KR20100023232A - Power supply having multiple outputs - Google Patents

Abstract

PURPOSE: A power supply having multiple outputs is provided to increase the voltage conversion efficiency by using a non-insulated voltage converter. CONSTITUTION: A multi-output power supply unit(100) comprises a power input unit(102), more than two voltage converters(120a,120b), a rectifying circuit(106). The power input unit receives an AC voltage. The rectifying circuit receives an inputted AC voltage. The rectifying circuit rectifies the AC voltage to a DC voltage. The voltage converter changes the rectified DC voltage into a desired output voltage. The voltage converter comprises a receiver, a transformer, and an output unit. The receiver receives the rectified DC voltage. The transformer converts the DC voltage. The output unit outputs the transformed DC voltage.

Description

Multiple output power unit {POWER SUPPLY HAVING MULTIPLE OUTPUTS}

The present invention relates to a power supply, and more particularly to a multiple output power supply for outputting a plurality of different DC voltages.

In addition to increasing functions of various electronic devices such as computers, communication devices, and home appliances, a number of devices using different voltages are included in a single device. If a device supplied with a constant commercial alternating voltage has a separate power supply for each voltage output required, in order to obtain a number of different DC voltage outputs required by each element contained therein in the device, Its industrial effectiveness is low because it will lead to larger equipment and higher prices. Accordingly, much research has been made on the design of a multiple output power supply that receives one AC voltage input and provides a plurality of different DC voltage outputs.

Specifically, as an example of such a power supply device, a separate transformer is used for each of a plurality of voltage outputs. In the case of such a device, feedback control is performed for each voltage output, so that a high-precision voltage adjustment is possible, but in order to obtain a plurality of outputs, as many transformers are used as the number of outputs, the volume increases due to the price increase and the number of parts. This will cause many problems.

As another example of such a power supply device, a plurality of outputs may be obtained using one common transformer, and only one output of the plurality of outputs may be feedback-controlled. Such a device has advantages such as a low cost and a reduced number of transformers. However, since the control of the remaining sub-outputs cannot be performed except for one main output stage where feedback control is performed, the voltage of the sub-output stage varies greatly depending on the load current. May cause

As a combination of the two types of devices described above, one dedicated transformer is used for the main voltage output (source voltage output), while a plurality of these subvoltage outputs are grouped together for the negative voltage outputs for a plurality of other devices. There is a form to configure and use one common transformer for each set. However, even with such a device, there are still problems such as a price increase, volume and weight increase due to the use of a plurality of transformers, and insufficient control of a plurality of sets of voltage outputs in a set.

As described above, in the case of a multiple output power supply device that performs voltage conversion using a plurality of transformers, there are many problems caused by using a plurality of transformers. Specifically, as well as the above-mentioned problems such as price, volume, weight increase, etc., all the transformation for each output voltage is made by the transformer and the switching control of each transformer is made through the switching element arranged on the primary side. The switching elements placed on the primary side of the transformer have a constraint that all must be designed with high breakdown voltage to withstand the high voltage before the transformer. In addition, the frequency of the signal for the high voltage resistance switching element included in the transformer is usually a relatively low frequency, such as 100 to 300KHz, so that the switching response of the transformer is made at a relatively slow speed and adjustment of the output result according to the switching control This is achieved within a relatively large margin of error of approximately ± 10%. In addition, since the output voltage is determined by a fixed hardware design of the feedback control circuit, there is a problem in that a new specification of a hardware design must be adopted to obtain a new voltage. The output sequence control procedure and the protection circuit configuration are complicated by controlling the output sequence of the secondary side after the transformation and feedback control of the switching elements placed on the primary side before the transformation again based on the output signal from the secondary side after the transformation. A large number of photocouplers for signal isolation are required for the feedback input of the secondary output signal, which adds to the cost and weight. In terms of design, the transformer controlled by the low frequency signal is usually designed to include an aluminum capacitor (Al-Cap) with good low frequency characteristics, which causes problems with deteriorating the lifetime and temperature characteristics of the device, and the transformer is mounted on the chip. In this case, the lead pin method is mainly used, which causes a problem that causes an additional request for an anti-vibration component.

