JP2020198703A - Power circuit of image formation device, and image formation device - Google Patents

Abstract

To provide a technology for decreasing a possibility of breaking a field effect transistor in a power circuit of an image formation device.SOLUTION: The power circuit is provided with: a transformer having a first primary side coil L11, a second primary side coil L12, a third primary side coil L13 and at least one secondary side coil L2; a first field effect transistor FET1 which drives the first primary side coil L11; a power source IC20 which generates a pulse signal by receiving power supply from the second primary side coil L12; and a driving circuit 30 which generates driving voltage which is synchronized with a pulse signal by receiving power supply from the third primary side coil L13, and thus outputs the driving voltage to the first field effect transistor FET1.SELECTED DRAWING: Figure 1

Description

The present invention relates to a power supply circuit of an image forming apparatus and an image forming apparatus.

A switching power supply circuit is known as a circuit for obtaining DC power from commercial AC power. For example, Patent Document 1 discloses a gate drive circuit that uses a power supply IC that is driven by DC power and outputs a pulse signal. That is, in Patent Document 1, DC power obtained by rectifying commercial AC power is supplied to the transformer, and an electric field effect transistor connected to the primary winding of the transformer is output from the Vout terminal of the power supply IC. It is driven by a pulse signal. As a result, the converted voltage is induced in the secondary winding of the transformer.

DC power needs to be supplied to the power supply IC, and in Patent Document 1, a primary winding for supplying DC power to the power supply IC is provided in the transformer, and the output of the primary winding is rectified. The configuration in which the obtained power is supplied to the power supply IC from the Vcc terminal is disclosed.

Japanese Unexamined Patent Publication No. 2010-41834

In the above-mentioned conventional technique, the loss of the field effect transistor connected to the primary winding of the transformer becomes large and may be destroyed. That is, in recent years, there are power supply ICs that can be driven by a wide range of voltages. For example, while the normal supply voltage to the Vcc terminal to which the drive voltage is supplied is 20V, the supply voltage is up to about 6.5V. Some are configured so that the power supply IC can be driven even in a lowered state. The amplitude of the pulse signal output from the Vout terminal in this power supply IC is proportional to the voltage supplied to the Vcc terminal.

Therefore, when the voltage of the DC power supplied to the Vcc terminal decreases, the voltage of the pulse signal output from the Vout terminal and supplied to the field effect transistor also decreases. In a field-effect transistor, if the gate voltage supplied to the field-effect transistor is excessively small, the on-resistance between the drain and the source at the time of switch-on increases, resulting in a large loss. And if the loss is excessively large, the field effect transistor may be destroyed. Therefore, in order to supply the output from the Vout terminal of the power supply IC to the field effect transistor and drive the primary winding of the transformer without destroying the field effect transistor, the DC power supplied to the Vcc terminal is sufficient. It needs to be big.

However, in the configuration in which the primary winding of the transformer is used to generate the DC power supplied to the Vcc, the magnitude of the DC power supplied to the Vcc terminal depends on the operation of the transformer. Therefore, the voltage of the DC power supplied to the Vcc terminal may fluctuate depending on the state of the load connected to the secondary winding. Then, when the fluctuation of the voltage becomes large and falls below the expected DC power voltage (for example, when the supply voltage to the Vcc terminal becomes about 6.5V), the voltage from the Vout terminal is increased according to the voltage. The output voltage also decreases. As a result, the gate voltage supplied to the field-effect transistor becomes small, and the loss in the field-effect transistor becomes large, which may cause destruction.
An object of the present invention is to reduce the possibility that a field effect transistor will be destroyed.

The power supply circuit of the image forming apparatus for achieving the above object includes a first primary side winding, a second primary side winding, a third primary side winding, and at least one secondary side winding. A transformer having a wire, a first electric field effect transistor for driving the first primary winding, a power supply IC for generating a pulse signal by receiving power from the second primary winding, and a third. It includes a drive circuit that receives power from the primary winding, generates a drive voltage synchronized with the pulse signal, and outputs the drive voltage to the first electric field effect transistor.

That is, in the power supply circuit, in addition to the first primary winding driven by the first electric field effect transistor and the second primary winding generating the power supplied to the power supply IC, the first A third primary winding is provided to generate the drive voltage provided to the field effect transistor of 1. According to this configuration, the power for driving the first field effect transistor is generated by the second primary winding that generates the power supplied to the Vcc terminal and another third primary winding. Can be done.

