 110 , and the transformer may be a component of a power supply device that supplies power inside the image forming apparatus 100 .

The electric component 120 may be disposed on the air flow generated by the fan 130 . Meanwhile, in the illustrated example, the electrical component 120 and the print engine 110 are illustrated and described as having different configurations, but in implementation, the electrical component 120 may be a configuration of the print engine 110 . In addition, one electrical component 120 may be used, or a plurality of electrical components 120 may be used. The electrical component 120 including such a coil may be referred to as a coil component.

The driving circuit 140 may generate driving power for the fan 130 according to a control command. For example, upon receiving a driving command (eg, current magnitude information) from the processor 150 , the driving circuit 140 may generate a constant current corresponding to the received driving command and provide it to the fan 130 . have.

For example, when the fan 130 is driven by a DC motor, the driving circuit 140 may generate a constant current and provide the generated constant current to the DC motor. In this case, the driving circuit 140 may vary the magnitude of the constant current or the supply duty of the constant current (ie, pulse width modulation (PWM) duty) according to the received driving command.

Also, the driving circuit 140 may provide driving power to the electric component 120 requiring driving power. For example, when the electric component 120 is a DC motor, a constant current for driving the DC motor can be generated and provided, and when the electric component 120 is a solenoid, a DC voltage of a predetermined size can be provided. .

In addition, the driving circuit 140 may sense the magnitude of the current flowing through the coil of the electric component 120 . For example, the driving circuit 140 may detect a voltage value corresponding to the magnitude of a current flowing through the coil of the electric component 120 using a shunt resistor connected in series to the coil.

The voltage of the shunt resistor changes in proportion to the temperature of the electrical component 120 , and in the present disclosure, the temperature of the electrical component 120 may be estimated using the voltage value of the shunt resistor. A correlation between the voltage of the shunt resistor and the temperature of the electrical component 120 will be described later with reference to FIG. 4 .

In addition, the driving circuit 140 may signal-process the sensed current and output it. For example, the driving circuit 140 may low-pass filter the voltage of the shunt resistor corresponding to the change in current of the coil, amplify the low-pass filtered voltage value, and output the amplified voltage to the processor 150 . A detailed configuration and operation of the driving circuit 140 will be described later with reference to FIGS. 5 to 7 .

The fan 130 may generate air flow in the image forming apparatus 100 . For example, the fan 130 may include a plurality of blades and a motor for rotating the plurality of blades. The fan 130 may be a common fan for discharging air inside the image forming apparatus to the outside (or introducing outside air), and a specific component (or part) in the image forming apparatus (eg, a fixing unit, a SMPS (Switching Mode) It may be a fan to cool the Power Supply)).

The processor 150 may control the overall operation of the image forming apparatus 100 . For example, the processor 150 may control the overall operation of the image forming apparatus 100 by executing at least one pre-stored instruction.

In addition, when a print job is required, the processor 150 may control the print engine 110 to perform a print operation. For example, when the electric component 120 is a motor for transferring paper, the processor 150 transmits control commands such as rotation start/stop, acceleration/deceleration, and speed command value for the motor to the driving circuit 140 . can

Meanwhile, in the present embodiment, the processor 150 directly transmits the control command for the electrical component 120 to the electrical component 120 , but in implementation, the print engine 110 controls the electrical component 120 . You can also send commands.

In addition, the processor 150 may estimate the temperature of the electrical component (or the ambient temperature of the electrical component) based on the current information (ie, the current magnitude information of the coil) provided by the driving circuit 140 . For example, the processor 150 may calculate (or estimate) the temperature around the electrical component 120 based on the magnitude of the voltage transmitted through the ADC port (or terminal). The temperature estimated herein may be an actual temperature value, but various forms may be used. For example, a high/low value indicating whether a fan is required to be driven may be estimated, and a value within a range of 0 to 10 may be calculated.

In this case, the processor 150 may estimate the temperature using current information of each of a plurality of electrical components instead of one electrical component. For example, when the first electrical component and the second electrical component are disposed around the fan 130 , the processor 150 provides information on the current flowing through the coil of the first electrical component and the current flowing through the coil of the second electrical component. The first temperature value and the second temperature value may be calculated using each of the information, and the temperature around the electric component may be estimated by using the higher value of the two calculated values or calculating an average value.