Accordingly, there is a need for a more efficient, simple and productive multiple output power supply device that overcomes many of the problems caused by performing voltage conversion through multiple transformers.

Accordingly, the present invention provides an efficient and highly productive multiple output power supply device that performs voltage conversion using a non-isolated voltage converter.

According to one aspect of the invention, a multiple output power supply having two or more outputs is provided. According to the present invention, the multiple output power supply apparatus includes a power input unit to which an AC voltage is input, a rectifier circuit unit to receive an input AC voltage and rectify the DC voltage, and two or more voltages to receive and convert the rectified DC voltage to a desired output voltage. It includes a converter. Each of the voltage converters includes a receiver for receiving a rectified DC voltage, a transformer for performing voltage conversion of the received DC voltage, and an output for outputting a DC voltage for which voltage conversion has been performed. Is composed of non-insulated type.

According to one embodiment of the invention, each voltage converter comprises a switching element, a diode, a coil and a capacitor for performing switching control.

According to an embodiment of the present invention, the multiple output power supply device further includes an insulated transformer that receives the rectified DC voltage in the rectifying circuit unit, and each voltage converter receives the rectified DC voltage through the insulated transformer.

According to an embodiment of the present invention, the multiple output power supply apparatus further includes a standby power unit for receiving the rectified DC voltage rectified by the rectifying circuit unit, converting the received DC voltage and outputting the standby power.

According to one embodiment of the invention, the standby power unit comprises an isolated transformer.

According to one embodiment of the invention, the multiple output power supply further comprises a switch for controlling the on / off input of the rectified DC voltage rectified in the rectifying circuit unit to the isolated transformer.

According to an embodiment of the present invention, the multiple output power supply apparatus further includes a power control unit for outputting a first control signal for on / off control of the switch and a second control signal for operation control of each voltage converter.

According to an embodiment of the present invention, the multiple output power supply apparatus further includes a micom to be connected to the power control unit for generating commands input to the power control unit, the power control unit based on the commands received from the microcomputer, the first Adjust the control signal and the second control signal.

According to one embodiment of the present invention, the power control unit includes one or more voltage converters, each of the one or more voltage converters, a receiving unit for receiving a predetermined DC voltage, a transformer for performing a voltage conversion of the received DC voltage, and And an output unit for outputting a DC voltage subjected to voltage conversion, and between the receiving unit and the output unit of each of the one or more voltage converters are configured to be non-isolated.

According to one embodiment of the invention, the power control section also receives a feedback signal from the output of each voltage converter.

According to one embodiment of the invention, the power control section adjusts each second control signal for operation control of each corresponding voltage converter based on the feedback signal received from the output of each voltage converter.

According to an embodiment of the present invention, the communication between the power control unit and the microcomputer is digital communication according to a predetermined protocol.

According to one embodiment of the invention, the predetermined protocol is I ² C or SPI.

According to an embodiment of the present invention, the rectifier circuit portion includes a bridge rectifier circuit.

According to an embodiment of the present invention, the multiple output power supply apparatus further includes a booster circuit unit for boosting the DC voltage rectified by the rectifier circuit unit.

According to the present invention, it is possible to provide a multiple output power supply device with a simple configuration, low production cost, and high efficiency.

Embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following, when it is determined that there is a risk of unnecessarily obscuring the gist of the present invention, a detailed description of already known functions and configurations will be omitted. In addition, it should be understood that the following description only relates to one embodiment of the present invention, but the present invention is not limited thereto.

1 is a view schematically showing a multiple output power supply device 100 according to an embodiment of the present invention.

As shown, the multiple output power supply device 100 receives an AC voltage signal from the power input unit 102. The AC voltage signal may be passed to the EMI filter 104. The EMI filter 104 removes electromagnetic noise from the received AC voltage signal to prevent component damage or the like inside the device.

