JPH02109110A - Constant voltage protector - Google Patents

Abstract

PURPOSE:To cut off an output voltage control part when an output current reaches a prescribed level by setting an output current detecting part between the input terminal of the output voltage control part and this part and connecting a latch control part and a latch control output part transistor TR to the output voltage control part. CONSTITUTION:The stabled DC voltage applied to an output voltage control part input terminal 4 is stabilized by a feedback amplifier consisting of an error amplifying part 3, an output voltage control part 5, an output voltage detecting resistance part 8, and a reference voltage source 7 and supplied to an output voltage control part output terminal 6. In this case, the voltage value is decided by the resistance voltages of the source 7 and the part 8 and the value of the open loop gain of the part 3. Then the output current is detected and supplied to a latch control part input terminal 14 from an output current detecting resistance 10 and an output current detecting TR 11. Thus a latch control part is latched and a latch control output TR 16 is saturated. Then the current of an error amplifying part output current source 13 is completely absorbed by the TR 16.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention The present invention relates to the structure of a protection device for a constant voltage device.

2. Description of the Related Art In recent years, constant voltage protection devices have been widely used as functional elements in all industrial fields.

An example of the above-mentioned conventional constant voltage protection device will be described below with reference to the drawings.

FIG. 3a and FIG. 4a show an example of a typical circuit of a conventional voltage regulator. In FIG. 3a, 1 is a non-inverting input terminal, 2 is an inverting input terminal, 3 is an error amplification section, 4 is an output voltage control section input terminal, 6 is an output voltage control section, 6 is an output voltage control section output terminal, 7 is a reference voltage source, 8 is an output voltage detection resistor section, 9 is an output current detection section, 1o is an output current detection resistor,
11 is an output current detection transistor, 12 is a ground terminal,
13 is an error amplifier output constant current source.

In FIG. 4a, 1 is a non-inverting input terminal, 2 is an inverting input terminal, 3 is an error amplification section, 4 is an output voltage control section input terminal, 5 is an output voltage control section, 6 is an output voltage control section output terminal, 7 is a reference voltage source, 8 is an output voltage detection resistor section, 9 is an output current detection section,
10 is an output current detection resistor, 11 is an output current detection transistor, 12 is a ground terminal, and 13 is an error amplifier output constant current source. The difference from the configuration shown in FIG. 3 is that two output voltage dividing resistors are inserted in the output current detection section. 21 is a first resistor for dividing the output voltage, and 22 is a second resistor for dividing the output voltage.

The operation of the constant voltage protection device configured as described above will be explained below.

First, in FIG. 3a, the unregulated DC voltage applied to the output voltage control section input terminal 4 is composed of an error amplification section 3, an output voltage control section 6, an output voltage detection resistor section 8, and a reference voltage source 7. By the function of the feedback amplifier, the output voltage is controlled by the output terminal 6.
is supplied with a regulated output voltage. This voltage value is determined by the voltage value of the reference voltage source 7, the respective resistance values of the output voltage detection resistor section 8, and the value of the open loop gain of the error amplification section 3.

Therefore, for the load connected to the output voltage output terminal 6,
A predetermined voltage is supplied, but since there is generally a limit to the power loss of the output voltage control section 6, the output current is limited as necessary. An output current detection section 9 is connected between the output voltage control section 6 and the output voltage control section output end 6. When the output current reaches a predetermined value, the output current detection transistor becomes active due to the voltage drop across the resistor in the output current detection section, and the output constant current source of the differential amplifier section connected to the input terminal of the output voltage control section It operates to absorb 11 currents.

The output voltage control unit output terminal 6 operates in constant current mode.

FIG. 3 shows the operating curve of the basic configuration circuit of FIG. 3a.

Next, in FIG. 4a, the operations other than the output current detection section 9 are the same as in FIG. 3a. The difference is the current detection resistor 1
0, a first resistor 21 for output voltage division, a second resistor 22 for output voltage division, and a load impedance 5 connected between the output terminal 6 of the output voltage control section and the ground terminal 13. Since a bridge circuit is formed, the smaller the load impedance, the greater the current driving capability of the output current detection transistor 11, so that it operates in a so-called holdback mode.

