The present application claims priority under 35 U.S.C §119 to Japanese Patent Application No. 2010-205653 filed Sep. 14, 2010, the entire contents of which are hereby incorporated herein by reference.
1. Field of the Invention
The present invention generally relates to an induction heating device that heats a heated body (i.e., a heating target member) by induction heating, an induction heating fixing device including the induction heating device, and an image forming apparatus including the induction heating device.
2. Description of the Related Art
In an image forming apparatus such as a copier and a printing device employing an electrophotographic process, an image is formed by transferring a toner image onto a sheet and then heating the sheet by a fixing roller as a fixing means, the toner image having been formed on a photosensitive body.
Recently, it has become more and more important to address environmental concerns, and accordingly energy conservation in an image forming apparatus has been improving. To improve the energy conservation in the image forming apparatus, it may be necessary to reduce the energy consumption in the fixing device that melts and adheres toner to the sheet.
In response to the demand for reducing the energy consumption, recently, there has been employed an induction heating fixing device 108 as illustrated in
The induction heating fixing device 108 heats the heating roller 102 by generating eddy currents in a heat generation layer (electrical conducting layer) of the heating roller 102 by using magnetic flux generated by the exciting coil 101, and transfers the heat of the heating roller 102 to the fixing/pressing roller 103. In the meantime, by feeding a sheet 107 between the heating roller 102 and the fixing/pressing roller 103, the toner 106 mounted on the sheet 107 is melted and adhered to the sheet 107. In this case, the temperature of the heating roller 102 is detected by the temperature sensor 105 provided near the heating roller 102, so that the induction heating driver circuit 104 controls the temperature of the heating roller 102 at a predetermined (desired) temperature.
Recently, the induction heating fixing device 108 having the configuration described above has attracted attention because of having remarkably shorter time period necessary to increase the temperature to the operating temperature and also having higher efficiency so as to contribute to reducing environmental impacts.
As illustrated in
The full-wave rectified AC voltage is converted (smoothed) into a direct current (DC) by an LC filter circuit 203 including capacitors C4 and C5 and a choke coil L2 and is input to one end of a resonance capacitor Cres. The other end of the resonance capacitor Cres is connected to the collector of a switching device Q1 made of an IGBT (Insulated Gate Bipolar Transistor) or the like. In this case, the emitter of the switching device Q1 is connected to ground (GND).
The ends of the resonance capacitor Cres are connected to corresponding ends of the exciting coil 101 via two wires and an external connector CN1, so that the exciting coil 101 and the resonance capacitor Cres constitute an LC parallel resonance circuit.
A drive circuit 206 of a control circuit 204 outputs a drive signal to the base of the switching device Q1. By turning on and off the switching device Q1 by the drive signal from the control circuit 204, a high-frequency current flows to the exciting coil 101. As a result, the magnetic flux is applied to the heating roller 102 and the eddy currents are generated in the surface of the heating roller 102 to generate heat in the heating roller 102.
As illustrated in
The LC parallel resonance circuit including the exciting coil 101 and the resonance capacitor Cres, the switching device Q1, and a diode D1 of the switching device Q1 constitute a voltage resonance (type) inverter. The operations of the voltage resonance (type) inverter are described with reference to
As schematically illustrated in
As schematically illustrated in
As described above, in the voltage resonance (type) inverter, the switching device Q1 is turned on while the voltage Vce between the collector and the emitter of the switching device Q1 is zero (zero voltage switching). Further, in the voltage resonance (type) inverter, generally, the frequency control is performed so as to obtain a desired temperature and a desired power level by controlling a harmonic current by controlling the length of the turned-on time Ton while the turned-off time Toff is set to be constant.
However, the inductance of the exciting coil 101 is determined based on a combination of the exciting coil 101 and the heating roller 102. More specifically, the inductance of the exciting coil 101 may vary depending on the temperature conditions of the exciting coil 101 and the heating roller 102. Because of this feature, when the inductance value of the exciting coil 101 changes by the temperature increase of the exciting coil 101 and the heating roller 102 due to the induction heating, the resonance frequency of the LC parallel resonance circuit including the exciting coil 101 and the resonance capacitor Cres varies (fluctuates). In
Because of this feature, for example, as illustrated in
To overcome the problems, Japanese Patent No. 3902937 proposes a method to prevent an over-current when the switching device is turned on by calculating and setting an appropriate time period of the turned-on time and an appropriate time period of the turned-off time based on the detected value of the input voltage of the voltage resonance (type) inverter and the detected value of the temperature of the heat roller.
