JP2008086123A - Power connection system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power connection system to suppress increase in circuit scale and cost and prevent increase of power consumption by a bleeder resistor and heat generation. <P>SOLUTION: The power connection system is provided with a circuit board having a logic circuit, a power supply unit supplying power to the circuit board, a power supply line which is connected between the power supply unit and the logic circuit for power supply, a ground line, a reset signal line transmitting a reset signal from the power supply unit to the logic circuit, and a transistor which has the bleeder resistor installed between the power supply line and the ground line, is connected between the bleeder resistor and the ground line and has a switch function controlling on/off connection of the bleeder resistor to the power supply unit in accordance with on/off of the reset signal. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a power supply connection system that uses a bleeder resistor and a switching circuit to ensure that a minimum output current defined by a power supply is consumed and suppresses power consumption and heat generation by the bleeder resistor.

  In a general power supply device, a minimum output current value is specified, but in order to comply with this restriction, a bleeder resistor is mounted on the device side and current is consumed by flowing a current exceeding the specified value.

In such a case, the power consumption of the entire system increases, and heat generation in the bleeder resistance has been a major issue.
To solve this problem, for example, a DC power supply circuit detects the load current flowing through the output terminal, turns off the transistor when the load current exceeds a specified value, and current flows through the bleeder resistor. There has been proposed a technique for preventing unnecessary power loss (see Patent Document 1).

However, such a method has a problem in that the load circuit such as a detection circuit is newly required and the number of circuit components increases, so that the entire circuit becomes large and the cost increases.
JP-A-7-337007

  However, such a method has a problem in that the load circuit such as a detection circuit is newly required and the number of circuit components increases, so that the entire circuit becomes large and the cost increases.

  An object of the present application is to provide a power supply connection system capable of preventing an increase in power consumption and heat generation due to a bleeder resistance while suppressing an increase in the entire circuit and suppressing an increase in cost.

  An aspect of the present invention is a circuit board for controlling a system, which includes a circuit board having a logic circuit, a power supply device that is provided outside the circuit board and supplies power to the circuit board, the power supply device, and the power supply device A power supply line connected to the logic circuit of the circuit board and used to supply power from the power supply device to the circuit board; and connected to the power supply device and the logic circuit of the circuit board; A ground line used for grounding the circuit board, and a reset signal line connected to the power supply device and the logic circuit of the circuit board, and for transmitting a reset signal from the power supply device to the logic circuit. And a bleeder resistor provided between the power supply line and the ground line, and connected to the reset signal, the bleeder resistor and the A power supply connection system comprising: a transistor connected to a land line, and a switch for controlling connection of the bleeder resistor to the power supply device in accordance with on / off of the reset signal. is there.

  Another aspect of the present invention is a circuit board for controlling a system, including a circuit board having a logic circuit, a power supply device provided outside the circuit board and supplying power to the circuit board, Connected to the power supply device and the logic circuit of the circuit board, connected to the power supply line used to supply power from the power supply device to the circuit board, and connected to the logic circuit of the power supply device and the circuit board, For connecting a ground line used for grounding the power supply device and the circuit board, the power supply device and the logic circuit of the circuit board, and transmitting a reset signal from the power supply device to the logic circuit. A reset signal line, a bleeder resistor provided between the power supply line and the ground line, and turning on / off the bleeder resistor from the logic circuit. An on / off signal line for transmitting an on / off signal for control, and the on / off signal line is connected to the logic circuit, and is connected between the bleeder resistor and the ground line, And a transistor serving as a switch for controlling connection of the bleeder resistor to the power supply device in accordance with on / off from the logic circuit.

  According to the present invention, it is possible to avoid waste of power and heat generation of the bleeder resistor by dynamically performing connection control of the bleeder resistor that satisfies the minimum current regulation of the power source. Further, since the current flows through the bleeder resistor in a short time, the resistor can be miniaturized, and the entire circuit can be prevented from becoming large.

  That is, according to the present invention, it is possible to provide a power supply connection system capable of avoiding an increase in power consumption and heat generation due to a bleeder resistance while suppressing an increase in cost.