FIG. 4 shows the operating curve of the basic configuration circuit of FIG. 4a.

Problems to be Solved by the Invention However, in the above configuration, as shown in FIG. 3, since the output current is limited in constant current mode, the power loss of the output voltage control section is maximum, when the output voltage control The problem is that the voltage applied to the output terminal is the product of the output current, resulting in excessive power loss.In addition, in Figure 4, the output current limit operates in holdback mode. Therefore, the power loss is considerably reduced compared to the constant current mode operation shown in FIG. ), resulting in a power loss that cannot be ignored.

In view of the above problems, the present invention provides a latch control section to control the output current to a cutoff state when the output current exceeds a predetermined value, thereby ignoring the power loss of the output voltage control section. Moreover, by detecting the presence or absence of AC voltage, a constant voltage protection device that does not require a special glue set switch is provided.

Means for Solving the Problems In order to solve the above problems, the constant voltage protection device of the present invention has a non-inverting input terminal, an inverting input terminal, an error amplification section, an output voltage control section input terminal, and an output voltage control section. a control unit, an output voltage control unit output terminal, a reference voltage source connected between the non-inverting input terminal and the ground terminal, and a reference voltage source connected between the inverting input terminal and the output voltage output terminal; output voltage detection resistor section,
1. An output current detection section connected between the input terminals of the output voltage control section and the output voltage control section; a latch control section supplied with power from the input terminal of the output voltage control section; and an AC voltage input terminal; It has a complete configuration of an AC voltage detection section.

According to the configuration of the present invention, when the load connected to the output terminal of the output voltage control section exceeds a predetermined current value, the current detected by the current detection section is input to the latch control section. A latch control output transistor shuts off the output voltage control. Therefore, the power loss of the output voltage control section is
Theoretically it can be ignored. In order to release the latch state, the launch control section is equipped with a reset terminal, and the reset is activated by detecting the presence or absence of an AC signal before rectification. With this configuration, a reset operation can be realized without providing a special reset switch.

EXAMPLE Hereinafter, a constant voltage protection device according to an example of the present invention will be described with reference to the M side.

The first quotient a shows the basic configuration circuit of the constant voltage protection device in the first embodiment of the present invention. In FIG. 1a, 1 is a non-inverting input terminal, 2 is an inverting input terminal, 3 is an error amplification section, 4 is an output voltage control section input terminal, 5 is an output voltage control section, 6
is the output terminal of the output voltage control section, 7 is the reference voltage source, 8 is the output voltage detection resistor section, 9 is the output current detection section, 10 is the output current detection resistor, 11 is the output current detection transistor, 12 is the ground terminal, and 13 is the Error amplifier section output constant current source, 14 is latch control section input terminal, 16 is launch control section, 16 is latch control section output transistor, 17 is latch control section reset terminal,
18 is an AC voltage detection section, 19 is an input terminal of the AC voltage detection section,
20 is an output terminal of the AC voltage detection section.

The operation of the constant voltage protection device configured as described above will be explained below using FIGS. 1A and 1S.

First, in FIG. 1d, the unregulated DC voltage applied to the input terminal 4 of the output voltage control section is generated by the error amplification section 3, the output voltage control section 5, the output voltage detection resistor section 8, and the reference voltage source 7. A stabilized output voltage is supplied to the output terminal 6 of the output voltage control section by the function of the feedback amplifier constructed. This voltage value is determined by the voltage value of the reference voltage 9\- pressure source 7, the respective resistance values of the output voltage detection resistor section 8, and the value of the open loop gain of the error amplification section 3.