Since the specifications of the windings of the second primary winding are determined to supply power to the power supply IC, if the number of windings is increased in preparation for a voltage drop, the voltage will become excessive if the voltage does not drop. Problems such as becoming large occur. Therefore, it is difficult to freely determine the specifications of the second primary winding in response to a request to sufficiently increase the amplitude of the pulse signal supplied to the first field effect transistor.

Therefore, if a third primary winding is provided separately from the second primary winding, a third winding is provided for the purpose of sufficiently increasing the amplitude of the pulse signal supplied to the first field effect transistor. It is possible to determine the specifications of the primary winding, and it is also easy to determine the specifications of the third primary winding so that a voltage is supplied to prevent the destruction of the first field effect transistor. is there. As a result, it is possible to reduce the possibility that the (first) field effect transistor will be destroyed.

Further, the drive circuit includes, at least, a conversion circuit that converts the voltage of the third primary winding into a DC voltage by a rectifying diode and a smoothing capacitor, and a first electric field effect that converts the DC voltage into a drive voltage. A second electric field effect transistor for driving the transistor and a drive transistor for driving the second electric field effect transistor may be included, and a pulse signal may be input to the drive transistor. According to this configuration, it is possible to drive the first primary winding with a simple configuration by using the voltage generated from the third primary winding.

Further, the drive voltage for driving the first field effect transistor may be higher than the voltage supplied to the power supply IC by the second primary winding. According to this configuration, even if the voltage supplied to the power supply IC is lowered by the second primary winding, a drive voltage higher than the voltage can be supplied to the first field effect transistor. The possibility that the field effect transistor of 1 is destroyed can be reduced.

Further, an image forming apparatus including a power supply circuit of the image forming apparatus may be configured. According to this configuration, it is possible to reduce the possibility that the first field effect transistor included in the power supply circuit for driving the image forming apparatus is destroyed.

It is a circuit diagram which shows the power supply circuit of the image forming apparatus which concerns on embodiment of this invention. It is a figure which shows the example of the voltage supplied to the Vcc terminal of a power supply IC. It is a figure which shows the example of the voltage output from the Vout terminal. It is a figure which shows the example of the voltage supplied to the Vcc terminal of a power supply IC. It is a figure which shows the example of the voltage output from the Vout terminal. It is a figure which shows the gate voltage applied to the gate of the 1st field effect transistor.

Here, embodiments of the present invention will be described in the following order.
(1) Configuration of power supply circuit of image forming apparatus:
(1-1) Drive circuit configuration:
(2) Operation example:
(3) Other embodiments:

(1) Configuration of power supply circuit of image forming apparatus:
FIG. 1 is a circuit diagram showing a power supply circuit of an image forming apparatus according to an embodiment of the present invention. The power supply circuit in this embodiment is incorporated in an image forming apparatus such as a printing apparatus. That is, the image forming apparatus includes various parts such as a print head and a drum unit that are driven by being supplied with electric power. The power supply circuit according to this embodiment is a circuit for supplying electric power to at least one of these components.

In the present embodiment, the image forming apparatus includes a power cable Ps (not shown), and receives commercial AC power via the power cable Ps. The parts in the image forming apparatus are driven by DC power. Therefore, in the present embodiment, the commercial AC power is converted into a DC voltage by the power supply circuit. The power supply circuit is equipped with a transformer, performs voltage conversion based on the power supplied to the primary side, and is used on the secondary side. FIG. 1 is a diagram showing mainly the primary side of the power supply circuit.

The commercial AC power acquired by the power cable Ps is supplied to the rectifier circuit 10. The rectifier circuit 10 rectifies the commercial AC power and supplies it to the first primary winding L ₁₁ in a state where it is substantially DC. Rectification may be performed by various circuits, for example, by a rectifying diode and a smoothing capacitor, or by a circuit having other functions (for example, a transformer for voltage conversion, an element for noise removal, etc.). ) May be included.

In the first primary winding L _11, a first field effect transistor FET1 is an NMOS is connected to the terminals of the rectifier circuit 10 and the opposite side. That is, the first primary winding L ₁₁ is connected to the drain D of the first field effect transistor FET 1, and the source S is grounded. The anode of the diode D ₁ and the resistance element R _{32 included} in the drive circuit 30, which will be described later, are connected to the gate of the first field effect transistor FET ₁ .