However, to respond to a recent strong demand for increasing the heating speed of the heating roller to reduce the heating time by the induction heating and improving the efficiency, the inductance may vary faster than ever. Therefore, when it is desired to control both the time period of the turned-on time and the time period of the turned-off time by performing a conventional calculation process and a conventional pulse width (length) setting process, the series of processes may not catch up (follow) the faster change of the inductance and be delayed. As a result, the energy loss in the switching device and the likelihood of damaging the switching device may be increased. Further, when such a fast calculation is desired to be performed, the cost of the control circuit may be increased.
The present invention is made to resolve at least one of the problems described above, and may provide a stable induction heating operation using the voltage resonance (type) inverter and fast power control while preventing the energy loss in the switching device and damage to the switching device even when the resonance frequency varies during the operation.
According to an aspect of the present invention, an induction heating device includes a resonance circuit including an exciting coil and a resonance capacitor, the exciting coil applying magnetic flux to a heated body, the resonance capacitor being connected to the exciting coil in parallel; a switching unit that turns on and off a high-frequency current flowing through the switching unit; a temperature detector that detects a temperature of the heated body; a power amount detector that detects a power amount at the exciting coil; a turned-on time setting unit that sets a turned-on time of the switching unit; a timing generation unit that generates a signal indicating a timing when a voltage between both ends of the switching unit is zero; and a timing setting unit that sets a turned-on timing of the switching unit based on the signal generated by the timing generation unit.
Other objects, features, and advantages of the present invention will become more apparent from the following description when read in conjunction with the accompanying drawings, in which:
In the following, embodiments of the present invention are described with reference to accompanying drawings.
First Embodiment
The induction heating device according to the first embodiment of the present invention differs from the induction heating device of the related art in
As illustrated in
Namely, in the resonance voltage detecting circuit 601, the resonance voltage of the LC parallel resonance circuit including the exciting coil 101 and the resonance capacitor Cres is divided by using the resistors R71 and R72, and the divided voltage is input to the inverting input terminal of the comparator CMP71.
As described above, the resonance frequency of the LC parallel resonance circuit including the exciting coil 101 and the resonance capacitor Cres varies (fluctuates) due to the temperature increase of the heating roller 102 and the exciting coil 101. To respond to the fluctuation of the resonance frequency, according to this embodiment of the present invention, attention is paid to the voltage Vce between both ends of the switching device Q1. Specifically, at the timing when Vce is zero (Vce=0), the comparator CMP71 is configured to output a turned-on timing control signal to the control section 207. To that end, the comparator CMP71 is configured to compare the divided voltage of the resonance voltage with ground (GND) level, and when determining that the divided voltage of the resonance voltage is equal to ground (GND) level, the comparator CMP71 is configured to output the turned-on timing control signal.
The pulse width of the pulse output from the drive circuit 206 under the control of the control section 207 is determined by using a digital control circuit such as a microcomputer and an FPGA (Field Programmable Gate Array) as the control section 207. Specifically, the pulse width (length) of the turned-on time Ton (hereinafter may be simplified as “On-width”) is controlled based on the calculation result of the input power detecting section 205 and the calculation result of the temperature sensor 105. On the other hand, the pulse width (length) of the turned-off time Toff (hereinafter may be simplified as “Off-width”) is controlled based on the turned-on timing control signal.
By doing in this way, it may become possible to promptly respond to the change (fluctuation) of the resonance frequency of the LC parallel resonance circuit including the exciting coil 101 and the resonance capacitor Cres. Further, as schematically illustrated in
As an example, in a case where a microcomputer is used as the control section 207, a PWM (Pulse Width Modulation) control unit may be used to output a signal (data) to the drive circuit 206, a timer unit may be used to control the On-width, a value of the comparison register may be updated based on the measurement value of the input power and the temperature, and an interruption process based on the turned-on timing control signal may be used to control the Off-width. Further, after the switching device Q1 is turned off, an interruption wait time in the resonance operation may occur. By measuring the input power and the temperature and updating the registers in the timer unit in the interruption wait time, the update may be performed (completed) within each pulse (cycle), and a faster response may be achieved.
