FR2990578A1 - Switching power supply circuit for supplying direct current voltage to humidity sensor of clothes washing or drying machine, has transformer controlled by control signals generated intermittently by control unit for period of time - Google Patents

Abstract

The circuit (10) has a transformer (11) controlled by control signals (PWM1, PWM2) generated by a control unit (12), where the control signals are generated intermittently. The control signals are generated for a first period of time, where the period of time is predetermined so that output voltage (Vout) of the circuit has a constant value. The control signals are not generated for a second period of time. Switching units e.g. transistors (T1, T2) such as MOSFETS, control injection of energy into the transformer. The switching units are controlled by the control signals. An independent claim is also included for an electrical household appliance.

Description

The present invention relates to a switching power supply circuit. It is particularly aimed at a switching power supply circuit of a household appliance. A supply circuit provides one or more DC voltages from the mains or mains voltage. These DC voltages feed the various modules of the appliance. This appliance is for example a dryer or a washing machine and dryer, and the module is for example a humidity sensor. In general, the supply of a humidity sensor in a dryer is carried out by a linear supply. This power supply essentially comprises a 50 / 60Hz transformer providing galvanic isolation, a rectifier and filters. This type of linear supply transformer does not have an optimum efficiency, which generates overheating. In addition, this type of power takes an important place on an electronic card. One solution is to use a switching power supply comprising a transformer (for example a high frequency transformer) capable of ensuring galvanic isolation. Nevertheless, the electromagnetic disturbances of such a power supply are high compared to the values which must be respected in order to comply with the standards dictated by standardization bodies. The object of the present invention is to solve the abovementioned disadvantages and to propose an efficient supply circuit which at the same time makes it possible to limit the electromagnetic disturbances.

For this purpose, the present invention aims according to a first aspect, a switching power supply circuit comprising a transformer and control means. According to the invention, the transformer is controlled by at least two control signals generated by the control means, the control signals being generated intermittently. Thus, the control signals are generated for a limited time thus avoiding electromagnetic disturbances for periods of time not necessary for the control of the transformer. The electromagnetic disturbances thus remain below the values predetermined by the standards. In addition, the size of a switching power supply is reduced and the efficiency is improved. In practice, said at least two control signals are generated during a first period of time, the first period of time being predetermined so that an output signal of the switching power supply circuit has a substantially constant value. Thus, the control signals are generated for a time that has been predetermined so that the output voltage of the power supply remains at the desired values. According to one characteristic, said at least two control signals are not generated during a second period of time, the first period of time being a fraction of the second period of time. According to one characteristic, the switching power supply circuit 25 further comprises switching means adapted to control the injection of energy into the transformer, the switching means being controlled by said at least two control signals. According to another characteristic, the switching power supply circuit further comprises rectifying means adapted to rectify the output voltage of the transformer, the rectifying means being adapted to multiply the value of the output voltage of the transformer.

Thanks to these characteristics, it is possible to multiply the value of the output voltage of the supply circuit without the need to change the transformer or to adapt its topology. The present invention aims according to a second aspect, an appliance having a supply circuit according to the invention. In practice, the switching power supply circuit supplies a module, said at least two control signals being in an inactive state when said module is not in operation. Thus, the electrical consumption of the appliance is reduced and conforms to the standards that impose ever lower power consumption, both when the appliance is in standby and when the appliance is in operation. Other features and advantages of the invention will become apparent in the description below. In the accompanying drawings, given as non-limiting examples: FIG. 1 represents the context in which the invention is located; and FIG. 2 represents an embodiment of a switching power supply circuit according to the invention. The context in which the invention is situated will first be described with reference to FIG. As indicated above, in a household appliance a general supply circuit 1 provides one or more direct voltages Vc from the mains or mains voltage 2, for example a voltage of 230 VRMS for the voltage. French electricity network. Of course, the voltage of the sector 2 may have different values, depending on the power grid of the country in which one is located. In the embodiment described, one of the DC voltages Vci generated by the general power supply circuit 1 supplies the switching power supply circuit 10 according to the invention. In this example, this DC voltage Vci has a value of 12 V. However, this DC voltage can have different values here. The switching power supply circuit 10 generates a voltage output Mosul 'adapted to supply at least one module 30 of the appliance. In this example, the appliance is a clothes dryer and the module 30 has a moisture sensor capable of measuring moisture in the drum of this apparatus. Nevertheless, the appliance may be for example a washing and drying apparatus, a dishwasher, a cooking oven, a hob or a refrigerator, and the module 30 may include any other sensor or electronic circuit . 2, an embodiment of a switching power supply circuit 10 according to the invention will be described next with reference to FIG.