On the other hand, when one of the two electrical components is a DC motor, the processor 150 estimates the temperature by using the current flowing in the coil of the first electrical component only when the DC motor is not driven, and when the DC motor is driven In this case, the temperature may be estimated using the current of the coil of the second electric component 120 - 2 other than the motor.

In addition, the processor 150 may control the operation of the fan 130 based on the estimated temperature. For example, the processor 150 may control the driving circuit 140 to drive the fan when the estimated temperature is equal to or greater than a preset temperature (ie, a betting temperature that requires fan driving). By this operation, the driving circuit 140 may provide driving power to the fan, and the fan 130 may generate an air flow by rotating a motor to which a plurality of blades are connected.

In this case, the processor 150 may control the driving circuit 140 so that the fan 130 rotates corresponding to the temperature. For example, when the estimated temperature of the processor 150 is high, the driving circuit 140 is controlled to supply driving power to the fan 130 to rotate at a high speed, and when the estimated temperature is relatively low, the driving circuit 140 is controlled at a low speed. The driving circuit 140 may be controlled so that driving power enabling rotation is supplied to the fan.

When implemented, the processor 150 may calculate a PWM duty for driving the fan corresponding to the estimated temperature, and provide the calculated PWM duty to the driving circuit 140 . The driving circuit 140 may provide driving power corresponding to the provided PWM duty to the fan 130 .

In addition, the processor 150 may control the driving circuit 140 to stop the rotation of the fan 130 when the estimated temperature is less than a preset temperature. The temperature for stopping the operation of the fan may be the same as the temperature for starting the operation of the fan, or may be different. That is, when the two temperature values are different, the processor 150 may hysterically control the operation of the fan 130 with respect to the estimated temperature.

Meanwhile, when the image forming apparatus 100 includes a plurality of fans, the processor 150 may control an operation of each of the plurality of fans. In this case, the processor 150 may use a temperature estimated from an electrical component corresponding to the fan to control each fan.

For example, when a first fan and a second fan are disposed in the image forming apparatus 100 , and a first electrical component is disposed around the first fan and a second electrical component is disposed around the second fan, the processor 150 ) may control the first fan based on the first temperature estimated in the coil of the first electrical component. In addition, the processor 150 may control the second fan based on the second temperature estimated in the coil of the second electrical component.

Also, the processor 150 may estimate the internal temperature of the system by considering the first temperature and the second temperature together. For example, the processor 150 may estimate the average value of the first temperature and the second temperature as the betting temperature, or may estimate the betting temperature by reflecting a weight for each temperature.

Also, the processor 150 may control the operation of the image forming apparatus 100 based on the calculated temperature of the electrical component 120 . For example, the processor 150 may determine whether the calculated temperature of the electrical component is a normal range or a temperature outside the normal range, and if the temperature is outside the normal range, a limited printing operation may be performed or a printing operation may not be performed. .

For example, if the calculated temperature is a preset first temperature range, the processor 150 may perform the requested print job, ie, operate in a normal mode. Conversely, the processor 150 may perform the requested job in the stress mode when the calculated temperature is in the second temperature section higher than the preset first temperature section. Here, the stress mode is a mode for performing a print job by limiting the performance of the image forming apparatus 100 .

The developing operation of the image forming apparatus 100 is affected by the internal temperature of the image forming apparatus 100 . In addition, the temperature of the electrical component 120 may be the same as the temperature in the image forming apparatus 100 before the printing operation or in a state in which a predetermined time has elapsed after the printing operation is performed.

In this regard, the processor 150 may determine a developing condition corresponding to the calculated temperature, and control the print engine 110 based on this. Meanwhile, although it has been described that only the developing condition is varied in the above example, in implementation, all conditions in a series of printing operations, such as a fixing condition and a charging condition, may be determined according to the calculated temperature.

Meanwhile, although only a simple configuration of the image forming apparatus has been illustrated and described above, various configurations may be additionally provided in implementation. This will be described below with reference to FIG. 2 .

2 is a block diagram illustrating a detailed configuration of an image forming apparatus according to an exemplary embodiment of the present disclosure.