Embodiments of the present invention will be described below with reference to the drawings.
First Embodiment FIG. 1 is a block diagram showing an overall configuration of a power supply connection system according to a first embodiment of the present invention. FIG. 2 is a time chart showing the control sequence of the bleeder resistance in this embodiment.

In FIG. 1, reference numeral 101 denotes a power supply circuit, which is a power supply device that supplies power to the system. In a broad sense, a DC-DC converter in the system is also included.
Reference numeral 102 denotes a circuit board, which is a system control circuit board. In a computer system or the like, it corresponds to a motherboard.
Reference numeral 103 denotes a logic circuit, which is a system control circuit itself.
Reference numeral 104 denotes a bleeder resistor, which is a resistor for consuming the minimum power consumption of the power supply circuit 101.
A transistor 105 is a switch used to control connection of the bleeder resistor 104 to the power supply circuit 101. In a broad sense, switches such as relays are included.
Reference numeral 106 denotes a current limiting resistor, which is a resistor for suppressing the base current of the transistor 105.
Reference numeral 107 denotes a power supply line + (plus), which is a line for supplying power from the power supply circuit 101 to the circuit board 102.
Reference numeral 108 denotes a power supply line − (minus), which is a line for supplying power from the power supply circuit 101 to the circuit board 102, and this is a ground line for grounding.
Reference numeral 109 denotes a reset signal line, which is a line for a reset signal output by the power supply circuit 101 to reset the entire system. This signal is asserted when the power supply output is finalized. In this embodiment, the logic is indicated by active high.

  As shown in FIG. 1, the function of each module of the present embodiment is as described above. In the present embodiment, the power supply circuit 101 and the circuit board 102 are made independent, but a similar effect can be expected with a DC-DC converter mounted on the circuit board 102.

  First, in general power supply circuits, a minimum current is often defined as an output constraint. There are various reasons for this depending on the circuit system, but in the simplest example, the output voltage may not be determined unless the current between the CEs is passed through the transistor used for voltage drop in the dropper regulator. Therefore, it is due to (out of the operating range).

  As described above, the minimum output current is defined due to restrictions on the circuit (or mounted circuit elements). In a system equipped with a power supply or DC-DC converter like a modern computer system, in order to satisfy the minimum current specification of the power supply circuit, a bleeder resistor may be inserted into the power supply output section in some cases to pass a current exceeding the specification. ing. In this case, power consumption due to the bleeder resistance and heat generation countermeasures for the bleeder resistance are problems.

  In the present invention, the bleeder resistor 104 mounted to satisfy the minimum output current regulation of the power supply circuit 101 is turned on / off (connected / not connected) as necessary to reduce the above-described power waste and heat generation of the bleeder resistor 104. It is something to avoid.

  In a system typified by a computer system, power consumption increases when the operation is started (because the switching operation of the logic circuit IC 103 is started), but the present invention pays attention to this point.

  Since the minimum current regulation of the power supply circuit is a relatively small value (about 1 to 2 A at most if it is a power supply for a computer system these days), once the system starts operation, the system side (logic circuit IC103 The circuit board 102 on which is mounted) consumes more current than the minimum current.

  In the present invention, the connection of the bleeder resistor 104 is turned on until the system side (the circuit board 102 on which the logic circuit IC 103 is mounted) is operated after the power supply circuit 101 is turned on. Turn off the connection.

The operation of this embodiment will be described in detail with reference to FIGS.
First, the configuration of the entire power connection system of the present embodiment is the configuration of FIG. 1 and the above-described elements.
Power is supplied from the power supply circuit 101 to the circuit board 102 via the power supply line + (plus) 107 and the power supply line − (minus) 108. In addition to the logic circuit 103, a bleeder resistor 104 is mounted on the circuit board 102. At this time, the minimum current of the power supply circuit 101 is consumed by the bleeder resistor 104.

  The control sequence (connection on / off control) of the bleeder resistor 104 in this embodiment is as shown in FIG. 2. First, when the power is turned on, that is, when the power is turned on, the power output increases.

  When the voltage rises and reaches the rated voltage (after a reset period), the reset signal 109 is deasserted. During the reset period, the logic circuit 103 mounted on the circuit board 102 does not perform a switching operation and consumes little power.

