JP2819798B2 - Online maintenance circuit for redundant power supply - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a redundant power supply that is suitable for use in an electronic device in which a plurality of power supply devices are connected in parallel and that can be maintained online.

<Conventional Technology> FIG. 4 is a configuration diagram illustrating a conventional redundant power supply device. In the figure, the power supply card 10 is a butt diode
It is connected to the system power supply line 30 through 20.

In such an apparatus, there is an application in which it is necessary to insert and remove the power supply card 10 in a live state (while the system is operating). In this case, connect the power card 10 to the system power line 30
In order to prevent excessive charging current from flowing from the system power supply line 30 side to the output smoothing capacitor of the power supply card 10 when the power supply card 10 is inserted into the power supply card 10 and burn out the connector, a butt diode 20 is arranged in series with the output of the power supply card 10. It had been.

<Problems to be Solved by the Invention> However, there has been a problem that the output voltage of the power supply card 10 drops due to the butt diode 20 and the loss increases, so that high efficiency cannot be obtained and heat generation also increases.

An object of the present invention is to provide an online maintenance circuit for a redundant power supply that achieves high output efficiency and generates little heat.

<Means for Solving the Problems> According to a first aspect of the present invention, the power transmitted from the input terminals (P1, P2) is set to a predetermined voltage, and the power is supplied to the output terminal (P5) and the common terminal (P6). A load-side circuit that has a plurality of power supplies (CVs) to be connected, is connected to the output terminal and the common terminal, and is commonly connected to the output terminal, the voltage detection terminal (P3), and the connection instruction terminal (P4). Against
In a redundant power supply in which the plurality of power supplies are connected in common with the output terminal and the common terminal to supply an output voltage,
It has the following configuration.

That is, a connector for connecting the power supply and the load side circuit, wherein the input terminal, the voltage detection terminal, and the common terminal are connected, and then the connection instruction terminal and the output terminal are connected, and the voltage of the output terminal. An error amplifier (A) that stabilizes the reference voltage to a reference voltage, and a reference voltage of the error amplifier,
A switch circuit (SW) that is connected to the voltage detection terminal and sets the voltage of the voltage detection terminal before the connection instruction terminal is connected, and sets a predetermined reference voltage (Vref) after the connection instruction terminal is connected. It is characterized by the following.

The second invention for achieving such an object relates to a case with remote sensing, which connects a power supply (CV) and a load side circuit, and has an input terminal and a remote terminal (P7, P8). A connector to which the output terminal and the common terminal are connected after being connected, and a voltage of the output terminal is connected to a voltage of the remote voltage detection terminal by a predetermined reference voltage (Vre
f) controlling the power supply device, a remote error amplifier (A0) for stabilizing the power supply device so as to be equal to the voltage of the output terminal, and a provisional error amplifier (A1) for stabilizing the voltage of the output terminal to the voltage of the remote voltage detection terminal. A switch circuit (SW) to which the error amplifier is connected as the temporary error amplifier before the connection of the connection terminal and the remote voltage detection terminal, and as a remote error amplifier after the connection of the output terminal. And

<Operation> Each component of the first invention has the following operation. The connector has a structure in which a voltage detection terminal and the like are connected before a voltage detection terminal and an output terminal. The switch circuit detects the connection state of the connector and switches the reference voltage of the error amplifier. The error amplifier raises the output voltage of the power supply to the system side voltage when only the voltage detection terminal and the like are connected, and prevents the occurrence of an inrush current when the output terminal is connected. After the output terminal is connected, the output voltage is stabilized by the error amplifier circuit.

The components of the second invention have the following functions. The connector has a structure in which a remote terminal or the like is connected before an output terminal or the like. The switch circuit detects the connection state of the connector and switches the error amplifier. The provisional error amplifier raises the output voltage of the power supply to the system side voltage when only the remote voltage detection terminal and the like are connected, and prevents the occurrence of an inrush current when the output terminal is connected. After the output terminal is connected, the output voltage is stabilized by the remote error amplifier.

<Example> Hereinafter, the present invention will be described with reference to the drawings.