Referring to FIG. 2 , an image forming apparatus 100 according to an embodiment of the present disclosure includes a print engine 110 , an electrical component 120 , a fan 130 , a driving circuit 140 , a processor 150 , and a communication system. It may be composed of a device 160 , a memory 170 , a display 180 , and an input device 190 .

Since the print engine 110 , the electrical component 120 , the fan 130 , and the driving circuit 140 have been described with reference to FIG. 1 , a redundant description will be omitted. In addition, since the processor 150 has also been described with reference to FIG. 1 , the contents described in FIG. 1 will not be repeated, and only the contents related to the configuration added to FIG. 2 will be described below.

The communication device 160 may be connected to a print control terminal (not shown) and receive print data from a print control terminal (not shown). Here, the print control terminal device is an electronic device that provides print data, and may be a personal computer (PC), a notebook computer, a tablet PC, a smart phone, a server, or the like.

The communication device 160 is formed to connect the image forming apparatus 100 to an external device, and is connected to a terminal device through a local area network (LAN) and an Internet network, as well as a Universal Serial Bus (USB). ) port or a wireless communication (eg, WiFi 802.11a/b/g/n, NFC, Bluetooth) port is also possible. Such a communication device 160 may be referred to as a transceiver.

In addition, the communication device 160 may receive print data from a print control terminal device (not shown). In addition, when an error occurs in the image forming apparatus 100 , the communication device 160 may notify the management server (or the manager terminal device) of the error.

The memory 170 may store at least one instruction related to the image forming apparatus 100 . For example, various programs (or software) for operating the image forming apparatus 100 according to various embodiments of the present disclosure may be stored in the memory 170 .

The memory 170 may store print data. For example, the memory 170 may store the print data received from the above-described communication device 160 . The memory 170 may be implemented not only as a storage medium in the image forming apparatus 100 , but also as an external storage medium, a removable disk including a USB memory, or a web server through a network.

In addition, the memory 170 may store information on the size of the current for temperature measurement. In addition, the memory 170 may store temperature information of the electrical component 120 corresponding to the voltage value sensed at the ADC port of the processor 150 . In addition, when implemented, the memory 170 may store calculation formula information for calculating the above-described temperature information.

The display 180 may display various types of information provided by the image forming apparatus 100 . For example, the display 180 may display an operation state of the image forming apparatus 100 or display a user interface window for selecting functions and options that a user can select.

In addition, the display 180 may display the operating state of the image forming apparatus 100 . For example, when a failure of the fan in the image forming apparatus 100 is confirmed, the display 180 may indicate that the fan has failed.

In addition, the input device 190 may include a plurality of function keys through which the user can set or select various functions supported by the image forming apparatus 100 . The input device 190 may be implemented as a device such as a mouse or a keyboard, or may be implemented as a touch screen capable of simultaneously performing the functions of the above-described display 180 . Through this, the user may input various driving commands for the image forming apparatus 100 .

When print data is received from the communication device 160 , the processor 150 may determine the operation mode of the image forming apparatus 100 according to the number of prints of the received print data and the temperature of the electrical component 120 .

When a failure of the fan 130 is confirmed, the processor 150 may control the display 180 to display failure information. In this case, the processor 150 may control the communication device 160 so that the failure information can be delivered to the manager.

As described above, the image forming apparatus 100 according to an embodiment of the present disclosure may detect the cabin temperature without an increase in material cost due to the addition of a separate temperature sensor, and may control the fan using the detected cabin temperature. . Also, the image forming apparatus 100 may check whether the fan is operating normally, even if an expensive fan motor having a feedback function is not used.

In the illustration and description of FIGS. 1 and 2 , only the form in which one driving circuit controls one electrical component has been described, but in implementation, one driving circuit can control a plurality of electrical components, and one driving circuit can control a plurality of electrical components. The driving circuit may control other electrical components and the like while controlling the electrical components.

1 and 2, the electrical component 120 is shown and described as a separate component distinct from the print engine or the driving circuit, but in implementation, the electrical component may be a component within the print engine, , may be a configuration in the driving circuit.

In addition, in the illustration and description of FIGS. 1 and 2 , the image forming apparatus 100 is illustrated and described as having one fan, but in implementation, the image forming apparatus 100 may include a plurality of fans. have. When a plurality of fans are provided, the processor 150 may control the plurality of fans in common, and may individually control each of the plurality of fans.