When the output current reaches a current determined by the output current detection resistor 10 and the output current detection transistor 11, a detection current flows from the output current detection transistor 11 to the latch control unit input terminal 14, and the latch control unit enters the latch state. , the latch control unit output transistor 16 becomes saturated. In this state, the current of the error amplification section output constant current source 13 is completely absorbed by the latch control section output transistor 16. Therefore, the output voltage control section is completely cut off, and the output terminal 6 of the output voltage control section becomes the ground potential. This state is a stable state because the launch control section receives the supply voltage υ from the input terminal 4 of the output voltage control section. Next, some kind of reset operation is required to return to the initial state. The AC voltage detection unit input terminal 19 is connected to one end of the AC voltage before rectification. To reset, the AC voltage detection unit output terminal 2o is cut off by cutting off the AC voltage.
This can be realized by operating the latch control unit reset terminal 17.

FIG. 1 is an operating curve of the output terminal 6 of the output voltage controller shown in FIG. 1a.

As described above, according to this embodiment, the output current detection section is provided between the input terminal of the output voltage control section and the output voltage control section, and the launch control section and the latch control section output transistor are connected to the output voltage control section. In particular, the output voltage control can be switched off when the output current reaches a predetermined current. However, by connecting the AC voltage detection unit to the reset terminal of the latch control unit, the reset operation can be realized only by the presence or absence of AC voltage.

A second embodiment of the present invention will be described below with reference to the drawings.

FIG. 2 is a basic configuration circuit of a constant voltage protection device showing a second embodiment of the present invention.

In the figure, 1 is a non-inverting input terminal, 2 is an inverting input terminal, and 3 is a non-inverting input terminal.
is an error amplification section, 4 is an output voltage control section input terminal, 5 is an output voltage control section, 6 is an inner end of the output voltage control section, 7 is a reference voltage source, 8 is an output voltage detection resistor section, 9 is an output current detection section Part, 10
is an output current detection resistor, 11 is an output current detection transistor, 12 is a ground terminal, 13 is an error amplifier output constant current source,
14 is a latch control unit input terminal, 15 is a latch control unit, 16
17 is the latch control unit output transistor, 17 is the latch control unit reset terminal, 18 is the AC voltage detection unit, 19 is the AC voltage detection unit input terminal, 20 is the AC voltage detection unit output terminal, and the following refers to the first (2). The configuration is similar to that of .

The difference from the configuration shown in FIG. 1 is that the AC voltage detection section 18 includes resistors 23, 29, 31 . The point is that a circuit configuration consisting of a capacitor 27, transistors 24, 25, 28, 32, and a constant current source 26 is used.

The operation of the constant voltage protection device configured as described above will be described below.

First, the unregulated DC voltage applied to the input terminal 4 of the output voltage control section is generated by a feedback amplifier composed of an error amplification section 3, an output voltage control section 6, an output voltage detection resistor section 8, and a reference voltage source 7. As a result, a stabilized output voltage is supplied to the output terminal 6 of the output voltage control section. This voltage value is the reference voltage source 7
, the respective resistance values of the output voltage detection resistor section 8 , and the open loop gain value of the error amplification section 3 . When the output current reaches a current determined by the output current detection resistor 1o and the output current detection transistor 11, a detection current flows from the output current detection transistor 11 to the latch control unit input terminal 14, and the latch control unit enters the launch state, and the latch The control unit output transistor 16 becomes saturated. In this state, the current of the error amplification section output constant current source 13 is completely absorbed by the launch control section output l transistor 16. Therefore, the output voltage control section is completely cut off, and the output terminal 6 of the output voltage control section becomes the ground potential. This state is a stable state because the latch control section receives power supply voltage from the output voltage control section input terminal 4.

Next, some kind of reset operation is required to return to the initial state. The AC voltage detection unit input terminal 19 is connected to one end of the AC voltage before rectification.

When AC voltage is being output, the l-run discs 2 and 4 operate in saturation for positive AC voltage.
For negative voltages, transistor 26 operates in saturation. Also, near the zero crossing of the AC voltage, there is a point in time when both of the above transistors are in a cut-off state.
At this time, charge is accumulated for a time determined by the capacitor 27 and the constant current source 26. Hold operation is possible by selecting the capacitor capacity. Therefore, in a state where an alternating current voltage is being output, transistor 28.
32 is in a cut-off state and does not reset.