As described above, the switching power supply circuit 10 here generates a voltage output VouT adapted to supply the module 30. The switching power supply circuit 10 comprises a transformer 11 adapted to transform a voltage input V1 into a output voltage V2 and to provide a galvanic isolation function. This transformer 11 is for example a high frequency transformer. The operation of the transformer 11 is controlled by at least two control signals PWM1, PWM2. In this example, the primary winding of the transformer 11 is a primary winding midpoint and has two parts 11a, 11b. A first portion of the primary winding 11a is controlled by a first control signal PWM1 and a second portion of the primary winding 11b is controlled by a second control signal PWM2. In particular, the first control signal PWM1 controls the operation of a first switching means Ti and the second control signal PWM2 controls the operation of a second switching means T2. The first T1 and second T2 switching means are adapted to respectively control the injection of energy into the first 11a and second llb parts of the primary winding of the transformer 11. The operation of the switching means T1, T2 and the transformer will be described later in the description. In other embodiments, the transformer 11 may comprise a number of different primary windings, the number of switching means and control signals may be as different. Thus, according to an alternative embodiment, the transformer 11 comprises a single primary winding which is controlled by a single control signal through a single switching means. According to another variant, the transformer 11 comprises two primary windings, a first primary winding which is controlled by the first PWM1 control signal and a second primary winding which is controlled by the second PWM2 control signal. The control signals PWM1, PWM2 are generated by control means 12. The control means 12 comprise in particular a microcontroller for managing the operation of the switching power supply circuit 10. In one exemplary embodiment, the control means 12 are adapted to manage in addition to the operation of the switching power supply circuit 10, the general power supply circuit 1 and / or other features of the appliance.

The switching power supply circuit 10 further comprises rectifying means 13 adapted to rectify the output voltage V2 of the transformer 11. Here, the rectifying means 13 are further adapted to multiply the value of the output voltage VOUT of the transformer. supply circuit. In this exemplary embodiment, the rectifying means 13 comprise a voltage doubler. Here, the supply voltage Vci is 12 V and the output voltage \ kin 'of the switching power supply circuit 10 is 24V. Of course, the values of the supply voltage Vci and the output voltage may be different. In addition, the value of the supply voltage Vci can be multiplied by a different factor. For example, in one embodiment, the multiplication factor may be the unit, i.e. the value of the input and output voltage of the rectifying means 13 is equivalent. In the embodiment described, the control means T1, T2 comprise a metal oxide gate effect field effect transistor (MOSFET), which is the acronym for Metal Oxide Semiconductor Filed Effect Transistor. Here, the control means T1, T2 may in particular be in two states, either in the on state, or in the off state. Thus, they implement a switch function. Of course, the control means T1, T2 may comprise other components instead of the MOSFET transistors. The gate T1G of the first switching means Ti is connected to the first control signal PWM1 coming from the control means 12, the drain T1D of the first switching means T1 is connected to the first part 1a1 of the primary winding of the transformer 11 , and the source T1S of the first switching means T1 is connected to the reference potential 14 (here 0 volts). A first terminal Ria of a first resistor R1 is connected to the gate T1G of the first switching means T1, and a second terminal R1b of the first resistor R1 is connected to the source T1S of the first switching means T1, as well as 14. The gate T2G of the second switching means T2 is connected to the second control signal PWM2 coming from the control means 12, the drain T2D of the second switching means T2 is connected to the second part 11b of the primary winding of the transformer 11, and the source T2S of the second switching means T2 is connected to the reference potential 14.