In addition, in the above example, it has been described that the temperature of the electrical component is calculated based on the voltage value of the shunt resistor. However, when implemented, the calculated temperature of the electrical component can be used as the internal temperature of the image forming apparatus 100 . . For example, the temperature of the electrical component may be the same as the internal temperature of the image forming apparatus before the printing operation or after a predetermined time after the printing operation is performed. Accordingly, the temperature of the electrical component at this point in time may be utilized as the temperature in the image forming apparatus.

3 is a view for explaining a fan control method using a sensing current of a coil.

There are various heat sources inside the image forming apparatus 100 , such as a fixing device that fixes an image on paper using heat and pressure, and an SMPS that converts AC (Alternating Current) power into DC (Direct Current) power.

Such a heat source may increase the internal temperature of the image forming apparatus 100 and cause problems such as toner solidification or thermal error. To prevent this, the image forming apparatus 100 may include a fan 130 around the heat source.

The fan 130 forms an airflow so that the temperature inside the image forming apparatus 100 does not rise above a certain level.

However, since driving of the fan 130 generates noise and increases current consumption, it can be driven only at a necessary time. For this operation, the image forming apparatus requires a temperature sensor for measuring the inside temperature.

In addition, since the above-mentioned problems may occur even when the fan motor does not operate due to a malfunction of the fan motor, assembly defects such as failure of the fan connector, or a motor failure, additional parts for checking whether the fan operates normally were also required. .

However, when a temperature sensor and a sensing circuit are separately added for fan control, a design burden and cost may increase. Accordingly, the present disclosure discloses a method for estimating the indoor temperature using a configuration provided in the prior art, and confirming whether the fan operates.

The fan 130 may be positioned to provide an air flow to the heat sources as described above. For example, the fan 130 may be a fan for cooling the fixing unit, a fan for cooling the SMPS, or a fan for introducing external air into the image forming apparatus 100 .

In order to control the fan 130 , the processor 150 must determine whether the fan needs to be driven. This means that the temperature of the target area must be known. To this end, in the present disclosure, electric components disposed around the fan 130 or the heat source are used. A fan or electrical component placed around a heat source will vary in temperature depending on the operation of the heat source and the operation of the fan.

For example, when the heat source is a fuser and the fan is a fuser fan, the temperature of the roller rotating the fuser roller varies according to the heat of the fuser and the operation of the fan. Alternatively, if the fan 130 is used to cool the SMPS, a transformer (ie, a transformer) in the SMPS may be used as the corresponding electrical component 120 .

Accordingly, it is possible to use an electrical component having a coil in a configuration disposed at a position affected by the operation of the heat source and the fan.

Hereinafter, for ease of explanation, it is assumed that the heat source is viewed as a fixing device, the fan 130 is used to cool the fixing device, and the electric component is a DC motor. In addition, the driving circuit 140 may include the shunt resistor 201 and the sensing circuit 200 shown in FIG. 3 . Also, the driving circuit 140 may include a driving circuit for driving a fan and/or an electric component.

The sensing circuit 200 may measure the voltage of the shunt resistor 201 connected in series with the coil 121 of the DC motor. The shunt resistor 201 is a component included in the circuit configuration for controlling the DC motor. In the present disclosure, such a shunt resistor 201 may be used not only for basic operation (ie, motor control), but also for measuring a current magnitude of a coil.

In the illustrated example, the shunt resistor 201 is illustrated and described as a configuration in the driving circuit 140 , but the shunt resistor 201 may be a configuration inside the electric component 120 .

The sensing circuit 200 may provide the measured voltage value to the processor 150 . For example, the sensing circuit 200 may measure a voltage across the shunt resistor 201 . A detailed configuration and operation of the sensing circuit 200 will be described later with reference to FIG. 5 .

The processor 150 may estimate a temperature based on the provided voltage, and determine whether the fan needs to be driven according to the estimated temperature.

If it is determined that the fan should be operated, the processor 150 may control the driving circuit 140 to drive the fan 130 .