FIG. 1 is a block diagram showing a configuration of an embodiment of the first invention, in which there is no remote sensing. In the figure, a power supply CV is, for example, an AC-DC converter, and input terminals P1 and P
The commercial AC power AC supplied from 2 is converted into a predetermined DC voltage and supplied to the output terminal P5 and the common terminal P6. A DC voltage such as 24V is supplied from the input terminals P1 and P2,
CV may be a DC-DC converter. The power supply CV is connected in parallel with another power supply CV via a system power supply line (not shown). In the load side circuit, it is connected to the output terminal P5 and the common terminal P6. Further, the voltage detection terminal P3 and the connection instruction terminal P4 are connected to the output terminal P5, and the voltage of the other power supply CV is the system side voltage.

FIG. 2 is an explanatory diagram of pins of a connector. The connector connects the power supply CV to the load side circuit on the system side. The length of the pins of the input terminals P1, P2, the voltage detection terminal P3, and the common terminal P6 is longer than the length of the pins of the connection instruction terminal P4 and the output terminal P5, and after the former terminal is connected. A so-called sequence connection in which the latter terminal is connected is realized.

Returning to FIG. 1, the error amplifier A has a negative terminal connected to the output terminal P5 and a positive terminal connected to the voltage detection terminal P3 via the resistor R1. The output signal of the error amplifier A is
Used to control the output voltage of the power supply CV. The transistor Q constituting the switch circuit SW has a collector terminal connected to the plus terminal of the error amplifier A via the reference voltage source Vref, and an emitter terminal grounded. Connection instruction terminal P4
Is applied to the base terminal of the transistor Q via the voltage dividing resistors R2 and R3.

The operation of the device configured as described above will now be described. When the power supply CV is half-inserted into the system power supply line, the input terminals P1, P2, the voltage detection terminal P3, and the common terminal P6 are connected to the load side circuit, and the connection instruction terminal P4 and the output terminal P5
Is open. Therefore, the transistor Q is turned off, and the reference voltage of the error amplifier A is at the voltage detection terminal P3. Therefore, the voltage of the output terminal P5 is equal to the voltage of the voltage detection terminal P3.

When the insertion operation is further continued, the power supply CV is all connected to the system power supply line. Since the connection instruction terminal P4 is connected to the system-side voltage, the transistor Q is turned on.
Therefore, the reference voltage of the error amplifier A becomes the reference voltage Vref, and the voltage of the output terminal P5 is stabilized based on the reference voltage Vref.

FIG. 3 is a structural block diagram showing an embodiment of the second invention, showing a case where remote sensing is provided. Power supply CV
Is the same as that of FIG. The load side circuit is the output terminal
It has a remote voltage detection terminal P7 and a remote common terminal P8 connected to P5 and the common terminal P6, and a system-side voltage is applied to these remote terminals. The connector has at least six terminals similar to those shown in FIG. 2, and has input terminals P1 and P2 and a remote voltage detection terminal P.
7 and the length of the remote common terminal P8 are the output terminal P5
In addition, the length is longer than the length of the pin of the common terminal P6, and the latter terminal is connected after the former terminal is connected. Note that the remote common terminal P8 is directly grounded, while the common terminal P6 is grounded via a resistor R4.

The remote error amplifier A0 has a negative terminal connected to the remote voltage detection terminal P7 and a voltage dividing resistor R5, R6. The plus terminal is the reference voltage source Vr via the resistor R7.
ef, the output terminal is connected to the voltage control terminal of the power supply CV via the resistor R8, and this output terminal voltage is called the remote stabilization voltage V0. In the provisional error amplifier A1, the output terminal P5 is connected to the minus terminal, and the voltage of the voltage dividing resistor R6 is connected to the plus terminal.
Vi is applied. This voltage Vi is selected to satisfy the following relationship.

Vref-Vi ≒ + 0 (1) [Rated current of connector] / [Wiring resistance]> Vref-Vi (2) Let Vr be the output voltage of provisional error amplifier A1. The transistor Q of the switch circuit SW has a collector terminal connected to the plus terminal of the remote error amplifier A0, and an emitter terminal grounded. The voltage Vr is applied to the base terminal by the voltage dividing resistors R9 and R10.
Is applied via The base-emitter voltage V _BE of the transistor Q satisfies the following relationship with the control voltage V _PWM during the normal operation of the voltage CV.

V _PWM ≫V _BE (3) The output voltage Vr of the provisional error amplifier A1 is matched with the output voltage V0 of the remote error amplifier A0 via the diode D1, and is the control voltage _VPWM .