The AC voltage signal from which the electromagnetic noise is removed from the EMI filter 104 may be input to the rectifier circuit 106. The rectifier circuit 106 converts an AC voltage signal in which the positive voltage and the negative voltage periodically change to a DC voltage signal having a positive voltage, and outputs the DC voltage signal. According to one embodiment of the present invention, the rectifying circuit section 106 may be configured to include, for example, a half-wave rectifying circuit, a full-wave rectifying circuit, a bridge rectifying circuit, and the like, and is particularly simple and efficient when it is configured to include a bridge rectifying circuit. A rectifying circuit part can be obtained.

The DC voltage signal output from the rectifying circuit unit 106 may be received by the switch 108 and the stand-by block 110, respectively. Regardless of the on / off state of the switch 108 which will be described later, as long as the AC voltage input from the power input unit 102 is continued, the standby power unit 110 continuously receives the DC voltage output from the rectifying circuit unit 106. Receive. Standby power refers to power consumed in a stand-by state in order to guarantee the normal operation of the device, and refers to power consumed regardless of whether the device is operated or not. The power consumed in the standby state for receiving the remote control signal.

According to an embodiment of the present invention, the standby power unit 110 may include a transformer. The transformer of the standby power unit 110 converts the DC voltage received from the rectifying circuit unit 106 into a predetermined constant voltage signal and outputs it. The predetermined constant voltage power output from the standby power unit 110, for example, 5 V standby power, may be received by the power controller 112 and the microcomputer 114, respectively. According to an embodiment of the present invention, the standby power unit 110 may include an insulated transformer. In this case, the standby power unit 110 insulates the primary side circuit and the secondary side circuit in the multiple output power supply device 100, and such insulation between the primary and secondary side circuits may cause noise or abnormality between both sides. Protect the equipment by blocking the ingress of voltage.

The switch 108 may be used to determine whether to transfer the DC voltage signal received from the rectifying circuit unit 106 to the next stage by being turned on and off under the control of the power control unit 112 and the microcomputer 114. According to one embodiment of the invention, the switch 108 may be configured as a relay or various electronic switches.

When the switch 108 is in the ON state, a DC voltage signal transmitted through the switch 108 may be received by a power factor correction part 116. The power factor correction booster circuit 116 is a circuit for correcting the power factor by adjusting a phase difference between a current and a voltage so that waveforms shifted from each other coincide with each other and are configured in a boost-up manner. That is, the power factor correcting booster circuit 116 boosts and outputs the DC voltage signal received through the switch 108 to a predetermined voltage using an inductance accumulating element or the like. According to an embodiment of the present invention, the resulting voltage boosted by the power factor correcting booster circuit 116 may have a value of, for example, 380 to 400V regardless of the input voltage. However, it should be noted that the power factor correcting booster circuit unit 116 is an element that can be selectively used when designing a power supply, and the present invention is not limited to a circuit configuration including the power factor correcting booster circuit unit 116.

The voltage signal output from the power factor correcting booster circuit 116 may be received by the insulated transformer 118. The insulated transformer 118 is constructed of a lottery type structure including primary and secondary coils separated from each other. The isolated transformer 118 insulates the primary side circuit and the secondary side circuit inside the multiple output power supply 100. Such insulation between the primary and secondary side circuits prevents the inflow of noise or abnormal voltage between the two sides. Protect your device by blocking it.

The power control unit 112 continuously monitors the voltage signal output by the insulated transformer 118 and determines whether the output voltage signal has a predetermined voltage. The power control unit 112 may also receive a constant voltage standby power from the standby power unit 110 while receiving a digital control signal from the microcomputer 114. The digital control signal transmitted from the microcomputer 114 to the power control unit 112 may not only include a command used for on / off control of the switch 108 as described above, but also each non-isolated voltage converter described below. It may include a command used to control the operation of (120a, 120b). Transmission and reception of digital control signals between the power control unit 112 and the microcomputer 114 may be performed based on a predetermined protocol. According to one embodiment of the present invention, for example, a protocol such as I ² C, SPI, and the like may be used to transmit and receive signals between the power control unit 112 and the microcomputer 114.