When the fan 130 operates normally, air flow occurs. Accordingly, the temperature around the electrical component 120 may change. Accordingly, the temperature estimated by the processor 150 through the above-described process may be lower than the existing measured value.

If the estimated temperature (or the temperature of the electrical component 120 ) does not decrease after the fan is driven, the processor 150 may determine that the fan does not operate normally. For example, the processor 150 determines that an error has occurred if the second estimated temperature after a preset time after the fan is driven is greater than the estimated first temperature before the fan is driven, or the temperature drop per minute is less than the preset value. In this case, it may be determined that an error has occurred.

If it is determined that an error has occurred in this way, the processor 150 may control the display 180 to provide an alarm. If necessary, the processor 150 may control the communication device 160 to notify the administrator of the occurrence of an error.

Hereinafter, a reason that can be used to estimate the temperature of an electrical component based on the magnitude of the current flowing through the coil will be described with reference to FIG. 4 .

4 is a diagram for explaining a relationship between temperature and coil resistance.

The amount of change in the temperature of the coil can be predicted through the amount of change in the resistance of the coil. As a material of the coil, copper or aluminum with good conductivity is mainly used. As shown in FIG. 4, the resistance value of these metal materials increases proportionally as the temperature rises, and a unique temperature resistance increase coefficient according to the material. (Ω/°C).

Accordingly, it is possible to calculate the amount of change in the coil temperature by the amount of change in the resistance value of the coil. A motor, a solenoid, a clutch, a transformer, etc. may be used as an electric component having such a coil.

And the resistance value of the coil can be found by measuring the current flowing through the coil. Since the voltage flowing through the coil is usually a fixed value or a value already known during the control process, when the current value is measured, the coil resistance value can be calculated using the previously known voltage value and the measured current value.

On the other hand, the current flowing in the coil may be a Hall element type current sensor IC, and it is also possible to calculate the current by measuring the voltage of the shunt resistor. Hereinafter, the use of a shunt resistor will be described as an example, but as described above, it may be implemented as a current sensor IC.

On the other hand, it is difficult to measure the resistance of the coil because the back electromotive force component is introduced during operation of the motor. Accordingly, in the present disclosure, when the motor is operating, the temperature can be estimated using an electric part other than the motor, and the temperature can be measured using the shunt resistor connected to the motor only when the motor is not operating.

Hereinafter, a detailed configuration and operation of the driving circuit 140 will be described in the case where the electric component is a motor.

5 is a diagram illustrating a sensing circuit diagram when the coil component is a motor.

Referring to FIG. 5 , the coil 121-1 of the motor may be connected in series to the shunt resistor 201 .

In addition, the sensing circuit 200 shown in FIG. 3 may include a filtering circuit 210 and an amplifying circuit 220 as shown in FIG. 5 .

The filtering circuit 210 may low-pass filter the voltage across the shunt resistor 201 . For example, the filtering circuit 210 may be configured as an RC smoothing circuit including a plurality of resistors and a plurality of capacitors. Although the filtering circuit 210 is implemented by connecting two RC circuits in series in FIG. 5, only one RC smoothing circuit may be used in the implementation, and it is also possible to implement the filtering circuit using a smoothing circuit other than the RC circuit.

Meanwhile, since the smoothed voltage value may not match the analog to digital converter (ADC) level of the processor, the smoothed voltage value may be amplified by using an amplifying circuit 220 to be described later that amplifies at a preset ratio. On the other hand, when the smoothed voltage value is sufficient to be measured by the ADC of the processor, the amplification circuit 220 to be described later may be omitted.

The amplifying circuit 220 may amplify an output value of the filtering circuit 210 . For example, the amplification circuit 220 may include an OP-amp and a plurality of resistors.

The voltage value output through such a circuit is input to the ADC port of the processor, and the processor can monitor the load change in real time.

The processor monitors the temperature of the fixing unit in real time, and when the estimated temperature exceeds a certain level, that is, when it is determined that the fan needs to be driven, the processor may provide a control signal to the driving circuit.

Meanwhile, a counter electromotive force may be generated when the motor rotates. Because of this back electromotive force, it is difficult to estimate the temperature using the current value in the motor when the motor is operating. Accordingly, when the coil of the motor is used, the processor 150 may estimate the temperature only when the motor does not rotate, or may prevent the motor from rotating when temperature estimation is required.