As described above, according to this embodiment of the present invention, by changing the level of the drive voltage VG to a high level based on the turned-on timing control signal generated by detecting the timing when the voltage Vice between both ends of the switching device Q1 is zero volts, the switching device Q1 may be turned on while the voltage Vice between both ends of the switching device Q1 is zero volts. Therefore, it may become possible to promptly respond to the change of the resonance frequency of the LC parallel resonance circuit including the exciting coil 101 and the resonance capacitor Cres, and control the voltage resonance (type) inverter at desired power and temperature while preventing the increase of the energy loss in the switching device Q1 and the damage to the switching device Q1.
Second Embodiment
The induction heating device according to the second embodiment of the present invention differs from the induction heating device of the related art in
As illustrated in
In the resonance current detecting circuit 701A, the resonance current is measured by performing the current-voltage conversion. Namely, the voltage V(R72A) illustrated in
As described above, according to this embodiment of the present invention, by detecting the timing when the state where the high-frequency current IL flowing through the exciting coil 101 decreases in a sine waveform transitions to the state where the high-frequency current IL starts linearly increasing, it may become possible to indirectly or equivalently detect the timing when the voltage Vce between the collector and the emitter of the switching device Q1 becomes zero volts and generate the turned-on timing control signal at that timing. Further, by turning on the switching device Q1 while the voltage Vice between the collector and the emitter of the switching device Q1 is zero volts by changing the level of the drive voltage VG to a high level based on the turned-on timing control signal, it may become possible to promptly respond to the change of the resonance frequency of the LC parallel resonance circuit including the exciting coil 101 and the resonance capacitor Cres, and control the voltage resonance (type) inverter at desired power and temperature while preventing the increase of the energy loss in the switching device Q1 and the damage to the switching device Q1.
Third Embodiment
The induction heating device according to the third embodiment of the present invention differs from the induction heating device of the related art in
As illustrated in
In the drive current detecting circuit 701B, the voltage V(R71B) illustrated in
As described above, according to this embodiment of the present invention, by detecting the timing when the voltage V(R71B) (i.e., the current passing through the switching device Q1) suddenly (steeply) decreases (drops) from the zero level, it may become possible to indirectly or equivalently detect the timing when the voltage Vce between the collector and the emitter of the switching device Q1 becomes zero volts and generate the turned-on timing control signal at the timing. Further, by turning on the switching device Q1 while the voltage Vce between the collector and the emitter of the switching device Q1 is zero volts by changing the level of the drive voltage VG to a high level based on the turned-on timing control signal, it may become possible to promptly respond to the change of the resonance frequency of the LC parallel resonance circuit including the exciting coil 101 and the resonance capacitor Cres, and control the voltage resonance (type) inverter at desired power and temperature while preventing the increase of the energy loss in the switching device Q1 and the damage to the switching device Q1.
According to an embodiment of the present invention, an induction heating device includes a resonance circuit including an exciting coil and a resonance capacitor, the exciting coil applying magnetic flux to a heated body, the resonance capacitor being connected to the exciting coil in parallel; a switching unit that turns on and off a high-frequency current flowing through the switching unit; a temperature detector that detects a temperature of the heated body; a power amount detector that detects a power amount at the exciting coil; a turned-on time setting unit that sets a turned-on time of the switching unit; a timing generation unit that generates a signal indicating a timing when a voltage between both ends of the switching unit is zero; and a timing setting unit that sets a turned-on timing of the switching unit based on the signal generated by the timing generation unit.
According to another embodiment of the present invention, an induction heating fixing device includes the induction heating device described above; a heating roller that is the heated body of the induction heating device; and a fixing/pressing roller disposed opposite to the heating roller.
According to another embodiment of the present invention, an image forming apparatus includes the induction heating fixing device.
According to an embodiment of the present invention, the turned-on time of the switching unit is set so that the temperature of the heated body or the input power amount at the exciting coil is at a desired value, and the turned-on timing of the switching unit is set based on the signal indicating that the voltage between both ends of the switching unit is zero. Because of this feature, it may become possible to perform the zero voltage switching control of the switching unit without being influenced by the change (fluctuation) of the resonance frequency due to the impedance change of the exciting coil and the resonance capacitor caused by the temperature increase of the heated body.
According to embodiments of the present invention, it may become possible to stably operate the induction heating using the voltage resonance (type) inverter, prevent the increase of loss in the switching unit and the damage to the switching unit, and perform faster power control.
Although the invention has been described with respect to a specific embodiment for a complete and clear disclosure, the appended claims are not to be thus limited but are to be construed as embodying all modifications and alternative constructions that may occur to one skilled in the art that fairly fall within the basic teaching herein set forth.
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