In the present embodiment, the second primary winding L ₁₂ and the third primary winding L ₁₃ are wound around a core common to the first primary winding L ₁₁ . The anode of the rectifier diode D ₂ is connected to one terminal of the second primary winding L ₁₂ , and the smoothing capacitor C ₂ is connected to the other terminal. The cathode of the rectifying diode D ₂ is connected to the terminal on the opposite side of the smoothing capacitor C ₂ . In the present embodiment, the AC power output from the second primary winding L ₁₂ is rectified by the rectifying diode D ₂ and the smoothing capacitor C ₂ .

That is, rectified DC power is output from the contact between the cathode of the rectifier diode D ₂ and the smoothing capacitor C ₂ . The contact is connected to the Vcc terminal of the power supply IC 20. That is, the power supply IC 20 is an IC driven by DC power, and the second primary winding L ₁₂ acquires power through a transformer, and the power is converted to DC and supplied to the power supply IC 20. In the present embodiment, when the load connected to the secondary side of the transformer is in a normal state, the second primary side winding is set so that the DC voltage supplied to the Vcc terminal becomes a predetermined voltage. The number of turns N _{12 of} L ₁₂ is fixed. In this embodiment, specifically, when the load connected to the secondary side is in a normal state, the number of turns N ₁₂ is determined so that the DC voltage supplied to the Vcc terminal is about 20 V. Has been done.

The power supply IC 20 may have various functions, but in the present embodiment, it has a function of generating a pulse signal. That is, the power supply IC 20 generates a rectangular pulse signal having a predetermined frequency based on the DC voltage supplied to the Vcc terminal, and outputs the rectangular pulse signal from the Vout terminal. In the present embodiment, the amplitude of the pulse signal output from the Vout terminal is the same as the voltage value of the DC voltage supplied to the Vcc terminal.

In the present embodiment, the voltage supplied to the Vcc terminal of the power supply IC 20 is assumed to be about 20 V, but the range of voltage values capable of driving the power supply IC 20 is wide, for example, 6. The power supply IC 20 operates even if the voltage drops to about 5V. In this case, the amplitude of the pulse signal is also about 6.5V.

In the present embodiment, the resistance element R ₁ is connected to the Vout terminal of the power supply IC 20, and the diode D ₁ is connected to the terminal on the opposite side of the resistance element R ₁ . In the present embodiment, the pulse signal output from the Vout terminal is used to switch the first field effect transistor FET1. That is, the first field effect transistor FET1 is turned on when the voltage value of the pulse signal output from the Vout terminal is high level, and turned off when the voltage value is low level.

In the present embodiment, as described above, it is assumed that the first field effect transistor FET1 is switched by using the pulse signal output from the Vout terminal of the power supply IC 20. However, the pulse signal itself output from the Vout terminal of the power supply IC 20 is applied to the gate of the first field effect transistor FET1, and the pulse signal output from the Vout terminal via various elements such as a resistance element is the first. In the configuration applied to the gate of the field effect transistor FET 1 of 1, the voltage may be insufficient.

That is, in the field effect transistor, if the gate voltage VGS (gate-source voltage) is excessively small, the on-resistance between the drain and the source at the time of switch-on increases, and the loss increases. And if the loss is excessively large, the field effect transistor may be destroyed. Therefore, the output from the Vout terminal of the power supply IC 20 is supplied to the gate G of the first field effect transistor FET1 to drive the first primary winding L ₁₁ in a state where the first field effect transistor FET 1 is not destroyed. For that purpose, it is necessary that the DC voltage supplied to the Vcc terminal is sufficiently large.

The magnitude of the DC voltage supplied to the Vcc terminal is determined by the number of turns N ₁₂ of the second primary winding L ₁₂ , and under normal conditions, the planned 20 V is supplied to the Vcc terminal. .. However, when the operation is started in a state where the load is unstable, such as when the switch of the image forming apparatus is turned off and turned on, the magnitude of the DC voltage supplied to the Vcc terminal is about 6.5V. It may become excessively small. In this case, since the power supply IC 20 is operable, a pulse signal is output from the Vcc terminal. However, the amplitude of the pulse signal is small, and when this pulse signal is supplied to the gate G of the first field effect transistor FET1, the drain-source at the time of switch-on is due to the excessively small voltage value. The on-resistance between them increases, and the loss increases.

(1-1) Drive circuit configuration:
Therefore, in the present embodiment, even if the DC voltage generated by the second primary winding L ₁₂ or the like and supplied to the Vcc terminal decreases, the gate voltage VGS of the first field effect transistor FET 1 is excessively increased. A drive circuit 30 is provided so as not to lower the voltage. In the present embodiment, the drive circuit 30 includes a third primary winding L ₁₃ and receives power from the third primary winding L ₁₃ to synchronize with a pulse signal output from the Vout terminal. Generate a voltage. The drive circuit 30 outputs the drive voltage to the gate G of the first field effect transistor FET1.