A first terminal R2a of a second resistor R2 is connected to the gate T2G of the second switching means T2, and a second terminal R2b of the second resistor R2 is connected to the source T2S of the second switching means T2, as well as to the second terminal R2b. reference potential 14.

A first capacitor C1 is connected by a first terminal Cl a to the midpoint of the primary winding 11a, 11b of the transformer 11 (intermediate point between the first part 1a and the second part 1 1b of the primary winding of the transformer 11), and by a second terminal Cl b to the reference potential 14.

The midpoint of the primary winding 11a, 11b of the transformer 11 is connected to the supply voltage Vci from the general power supply 1. Thus, the input voltage to the transformer V1 is composed of a first voltage V1 applied. to the first portion 11a of the winding and a second voltage V12 applied to the second portion 11b of the winding.

The rectifying means 13 are connected at the output of the secondary winding 11c of the transformer 11, and comprise a first D1 and second D2 diodes, and a second C2 and third C3 capacitors. The anode D1 of the first diode D1 is connected to a first output terminal V2a of the transformer 11, and to the cathode D2b of the second diode D2, the cathode D1b of the first diode D1 is connected to an first terminal C2a of the second capacitor C2. The second terminal C2b of the second capacitor C2 is connected to a first terminal C3a of the third capacitor C3 and to a second terminal V2b of the secondary winding 11c of the transformer 11. A second terminal C3b of the third capacitor C3 is connected to the anode D2a of the second diode D2. The switching power supply circuit 10 further comprises a fourth capacitor C4 connected by a first terminal C4a, to the first terminal C2a of the second capacitor C2 and by a second terminal C4b to the second terminal C3b of the third capacitor C3. The output voltage of the switching power supply circuit 10 is taken between the first C4a and the second C4b terminals of this fourth capacitor C4. This output voltage VouT is able to supply the module 30. Here, this fourth capacitor C4 is an electrolytic capacitor, and is able to maintain the output voltage Vour at a substantially constant value. The operation of the switching power supply circuit shown in FIG. 2 will next be described. When the module 30 is in operation, the first and second control signals PWM1, PWM2 are generated by the control means 12. Thus, by For example, these control signals PWM1, PWM2 are generated when the humidity sensor is to take a moisture measurement of the laundry in the drum of the dryer. In another example, the PWM1, PWM2 control signals are generated when a drying cycle starts. When the drying cycle ends, the control means 12 inhibit the control signals PWM1, PWM2. For example, the value of the control signals PWM1, PWM2 is constant and equal to zero. In this case, the switching means Ti, T2 are in the off state and the voltage in the secondary winding 11c of the transformer 11 is zero. When the dryer is in a cycle other than drying, for example in standby or off, the control means 12 also inhibits the control signals PWM1, PWM2. If the appliance is a washer and dryer, the control signals PWM1, PWM2 are inhibited when the appliance is, for example, in a wash or spin cycle. Thus, the switching power supply circuit 10 supplies the module 30 only when the module is in operation. The consumption of the switching power supply circuit 10 is then reduced and consequently, the power consumption of the appliance is reduced. Thus, only when the module 30, here the humidity sensor, is in operation, the control means 12 generate the control signals PWM1, PWM2. In this embodiment, when the first PWM1 control signal is generated, the second PWM2 control signal is not generated and vice versa. Thus, the control signals PWM1, PWM2 are generated substantially in phase opposition. With this generation of PWM1, PWM2 control signals in phase opposition, the input currents of the transformer have substantially constant values. The generation of a control signal with respect to the other control signal is shifted by a short period of time or dead time. In this example, the dead time is 120 ns. During this dead time a transistor T1, T2 goes into the on state and the other transistor T2, Ti goes into the off state. Thus, the two parts 11a, 11b of the primary winding are successively controlled, each in turn. In this example, when the first transistor T1 is in the on state (and therefore the second transistor T2 is in the off state), the first voltage V1 is applied to the first part 11a of the primary winding of the transformer 11. The second part 11b of the primary winding of the transformer 11 is deactivated. In contrast, when the second transistor T2 is in the on state (and therefore the first transistor T1 is in the off state), the second voltage V12 is applied to the second portion 11b of the primary winding of the transformer 11. The first part 11a of the primary winding of the transformer 11 is deactivated. In the embodiment described, the two control signals PWM1, PWM2 are generated intermittently. In particular, the control signals PWM1, PWM2 are generated during a first period of time and are not generated during a second period of time. The first period of time is predetermined so that the output voltage Vour of the switching power supply circuit 10 has a substantially constant value, in this case 24 V. The first period of time is a fraction of the second period. 5 of time. In this example, the first time period is 1 ms and the second time period is 4 ms. Thus, in this example, the PWM1, PWM2 control signals have a frequency of 200 Hz. Of course, the values of the first and second time periods may be different. When one of the parts 11a, 1 lb of the primary winding is energized, the transformer 11 generates a voltage output V2 of its secondary winding 11c. In the embodiment described, the output voltage V2 is rectified and multiplied by a factor of two by the rectifying means 13. Of course, the multiplication factor of the rectifying means 13 may have different values. In another embodiment, the rectifying means are not adapted to multiply the output voltage V2 of the transformer 11, or the multiplication factor is equal to 1. In this case, the windings 11a, 11b, 11c of the transformer 11 must be adapted so that the output voltage V2 of the transformer 11 is at the appropriate value to supply the module 30.