Next, when the AC voltage is in a cutoff state, the potential of the AC voltage detection section input terminal 19 is at the ground potential. Therefore, the transistors 24 and 25 are in a cut-off state, and the base of the transistor 28 is driven by the current from the constant current source 26.

As a result, the transistor 32 becomes saturated, and a reset operation is realized by setting the latch control unit reset terminal 17 to the ground potential.

As described in 2 below, by providing the AC voltage detection unit 18 with a pair of transistors that can detect positive and negative polarity AC signals and a capacitor that can hold them, it is possible to detect binary states depending on the presence or absence of AC voltage. Since it is possible to create a circuit configuration that holds the latch control section, the latch control section can be reset in an alternating current voltage cutoff state by connecting it to the latch control section reset terminal.

Note that in the first embodiment, the output voltage control unit input terminal 4
The circuit is configured with the polarity of the power supply connected to the output voltage controller 5 as a positive voltage, but the output voltage controller 5
is PNP, and the output current detection transistor 11 is NPN.
The launch control unit output transistor 16 may be a PNP. Further, a field effect transistor (FET) may be used for the output voltage control section 6.

Effects of the Invention As described above, the present invention provides an output current detection section between the input terminal of the output voltage control section and the output voltage control section, and connects the latch control section and the latch control section output transistor to the output voltage control section. By connecting, when the output current reaches a predetermined current, the output voltage control section can be placed in a cut-off state. In addition, by connecting the AC voltage detection section to the launch system 16 and the row section reset terminal, the AC voltage ('
] Since the reset operation can be realized only by using no setting switch, there is no need to provide a special set switch.

[Brief explanation of the drawing]

Fig. 1 is a basic configuration circuit diagram and its operating curve diagram of a constant voltage protection device according to a first embodiment of the present invention, and Fig. 2 is a basic configuration circuit diagram of a constant voltage protection device according to a second embodiment of the present invention. , FIG. 3 is a basic configuration circuit diagram of a conventional constant voltage protection device and its operating curve diagram, and FIG. 4 is a basic configuration circuit diagram of a conventional constant voltage protection device and its operating curve diagram. DESCRIPTION OF SYMBOLS 1...Non-inverting input terminal, 2...Inverting input terminal, 3...Error amplification section, 4...Output voltage control section input terminal, 6. ...Output voltage Tsukuda control section, 6
...Output voltage control unit output end, 7...Reference voltage source, 8...Output voltage detection resistor section, 9...
... Output current detection section, 10 ... Output current detection resistor, 11 ... Output current detection transistor, 1
2...Ground terminal, 13...Error amplifier section output constant current source, 14...Latch control section input terminal, 15...Latch control section, 16 ...Latch control unit output transistor, 17...Latch control unit reset terminal, 18...AC voltage detection unit, 1
9... AC voltage detection section input terminal, 20...
・AC voltage detection part protruding end. Name of agent: Patent attorney Shigetaka Awano and one other person Tsukasa Tsuka “N = 105

Claims (1)

[Claims] Between the non-inverting input terminal, the inverting input terminal, the error amplification section, the output voltage control section input terminal, the output voltage control section, the output voltage control section output terminal, and the non-inverting input terminal and the ground terminal. a connected reference voltage source, an output voltage detection resistor connected between the inverting input terminal and the output voltage output terminal, and a connection between the output voltage control section input terminal and the output voltage control section. an output current detection section connected to the output terminal of the output voltage control section; a latch control section supplied with power from the input terminal of the output voltage control section; an AC voltage input terminal; and an AC voltage detection section connected to the output terminal of the output voltage control section. When the load exceeds a predetermined current value, the output current detection unit detects the current, and the latch control unit sets the output voltage control unit to a cutoff state, and the AC voltage at the AC voltage input terminal is cut off. and a constant voltage protection device, wherein the AC voltage detection section resets the latch control section.