The operation of the device configured as described above will now be described. When the power supply CV is half inserted, the input terminals P1 and P2 are connected to the remote terminals P7 and P8, and the output terminal P5 and the common terminal P6 are open. The provisional error amplifier A1 outputs the output voltage Vr such that the voltage between the output terminal P5 and the remote common terminal P8 (= common terminal P6) is substantially equal to the voltage between the remote terminals P7 and P8. Since Vr> VBE, transistor Q turns on and the output voltage of remote error amplifier A0
V0 is a low voltage.

When the power supply CV is completely inserted, the voltage of the remote voltage detection terminal P7 is substantially equal to the voltage of the output terminal P5, and the voltage Vr becomes a low voltage. Therefore, the voltage Vr and the control voltage _VPWM are disconnected. Further, since Vr <V _BE , the transistor Q is turned off, and the remote error amplifier A0 is connected to the remote terminals P7 and P7.
The voltage between 8 is controlled to be equal to the reference voltage source Vref.

In the case where the load current is divided at a predetermined ratio between the operated power supplies, which is called a load share, the parallel operation control circuit can be installed in the control voltage V _PWM line. .

In the above embodiment, the transistor Q is used as the switch circuit SW. However, the present invention is not limited to this, and may be replaced with an equivalent having the same function.

<Effects of the Invention> As described above, according to the first and second inventions,
When connecting the power supply card to the system power supply line, the output voltage is controlled to be the same as the system side voltage, so excessive charging current does not flow through the smoothing diode inside the power supply, and a butt diode is not required. Thus, a redundant power supply device with high output efficiency and low heat generation can be realized.

Furthermore, according to the second aspect, since the remote terminals P7 and P8 are used, the reverse charging current of the smoothing capacitor can be prevented without increasing the number of pins of the connector.

[Brief description of the drawings]

FIG. 1 is a configuration block diagram showing an embodiment of the first invention,
FIG. 2 is an explanatory view of the pins of the connector, and FIG. 3 is a block diagram showing an embodiment of the second invention. FIG. 4 is an explanatory view of a conventional device. CV: Power supply, A, A0, A1: Error amplifier, SW: Switch circuit, P1, P2: Input terminal, P3: Voltage detection terminal, P4:
… Connection instruction terminal, P5 …… Output terminal, P6 …… Common terminal,
P7, P8 …… Remote terminals.

Claims (2)

(57) [Claims] A power supply (CV) for supplying electric power from input terminals (P1, P2) to a predetermined voltage and supplying the power to an output terminal (P5) and a common terminal (P6). While being connected to the terminal,
For the load side circuit to which the output terminal, the voltage detection terminal (P3) and the connection instruction terminal (P4) are commonly connected, the plurality of power supplies are commonly connected to the output terminal and the common terminal, and In the redundant power supply for supplying, the power supply and the load side circuit are connected, and the input terminal, the voltage detection terminal and the common terminal are connected, and then the connection instruction terminal and the output terminal are connected to the connector. An error amplifier (A) for stabilizing the voltage of the output terminal to a reference voltage; and a reference voltage of the error amplifier, the voltage of the voltage detection terminal being connected to the voltage detection terminal and being connected to the connection instruction terminal. And a switch circuit (SW) for setting a predetermined reference voltage (Vref) after connection of the connection instruction terminal, and an online maintenance circuit for a redundant power supply. 2. A power supply (CV) for supplying electric power transmitted from input terminals (P1, P2) to a predetermined voltage and supplying the electric power to an output terminal (P5) and a common terminal (P6). While being connected to the terminal,
For a load side circuit having a remote voltage detection terminal (P7) and a remote common terminal (P8), in a redundant power supply in which the plurality of power supplies are connected in common with the output terminal and the common terminal to supply an output voltage. A connector for connecting the power supply and the load-side circuit, wherein the connector to which the output terminal and the common terminal are connected after the input terminal and the remote terminal (P7, P8) are connected; A remote error amplifier (A0) for stabilizing the voltage of the remote voltage detection terminal so as to be equal to a predetermined reference voltage (Vref); and a provisional stabilization of stabilizing the voltage of the output terminal to the voltage of the remote voltage detection terminal. An error amplifier (A1), and an error amplifier for controlling the power supply device are provisional error amplifiers before the remote voltage detection terminal is connected and the connection output terminal is connected; Line maintenance circuit of the redundant power supply, wherein After connection of the child which comprises a switching circuit for a remote error amplifier (SW), a.