On the other hand, the shunt resistor 201 , the filtering circuit 210 , and the amplification circuit 220 shown in FIG. 5 are not newly provided for temperature estimation, but a motor for overcurrent protection, constant current control, and load monitoring of an existing motor. It is a configuration provided for the purpose of control. Therefore, a separate cost increase for controlling the fan motor does not occur.

On the other hand, if the driving motor for the fuser unit is in a position where it is less affected by the air flow formed by the fan, other electric parts in the position affected by the air flow formed by the fan, for example, a clutch or a solenoid may be used. can An embodiment using the coil in the solenoid will be described below with reference to FIG. 6 .

6 is a diagram illustrating an example of a sensing circuit when the coil component is a solenoid.

Referring to FIG. 6 , the coil 121 - 2 of the solenoid may be connected in series to the shunt resistor 201 .

In addition, the sensing circuit 200 shown in FIG. 3 may include a filtering circuit 210 and an amplifying circuit 220 as shown in FIG. 6 . Since the detailed configuration of the sensing circuit 200 is the same as that of FIG. 5 , a redundant description thereof will be omitted.

The processor 150 may sense a current flowing through the coil 121 - 2 in an ON period in which the solenoid operates.

Since the operation control of the solenoid is performed by a processor or a print engine, the processor 150 may determine a sensing time based on control information on the solenoid, and estimate the temperature by measuring a coil current at the determined sensing time.

7 is a diagram illustrating an example of a sensing circuit when the coil component is a transformer.

Referring to FIG. 7 , the primary side coil 121-3 of the transformer may be connected in series to the shunt resistor 123-3.

Here, the shunt resistor 123-3 is configured to monitor the amount of current of the primary side coil, and in general, the SMPS may be provided with a shunt resistor for overcurrent protection.

In the present disclosure, such a shunt resistance is also used for temperature estimation. As described above, the present disclosure can perform temperature estimation around the SMPS or detection of whether a fan is operating, etc. without adding additional hardware configuration, in that the present disclosure utilizes an existing configuration.

In addition, the sensing circuit 200 shown in FIG. 3 may include a filtering circuit 210 , an amplifying circuit 220 , and an insulating circuit 240 as shown in FIG. 7 . Specific configurations of the filtering circuit 210 and the amplifying circuit 220 are the same as those of FIG. 5 , and thus a redundant description will be omitted.

The insulation circuit 240 is a circuit that transmits information while maintaining the insulation state between the circuit connected to the primary side of the transformer and the circuit connected to the secondary side of the transformer. For example, the insulating circuit 240 may include a photo coupler, a transformer, or the like. When implemented as a photo coupler, it may be composed of a light emitting unit that emits light corresponding to the voltage value of the shunt resistor 123 - 3 and a light receiving unit that receives the amount of light emitted from the light emitting unit.

On the other hand, although the illustrated example has been illustrated and described as measuring the current of the primary side coil of the transformer in order to utilize the shunt resistor provided in the SMPS circuit, it is also possible to measure the current of the secondary side coil in implementation.

8 is a diagram illustrating a change in a sensed current value when a fan is driven.

Referring to FIG. 8 , when the temperature around the electrical component increases, the fan may be driven at a specific temperature or higher. When the fan operates normally, the temperature around the electrical component estimated after the fan operation may drop as illustrated.

Conversely, when the fan does not operate, the estimated temperature has a different aspect from that during normal operation. Accordingly, the processor 150 may receive the temperature estimated in real time, and determine whether the fan has an error by comparing the received temperature information with information on whether the fan is operating.

9 is a flowchart for explaining an embodiment of an image forming method of the present disclosure.

Referring to FIG. 9 , the current flowing through the coil is sensed ( S910 ). Specifically, the current provided to the electrical component may be sensed by using a voltage value of the shunt resistor for sensing the magnitude of the constant current provided to the electrical component.

And the temperature around the coil is estimated based on the sensed current (S920). For example, a preset value may be calculated by integrating the amount of change in current flowing through the electrical component, and the temperature of the electrical component may be calculated using the calculated value.