  The load of the power supply circuit 101 is light, and only a current below the minimum current specification flows. Therefore, only during the reset period, the transistor 105 is turned on using the reset signal 109 as a control signal, and a current flows through the bleeder resistor 104.

  By passing a current through the bleeder resistor 104, the minimum current constraint of the power supply circuit 101 is satisfied. When the reset period ends and the reset signal 109 is deasserted, the transistor 105 is turned off, and power is not consumed by the bleeder resistor 104.

  On the other hand, since the logic circuit 103 starts the switching operation, the power consumption increases and a current exceeding the minimum current consumption of the power supply circuit 101 flows, and the operation of the power supply circuit 101 is guaranteed.

  That is, in the power supply connection system according to the first embodiment, a circuit board 101 that is a circuit board that controls the system and has the logic circuit 102, and is provided outside the circuit board 102 to supply power to the circuit board 102. A power supply line + (+) connected to the power supply apparatus 101 and the logic circuit 103 provided in the circuit board 102 and used for power supply from the power supply apparatus 101 to the circuit board 102 (Plus) 107 and a power supply line − (minus) which is connected to the power supply apparatus 101 and the logic circuit 103 provided in the circuit board 102 and is used for grounding the power supply apparatus 101 and the circuit board 102. 108).

  Further, the power supply connection system in the first embodiment is connected to the power supply device 101 and the logic circuit 103 provided in the circuit board 102, and is a reset signal line for transmitting a reset signal from the power supply device to the logic circuit 103. 109, a bleeder resistor 104 provided between a power supply line + (plus) 107 as a power supply line and a power supply line − (minus) 108 as a ground line, and a reset signal line 109. , A switch for controlling the connection of the bleeder resistor 104 to the power supply device 101 in accordance with the on / off of the reset signal 109, connected between the bleeder resistor 104 and the power supply line − (minus) 108 as a ground line. A transistor 105 is provided.

  As described above, in the first embodiment, the bleeder resistance 104 is dynamically connected / not connected as the load of the power supply circuit 101 by turning on / off the transistor 105 according to the reset signal 109. Unnecessary current consumption by 104 and heat generation of bleeder resistor 104 are avoided.

Second Embodiment FIG. 3 is a block diagram showing an overall configuration of a power supply connection system according to a second embodiment of the present invention. Further, the control sequence of the bleeder resistance in this embodiment takes the same time chart as FIG.

In FIG. 3, reference numeral 101 denotes a power supply circuit, which is a power supply device that supplies power to the system. In a broad sense, a DC-DC converter in the system is also included.
Reference numeral 102 denotes a circuit board, which is a system control circuit board. In a computer system or the like, it corresponds to a motherboard.
Reference numeral 103 denotes a logic circuit, which is a system control circuit itself.
Reference numeral 104 denotes a bleeder resistor, which is a resistor for consuming the minimum power consumption of the power supply circuit 101.
A transistor 105 is a switch used to control connection of the bleeder resistor 104 to the power supply circuit 101. In a broad sense, switches such as relays are included.
Reference numeral 106 denotes a current limiting resistor, which is a resistor for suppressing the base current of the transistor 105.
Reference numeral 107 denotes a power supply line + (plus), which is a line for supplying power from the power supply circuit 101 to the circuit board 102.
Reference numeral 108 denotes a power supply line − (minus), which is a line for supplying power from the power supply circuit 101 to the circuit board 102, and this is a ground line for grounding.
Reference numeral 109 denotes a reset signal line, which is a line for a reset signal output by the power supply circuit 101 to reset the entire system. Asserted when power supply output is finalized.
An on / off signal line 110 is connected to the bleeder resistor 104 from the logic circuit 103 and is a signal for controlling the connection of the bleeder resistor 104. When the logic circuit 103 starts to operate, the signal shifts to a low level. Signal.

  The power connection system in the second embodiment has the same configuration as that of the first embodiment described above from the power supply circuit 101 to the reset signal line 109, but not in response to the reset signal 109 but in the circuit board 102. The point that the connection of the bleeder resistor 104 can be controlled by turning on / off the transistor 105, which is a switch circuit, directly from the provided logic circuit 103 using the on / off signal 110 is the same as in the first embodiment. Is different.