Specifically, the drive circuit 30 includes a conversion circuit 31 that converts the voltage of the third primary winding L ₁₃ into a DC voltage by means of a rectifier diode D ₃ and a smoothing capacitor C ₃ . That is, in the conversion circuit 31, the anode of the rectifier diode D ₃ is connected to one terminal of the third primary winding L ₁₃ , and the smoothing capacitor C ₃ is connected to the other terminal. The cathode of the rectifier diode D ₃ is connected to the terminal on the opposite side of the smoothing capacitor C ₃ . In the present embodiment, the AC power output from the third primary winding L ₁₃ is rectified by the rectifying diode D ₃ and the smoothing capacitor C ₃ . That is, the conversion circuit 31 outputs the power converted into the DC voltage from the contact between the cathode of the rectifier diode D ₃ and the smoothing capacitor C ₃ .

Further, the drive circuit 30 includes a second field-effect transistor FET2 that converts the DC voltage into a drive voltage of the first field-effect transistor FET1 and drives the first field-effect transistor FET1. That is, the contact point between the cathode of the rectifier diode D ₃ and the smoothing capacitor C ₃ in the conversion circuit 31 is connected to the source S of the second field effect transistor FET 2 which is a MOSFET. The drain of the second field-effect transistor FET 2 is connected to the gate G of the first field-effect transistor FET 1 via the resistance element R ₃₂ .

A drive transistor Tr1 is connected to the gate G of the second field-effect transistor FET2 via a resistance element R ₃₃ , and the second field-effect transistor FET2 is driven by the drive transistor Tr1. That is, the collector C of the drive transistor Tr1 is connected to one terminal of the resistance element R ₃₃ connected to the gate G of the second field effect transistor FET2, and the emitter E is grounded.

On the other hand, the Vout terminal of the power supply IC 20 is connected to the base B of the drive transistor Tr1 via the resistance element R ₃₁ . The drive transistor Tr1 and the resistance element R ₃₁ in the present embodiment switch the drive transistor Tr1 even if the voltage value of the pulse signal output from the Vout terminal drops to a small value such as 6.5 V. The specifications have been selected so that it can be implemented.

That is, in the present embodiment, when a pulse signal is output from the Vout terminal, the drive transistor Tr1 is repeatedly turned on and off, and the second field effect transistor FET2 is switched by the gate voltage VGS applied at the on / off. .. In response to the switching operation of the second field-effect transistor FET2, a pulsed voltage having a voltage value output from the conversion circuit 31 as an amplitude is used as a driving voltage with respect to the gate G of the first field-effect transistor FET1. It is applied.

Then, in the present embodiment, the drive voltage is higher than the voltage supplied to the power supply IC by the second primary winding L ₁₂ . That is, the third primary winding L ₁₃ includes a second primary winding L ₁₂ is wound on a common core, the number of turns N ₁₃ of the third primary winding L ₁₃ is the second The number of turns of the primary winding L ₁₂ is larger than that of N ₁₂ . Therefore, the DC voltage value (output voltage value of the conversion circuit 31) obtained from the number of turns N _{13 of} the third primary winding L ₁₃ is larger than the DC voltage value obtained from the second primary winding L _12. ..

Here, the DC voltage generated by the second primary winding L ₁₂ is applied to the Vcc terminal of the power supply IC 20, and the amplitude of the pulse signal output from the Vout terminal is the voltage value applied to the Vcc terminal. equal. Therefore, the amplitude of the drive voltage applied to the gate G of the first field effect transistor FET1 is larger than the amplitude of the pulse signal output from the Vout terminal.

Therefore, even if the DC voltage value generated by the second primary winding L ₁₂ decreases and at the same time the DC voltage value generated by the third primary winding L ₁₃ decreases, the voltage value Since the latter is larger, the drive voltage applied to the first field effect transistor FET1 is not excessively small. Therefore, the drive voltage for driving the first field-effect transistor FET1 is not excessively small, the on-resistance between the drain and the source at the time of switch-on is not excessively large, and the first field-effect transistor FET1 is The possibility of being destroyed can be reduced.