The fourth capacitor C4 is able to filter and maintain the output voltage VOUT of the supply circuit 11 at a constant value. The transformer 11 and the rectifying means 13 operate during the first period of time. Thus, in this example, they operate for 1 ms every 5 ms. The first period is predetermined so that the value of the output voltage is maintained at a constant value by the fourth capacitor C4, while limiting the electromagnetic disturbances.

Thus, thanks to the invention, the electromagnetic disturbances produced by a switching power supply circuit according to the invention remain below the values predetermined by the standards.

Claims (9)

REVENDICATIONS1. Switching power supply circuit (10) comprising a transformer (11) and control means (12), characterized in that the transformer is controlled by at least two control signals (PWM1, PWM2) generated by said control means (12), said at least two control signals (PWM1, PWM2) being generated intermittently. The power supply circuit according to claim 1, wherein said at least two control signals (PWM1, PWM2) are generated during a first period of time, said first period of time being predetermined so that a voltage output (VouT) of said switching power supply circuit (10) has a substantially constant value. The power supply circuit according to claim 2, wherein said at least two control signals (PWM1, PWM2) are not generated during a second period of time, the first period of time being a fraction of the second period. of time. 4. Power supply circuit according to one of claims 1 to 3, further comprising switching means (Ti, T2) adapted to control the injection of energy into said transformer (11), said switching means. (T1, T2) being controlled by said at least two control signals (PWM1, PWM2). 5. Power supply circuit according to one of claims 1 to 4, further comprising rectifying means (13) adapted to rectify the output voltage (V2) of said transformer (11), the rectifying means 25 (13). ) being adapted to multiply the value of the output voltage (V2) of the transformer (11). The power supply circuit according to one of claims 3 to 5, wherein the first time period is 1 ms and the second time period is 4 ms. 30 7. Appliance characterized in that it comprises a switching power supply circuit (10) according to one of the preceding claims. 8. Appliance according to the preceding claim, wherein said switching power supply circuit (10) supplies a module (30), said at least two control signals (PWM1, PWM2) being in an inactive state when said module ( 30) is not in operation. Domestic appliance according to claim 8, wherein the module (30) comprises a humidity sensor.