Then, an operation of a fan generating air flow in the image forming apparatus is controlled based on the estimated temperature (S930). For example, if the estimated temperature is higher than a preset temperature, the fan may be rotated, and if the estimated temperature is lower than the preset temperature, the fan may be controlled not to rotate.

In addition, it is possible to determine whether the fan is abnormal using the operating state of the fan and the estimated temperature.

As described above, the image forming method according to FIG. 9 can detect the cabin temperature without an increase in material cost due to the addition of a separate temperature sensor, and control the fan using the detected cabin temperature. In particular, even if an expensive fan motor with a feedback function is not used, it is possible to check whether the fan is operating normally.

Meanwhile, the above-described image forming method may be implemented as a program and provided to the image forming apparatus. In particular, the program including the image forming method may be stored and provided in a non-transitory computer readable medium. Here, the non-transitory readable medium is a compact disc (CD), a digital video disc (DVD), a hard disk drive (HDD), a solid state drive (SSD) Blu-ray disc, a USB, a memory card, and a read- only memory), etc.

In the above, preferred embodiments of the present disclosure have been shown and described, but the present disclosure is not limited to the specific embodiments described above, and without departing from the gist of the present disclosure as claimed in the claims, in the technical field to which the disclosure belongs Any person skilled in the art can make various modifications, of course, and such modifications are within the scope of the claims.

100: image forming apparatus 110: print engine
120: electrical component 130: drive circuit
140: fan 150: processor
160: communication device 170: memory
180: display 190: input device

Claims (15)

In the image forming apparatus,
a print engine that forms an image;
a fan for generating an air flow in the image forming apparatus;
electrical components including coils;
a driving circuit that provides driving power to the fan and senses a current flowing through the coil; and
and a processor estimating a temperature around the coil based on a current flowing through the coil and controlling an operation of the fan based on the estimated temperature. According to claim 1,
The processor is
An image forming apparatus for determining whether the fan is abnormal based on a driving state of the fan and the estimated temperature. 3. The method of claim 2,
Display; further comprising,
The processor is
An image forming apparatus for controlling the display to display an error state when it is determined that the fan is abnormal. According to claim 1,
The processor is
An image forming apparatus for controlling the driving circuit to drive the fan when the estimated temperature is greater than or equal to a preset temperature, and controlling the driving circuit to stop driving of the fan when the estimated temperature is less than a preset temperature. According to claim 1,
The processor is
and controlling the driving circuit so that driving power corresponding to the estimated temperature is supplied to the fan. According to claim 1,
The electrical component is
An image forming apparatus that is at least one of a DC motor, a step motor, a solenoid, a clutch, or a transformer. According to claim 1,
and the electrical component is disposed on an air flow path generated by the fan. According to claim 1,
The electrical component is a plurality,
The processor is
An image forming apparatus for estimating a temperature based on a current flowing through each coil of the plurality of electrical components. 9. The method of claim 8,
one of the plurality of electrical components is a motor,
The processor is
An image forming apparatus for estimating a temperature based on a current flowing through a coil of the motor when the motor does not rotate, and estimating a temperature based on a current flowing through a coil of an electric component other than the motor when the motor rotates. According to claim 1,
The driving circuit is
a driving driver providing power to the fan;
a resistor connected in series with the coil;
a filtering circuit for low-pass filtering the voltage of the resistor;
and an amplifying circuit amplifying an output value of the filtering circuit and providing the amplified value to the processor. According to claim 1,
If the electric component is a motor,
The processor is
An image forming apparatus for estimating a temperature around the motor based on a current when the operation of the motor does not rotate. According to claim 1,
The electrical component is
clutch or solenoid,
The processor is
An image forming apparatus for estimating a temperature based on a current flowing through the clutch or the solenoid when the clutch or the solenoid is operated. According to claim 1,
The electrical component is a transformer,
The driving circuit is
An image forming apparatus for sensing the current flowing in the primary coil of the transformer. 14. The method of claim 13,
and an insulation circuit to insulate information corresponding to the amount of current flowing through the primary coil and provide the information to the driving circuit. In the image forming method,
sensing the current flowing in the coil;
estimating a temperature around the coil based on the sensed current; and
and controlling an operation of a fan for generating an air flow in the image forming apparatus based on the estimated temperature.

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