The voltage signal output from the isolated transformer 118 is received by the voltage receivers of the respective non-isolated voltage converters 120a and 120b. The non-isolated voltage converters 120a and 120b include a transformer that performs voltage conversion of the input DC voltage signal, and an output unit that outputs a DC voltage subjected to voltage conversion. It should be noted that each of the non-isolated voltage converters 120a and 120b is a non-isolated type without electrical insulation between the voltage receiver and the output part.

According to an embodiment of the present invention, the non-isolated voltage converters 120a and 120b may be composed of a circuit including a switching element, a diode, and an LC filter instead of using a transformer. According to an embodiment of the present invention, the non-isolated voltage converters 120a and 120b may be configured in a so-called buck or buck-boost manner. The non-isolated voltage converters 120a and 120b also receive operation control signals from the microcomputer 114 and the power control unit 112. According to an embodiment of the present invention, the operation control signal may be a pulse width modulation (PWM) control signal. The operation control signal controls on / off of the switching elements included in each of the non-isolated voltage converters 120a and 120b, and the DC voltage signal input to the non-isolated voltage converters 120a and 120b is converted into a predetermined DC voltage. To control. Accordingly, the values of the output voltages 122a and 122b from the non-isolated voltage converters 120a and 120b may vary according to control signals from the microcomputer 114 and the power control unit 112.

The voltage signal output from the non-isolated voltage converters 120a and 120b may also be feedbacked to the power control unit 112. The power controller 112 monitors the feedback input signal and adjusts an operation control signal to be transmitted to the non-isolated voltage converters 120a and 120b. As described above, the operation control signal controls on / off of the switching elements of the non-isolated voltage converters 120a and 120b, and the DC voltage signal input to the non-isolated voltage converters 120a and 120b is converted to a predetermined DC voltage. Control to be converted. Accordingly, the signal inputted from the output of the non-isolated voltage converters 120a and 120b may be used by the power controller 112 to generate an operation control signal of the non-isolated voltage converters 120a and 120b. Although only two non-isolated voltage converters 120a and 120b are shown in FIG. 1, it is to be understood that the present invention may be configured to include a different number of non-isolated voltage converters 120a and 120b.

Although not shown in FIG. 1, according to another embodiment of the present invention, one or more non-isolated voltage converters may be included in the power controller 112. For example, it should be appreciated that a non-isolated voltage converter that provides a relatively low voltage output for a load with low power consumption may be included in the power control unit 112 instead of a separate device.

2 is a diagram illustrating a circuit configuration of a non-isolated voltage converter 120 according to an embodiment of the present invention.

As shown, the input current Vi is connected to one terminal of the switch S. The switch S may be composed of any semiconductor switch element such as FET or IGBT. The switch S is controlled on / off based on the operation control signal CS. As a method of controlling the switch S, for example, a frequency control method of varying the switching frequency and a duty ratio control method of varying the switching duty ratio are controlled. Consider. However, it should be noted that the present invention is not limited thereto.

As shown, when switch S is turned on, input current Vi flows through L to output output, while electrical energy is accumulated in coil L. After that, when the switch S is turned off, the power energy accumulated in the coil L flows through the diode D to the output output. This operation is repeated for each switching cycle, causing the input voltage Vi to change to the output of the appropriate voltage. Capacitor C removes noise from the voltage signal, allowing the output output to have a stable DC constant voltage.

3 is a diagram schematically illustrating an internal configuration of the power control unit 112 shown in FIG. 1. 3 shows only the components necessary to explain the gist of the present invention, and it should be understood that the illustration and description have been omitted for other components irrelevant to the gist of the present invention or well known to those skilled in the art. .