(2) Operation example:
2 to 6 are diagrams for explaining the time change of the voltage generated in the power supply circuit. 2 and 4 are diagrams showing an example of the voltage supplied to the Vcc terminal of the power supply IC 20. 3 and 5 are diagrams showing an example of the voltage output from the Vout terminal. FIG. 6 is a diagram showing a gate voltage VGS applied to the gate G of the first field effect transistor FET1.

When the image forming apparatus is on and the load is stable, the DC voltage obtained by being rectified from the voltage output from the second primary winding L ₁₂ is, for example, as shown in FIG. It changes at an almost constant voltage. The voltage value of this DC voltage is in a predetermined range, for example, 20 V.

In this case, a pulse signal having the same amplitude as the DC voltage value applied to the Vcc terminal is output from the Vout terminal of the power supply IC 20. Therefore, if the DC voltage value applied to the Vcc terminal is 20V, the amplitude of the pulse signal is 20V. FIG. 3 is a diagram showing a pulse signal in this state.

On the other hand, if the power of the image forming apparatus is turned off from the on state and then turned on immediately, the load state of the image forming apparatus is unstable, and the second primary winding is made for various reasons. The voltage output from L ₁₂ drops. In this case, the DC voltage value obtained by rectifying from the voltage output from the second primary winding L ₁₂ also decreases. FIG. 4 is a diagram illustrating a voltage value in a lowered state. In this example, the voltage value of the DC voltage is 6.5V.

The power supply IC 20 according to this embodiment can be driven even if the voltage value is 6.5V. Therefore, a pulse signal having the same amplitude as the DC voltage value applied to the Vcc terminal is output from the Vout terminal of the power supply IC 20. Therefore, if the DC voltage value applied to the Vcc terminal is 6.5V, the amplitude of the pulse signal is also 6.5V. FIG. 5 is a diagram showing a pulse signal in this state.

When the reduced pulse signal is applied to the first field-effect transistor FET1 in this way, the gate voltage supplied to the first field-effect transistor FET 1 becomes excessively small, and the on-resistance between the drain and the source becomes excessive. Becomes larger. As a result, the first field effect transistor FET1 may be destroyed. However, in the present embodiment, the drive circuit 30 is provided, and the amplitude of the drive circuit output from the drive circuit 30 is larger than the amplitude of the pulse signal output from the Vout terminal.

That is, in this embodiment, the DC voltage output from the conversion circuit 31 is adjusted to be larger than the DC voltage applied to the Vcc terminal. Therefore, the drive voltage obtained by switching the output of the conversion circuit 31 by the drive transistor Tr1 and the second field effect transistor FET2 is not excessively small, but is sufficiently large. FIG. 6 is an example showing a voltage applied to the first field effect transistor FET1 as a drive voltage, and in this example, the amplitude is about 20 V. Of course, the magnitude of the voltage is an example, and any magnitude may be sufficient as long as the first field effect transistor FET1 is not destroyed.

As described above, in the present embodiment, even if the DC voltage output from the second primary winding L ₁₂ is reduced, the drive voltage applied to the gate of the first field effect transistor FET 1 is excessively reduced. There is nothing to do. Therefore, the possibility that the first field effect transistor FET1 is destroyed can be reduced.

(3) Other embodiments:
The above embodiment is an example for carrying out the present invention, and various other embodiments can be adopted. For example, the image forming apparatus is not limited to the printing apparatus, and may be a projector or the like. Further, the values such as the voltage value shown in the above-described embodiment are examples, and are not limited to these examples. Further, the circuit shown in FIG. 1 is an example, and various other elements may be added, or some circuits may be omitted.

The transformer has a primary side winding and a secondary side winding, and it is sufficient that the voltage can be converted between the primary side and the secondary side by applying AC power to each winding. At least three windings are provided on the primary side. At least one winding may be present on the secondary side, and the converted electric power may be used to drive the load. When the power supply circuit drives the image forming apparatus, at least one of the loads is a component of the image forming apparatus. Of course, if there are a plurality of loads driven by the secondary windings and the required voltage is different for each load, the number of secondary windings may be plural.

The electric power before conversion of the electric power used in the secondary electric power may be applied to the first primary winding. Therefore, as in the above-described embodiment, the DC power obtained by rectifying the commercial AC power may be supplied to the first primary winding, or the DC obtained from various power sources may be supplied. The configuration may be such that power is supplied to the first primary winding.

The first field effect transistor only needs to be able to drive the first primary winding. That is, the first primary winding is a winding to which the voltage before being converted by the transformer is applied, and needs to be an AC voltage for conversion. Therefore, it is sufficient that the first field effect transistor functions as a switching element so that AC power is applied to the first primary winding. Driving means that the AC power is applied.