  In other words, the power supply connection system according to the second embodiment has a logic circuit 103, a circuit board 102 for controlling the system, and a power supply that is provided outside the circuit board 102 and supplies power to the circuit board 102. A power supply line + (plus) which is connected to the device 101, the power supply device 101 and the logic circuit 103 provided in the circuit board 102 and is used for power supply from the power supply apparatus 101 to the circuit board 102. 107, and a power supply line-(minus) 108, which is connected to the power supply apparatus 101 and the logic circuit 103 of the circuit board 012 and is used for grounding the power supply apparatus 101 and the circuit board 102. ing.

  Further, the power supply connection system in the second embodiment is connected to the power supply device 101 and the logic circuit 103 provided in the circuit board 102, and a reset signal for transmitting a reset signal from the power supply device 101 to the logic circuit 103. A bleeder resistor 104 provided between a line 109, a power supply line + (plus) 107 as a power supply line and a power supply line − (minus) 108 as a ground line; An on / off signal line 110 for transmitting an on / off signal for controlling on / off, and a power supply that is connected to the logic circuit 103 by the on / off signal line 110 and is a bleeder resistor 104 and a ground line Connected between the supply line-(minus) 108 and turned on / off from the logic circuit 103 And a transistor 105 is a switch for controlling the connection to the power supply 101 of the bleeder resistor 104.

  As described above in detail, according to the present invention, it is possible to avoid waste of power and heat generation of the bleeder resistor by dynamically performing connection control of the bleeder resistor that satisfies the minimum current regulation of the power source. Further, since the current flows through the bleeder resistor in a short time, the resistor can be miniaturized, and the entire circuit can be prevented from becoming large.

  That is, according to the present invention, it is possible to provide a power supply connection system capable of avoiding an increase in power consumption and heat generation due to a bleeder resistance while suppressing an increase in cost.

1 is a block diagram showing an overall configuration of a power connection system according to a first embodiment of the present invention. The time chart which shows the control sequence of the bleeder resistance in this embodiment. The block diagram which shows the whole structure of the power supply connection system regarding the 2nd Embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 101 ... Power supply circuit 102 ... Circuit board 103 ... Logic system 104 ... Bleeder resistance 105 ... Transistor 106 ... Power supply limitation resistance 107 ... Power supply line + (plus): Power supply line 108 ... Power supply line-(minus): Ground line 109 ... Reset signal line 110 ... On / off signal line

Claims (2)

A circuit board for controlling the system, the circuit board having a logic circuit;
A power supply device provided outside the circuit board for supplying power to the circuit board;
A power supply line connected to the power supply device and the logic circuit of the circuit board, and used to supply power from the power supply device to the circuit board;
A ground line connected to the power supply device and the logic circuit of the circuit board, and used for grounding the power supply device and the circuit board;
A reset signal line connected to the power supply device and the logic circuit of the circuit board, for transmitting a reset signal from the power supply device to the logic circuit;
A bleeder resistor provided between the power supply line and the ground line;
A switch connected to the reset signal, connected between the bleeder resistor and the ground line, and for controlling connection of the bleeder resistor to the power supply device according to on / off of the reset signal. A power supply connection system comprising: a transistor. A circuit board for controlling the system, the circuit board having a logic circuit;
A power supply device provided outside the circuit board for supplying power to the circuit board;
A power supply line connected to the power supply device and the logic circuit of the circuit board, and used to supply power from the power supply device to the circuit board;
A ground line connected to the power supply device and the logic circuit of the circuit board, and used for grounding the power supply device and the circuit board;
A reset signal line connected to the power supply device and the logic circuit of the circuit board, for transmitting a reset signal from the power supply device to the logic circuit;
A bleeder resistor provided between the power supply line and the ground line;
An on / off signal line for transmitting an on / off signal for controlling on / off of the bleeder resistor from the logic circuit;
The on / off signal line is connected to the logic circuit, and is connected between the bleeder resistor and the ground line, and the bleeder resistor is connected to the power supply device according to on / off from the logic circuit. And a transistor that is a switch for controlling connection.

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