As shown, the power controller 112 includes a standby power receiver 302, a microcomputer interface unit 304, a switch controller 306, a voltage converter feedback input receiver 308, and a voltage converter operation control signal output unit 310. It includes. As described above, the standby power receiver 302 continuously receives standby power of a predetermined constant voltage from the standby power unit 110 while there is a signal input from the power input unit 102, and each element inside the power control unit 112. To deliver the necessary power. The microcomputer interface unit 304 serves as an interface when receiving a signal from the microcomputer 114. As described above, signal transmission from the microcomputer 114 to the power control unit 112 may be based on a predetermined protocol, and the microcomputer interface unit 304 interprets the signal transmitted according to the protocol as an appropriate form of command. . The switch controller 306 monitors a voltage signal output from the isolated transformer 118 and input to the non-isolated voltage converters 120a and 120b, and receives the monitored signal and the command received from the microcomputer interface unit 304. Based on the switch 108 on / off control command, a control signal for controlling the on / off of the switch 108 is generated and output. The voltage converter feedback input receiver 308 monitors each output voltage signal from each of the non-isolated voltage converters 120a and 120b and feedback-receives the monitoring signal. The voltage converter operation control signal output unit 310 controls each of the non-isolated voltage converters 120a and 120b based on a feedback monitoring signal from the voltage converter feedback input receiver 308 and a control command received from the microcomputer interface unit 304. Outputs an operation control signal.

Although not shown in FIG. 3, it is to be understood that the power control 112 as described above may include one or more non-isolated voltage converter configurations therein. The specific configuration of the one or more non-isolated voltage converters included in the power control unit 112 may be, for example, a configuration as shown in FIG. 2, and a detailed description thereof will be omitted. When the power control unit 112 includes one or more non-isolated voltage converter configurations therein, the non-isolated voltage converter configuration included in the power control unit 112 receives predetermined standby power from the standby power receiver 302 therein. The received and received standby power is converted into a predetermined voltage and output. However, it should be understood that the present invention is not necessarily limited to such a configuration.

According to the present invention, the circuit isolation of the primary and secondary side of a multiple output power supply is made at the stage before the non-isolated voltage converter in which the output voltage conversion is made, and the actual conversion of each output voltage is made of non-isolated type arranged on the secondary side. By means of a voltage converter, each output voltage conversion is performed by an insulated transformer, and the primary side components and wiring are greatly reduced compared to the prior art in which the primary and secondary side circuit insulation is performed by such a transformer, thereby ensuring safety Easy to design In addition, the transformers are used only for primary and secondary side isolation of the entire circuit and may not be used for each voltage output, thus greatly reducing the number of transformers required and reducing board size and weight. In addition, the demand for high voltage resistance switches and transformer current detection resistors placed on the primary side is greatly reduced. In addition, compared to a transformer according to a low frequency control of about 100 to 300 KHz, a non-isolated voltage converter can perform voltage conversion under high frequency control of about 1 MHz, so that a fast response speed can be achieved, and the output voltage can be adjusted by about ±. As high as 2.5% can be achieved.

In addition, in the conventional case in which the isolated transformer performs circuit isolation and voltage conversion, a large number of photocouplers are required so that the voltage-converted secondary output signal can be fed back to the primary side. Input and output feedback control of the non-isolated voltage converter is done on the secondary side, which eliminates most of the use of photocouplers for signal isolation and simplifies protection circuit and output sequence control. In addition, transformers with low frequency control have undesirable life and temperature characteristics by using aluminum capacitors (Al-Caps) at their output terminals and require additional components for vibration test measures as they are integrated by lead mounting methods. In contrast, non-isolated voltage converters, which are small elements that receive high-frequency input signals, can use ceramic capacitors at their output terminals, which not only provide good life and temperature characteristics, but are also integrated by surface mount methods. Does not require additional parts as a vibration test measure.