The first field effect transistor may be an element that controls the current between the drain and the source by the voltage applied to the gate. However, since the drive voltage of the first field-effect transistor is not excessively lowered by the third primary winding, the gate threshold voltage of the first field-effect transistor FET1 is not a small value. Good. That is, a field-effect transistor having a small gate threshold voltage is expensive, but if the drive voltage of the first field-effect transistor is not excessively lowered by the third primary winding, the gate threshold voltage will be high. A relatively large field effect transistor can be used. Therefore, it is not necessary to use an expensive field effect transistor, and the cost can be suppressed.

The power supply IC may be able to generate a pulse signal by receiving power supply from the second primary winding. For example, the power supply IC can be configured by an IC that generates a pulse signal having the value of the DC voltage as an amplitude based on the DC voltage supplied from the second primary winding. Of course, the power supply IC may have a function other than the function of generating the pulse signal, and the amplitude of the generated pulse signal may be different from the value of the DC voltage supplied to the power supply IC. .. Further, the shape, frequency, and the like of the pulse signal may be in various forms and may be variable.

The drive circuit may receive power from the third primary winding, generate a drive voltage synchronized with the pulse signal, and output it to the first field effect transistor. That is, the drive circuit only needs to be able to generate a drive voltage synchronized with the pulse signal output from the power supply IC. For this purpose, for example, a configuration in which a pulse signal output from the power supply IC is input to the drive circuit and a drive voltage is generated by an amplifier circuit switched by the pulse signal can be adopted.

The second primary winding and the third primary winding may be different windings. That is, the second primary winding for generating the DC voltage for driving the power supply IC and the third primary winding for generating the signal for driving the first field effect transistor are different windings. It can be a line. Therefore, as in the above-described embodiment, the second primary winding and the third primary winding may share the core of one transformer, or the second primary winding may be shared. Power may be obtained from the core of a transformer in which the wire and the third primary winding are different.

The drive voltage may be output to the first field effect transistor, and as a result, the first primary winding may be driven. That is, the first field effect transistor operated by the drive voltage may switch the first primary winding, and as a result, the voltage required by the load may be induced in the secondary winding.

Various configurations can be adopted as the configuration for the drive voltage to be higher than the voltage supplied to the power supply IC by the second primary winding. That is, if the configuration is such that the second primary winding and the third primary winding are wound around a common core as in the above embodiment, the third primary is more than the second primary winding. The side winding may be configured so that the number of turns is larger. Further, the second primary winding and the third primary winding may be configured to generate electric power from different power sources or different transformers.

Further, as described above, the method of driving the first field effect transistor by the primary side winding different from the primary side winding that generates the voltage supplied to the Vcc terminal is also feasible as a method.

1 ... 1st field effect transistor FET, 2 ... 2nd field effect transistor FET, 10 ... rectifier circuit, 20 ... power supply IC, 30 ... drive circuit, 31 ... conversion circuit, C ₂ , C ₃ ... smoothing capacitor, D ₁ ... Diode, D ₂ , D ₃ ... Rectifier diode, L ₁₁ ... 1st primary winding, L ₁₂ ... 2nd primary winding, L ₁₃ ... 3rd primary winding, Ps ... Power cable , R ₁ , R ₃₁ , R ₃₂ , R ₃₃ ... Resistance element, Tr 1 ... Drive diode

Claims (4)

A transformer having a first primary winding, a second primary winding, a third primary winding, and at least one secondary winding.
The first field effect transistor that drives the first primary winding, and
A power supply IC that receives power from the second primary winding and generates a pulse signal.
A drive circuit that receives power from the third primary winding, generates a drive voltage synchronized with the pulse signal, and outputs the drive voltage to the first field effect transistor.
A power supply circuit for an image forming apparatus. The drive circuit is at least
A conversion circuit that converts the voltage of the third primary winding into a DC voltage by using a rectifier diode and a smoothing capacitor.
A second field-effect transistor that converts the DC voltage into the drive voltage and drives the first field-effect transistor,
A drive transistor for driving the second field effect transistor and a drive transistor are included.
The pulse signal is input to the drive transistor.
The power supply circuit of the image forming apparatus according to claim 1. The drive voltage is higher than the voltage supplied to the power supply IC by the second primary winding.
The power supply circuit of the image forming apparatus according to claim 1 or 2. An image forming apparatus comprising the power supply circuit according to any one of claims 1 to 3.

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