According to the present invention, when a plurality of output voltages are conventionally bundled and voltage converted by one transformer block, output voltages are fixed for each block developed by a hardware design, so that a power supply device is individually developed for each device. Unlike what has to be done, the output voltage of each voltage converter can be variably controlled according to the digital signal control by the microcomputer and the power control unit without changing the hardware design, it is possible to develop a general-purpose power supply. In short, the present invention not only greatly improves product efficiency, economy, productivity, and the like, but also has the advantage of enabling development of a general-purpose multiple output power supply device.

As will be appreciated by those skilled in the art, the present invention is not limited to the examples described herein but may be variously modified, reconfigured and replaced without departing from the scope of the present invention. Therefore, it is intended that the present invention cover all modifications and variations that fall within the true spirit and scope of the present invention.

1 is a view schematically showing a multiple output power supply device according to an embodiment of the present invention;

2 is a circuit diagram of a non-isolated voltage converter according to an embodiment of the present invention.

3 is a diagram schematically showing an internal configuration of the power control unit shown in FIG. 1;

<Explanation of symbols for the main parts of the drawings>

102: power input unit 104: EMI filter

106: rectifying circuit section 108: switch

110: standby power unit 112: power control unit

114: micom 116: boost circuit unit for power factor correction

118: isolated transformer 120a, 120b: non-isolated voltage converter

Claims (16)

Multiple output power supply with two or more outputs, A power input unit to which an AC voltage is input; A rectifier circuit unit configured to receive the input AC voltage and rectify the DC voltage; And Two or more voltage converters for receiving the rectified DC voltage and converting it to a desired output voltage Including, Each of the voltage converters includes a receiver for receiving the rectified DC voltage, a transformer for performing voltage conversion of the received DC voltage, and an output for outputting a DC voltage in which the voltage conversion is performed. Non-isolated type between the receiver and the output in each of the voltage converters Multiple output power supply. The method of claim 1, Wherein each voltage converter comprises a switching element, a diode, a coil, and a capacitor for performing switching control. The method of claim 2, And an insulated transformer receiving the rectified DC voltage in the rectifying circuit unit, wherein each voltage converter receives the rectified DC voltage through the insulated transformer. The method of claim 1, And a standby power unit configured to receive the DC voltage rectified by the rectifier circuit unit, convert the received DC voltage and output the standby DC voltage as standby power. The multiple output power supply of claim 4, wherein the standby power unit comprises an isolated transformer. 4. The multiple output power supply device according to claim 3, further comprising a switch for on / off controlling the input of the DC voltage rectified in the rectifying circuit unit to the isolated transformer. The method of claim 6, And a power controller configured to output a first control signal for on / off control of the switch and a second control signal for operation control of each voltage converter. The method of claim 7, wherein Output voltage of each voltage converter is determined based on the corresponding second control signal. The method of claim 7, wherein A microcomputer connected to the power control unit to generate commands input to the power control unit; The power control unit adjusts the first control signal and the second control signal based on the commands received from the microcomputer. The method of claim 7, wherein The power control unit includes one or more voltage converters, and each of the one or more voltage converters includes a receiver for receiving a predetermined DC voltage, a transformer for performing voltage conversion of the received DC voltage, and the voltage conversion being performed. And an output unit for outputting a DC voltage, wherein the receiving unit and the output unit of each of the one or more voltage converters are non-isolated. The method of claim 7, wherein And the power control unit also receives a feedback signal from the output of each of the voltage converters. The method of claim 11, And the power control unit adjusts each of the second control signals for operation control of each corresponding voltage converter based on the feedback signal received from the output unit of each voltage converter. The method of claim 9, Communication between the power control unit and the microcomputer is a multiple output power supply device according to a predetermined protocol. The method of claim 13, And the predetermined protocol is I ² C or SPI. The method of claim 1, The rectifier circuit portion includes a bridge rectifier circuit. The method of claim 1, And a booster circuit unit for boosting the DC voltage rectified by the rectifier circuit unit.

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