JPS62260518A - Overcurrent protecting circuit - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed Description of the Invention] (Field of Industrial Application) The present invention applies to overcurrent protection circuits, and more specifically, the overcurrent that enters the signal transmission path of telephones etc. due to lightning surge or induction is applied to loads of various communication equipment, etc. The present invention relates to an overcurrent protection circuit that prevents overcurrent from flowing into the circuit.

(Prior art and its problems) Conventionally, the elements used for this type of overcurrent protection are:
Fuses, heat coils, and PTCs (positive characteristic thermistors) are known to be connected in series to the signal transmission path.

However, all of these overcurrent protection elements utilize the temperature rise that occurs when a current of a certain magnitude or more continues to flow for a certain period of time, and they operate based on the accumulation of current and time. Therefore, the response speed is generally slow, and as a result, an overcurrent continues to flow through the load for a long time.

On the other hand, a method has been proposed in which an overvoltage protection element such as an arrester is connected in parallel with the load to provide overcurrent protection, but since the operating voltage of the overvoltage protection element cannot be set below the so-called operating voltage, this is especially true for low-impedance loads. However, there was a problem in that an overcurrent flows to the load side before the overvoltage protection element operates, resulting in insufficient protection of the load.The present invention was proposed to solve the above problems. The purpose of this is to detect overcurrent that has flowed into the signal transmission path, and use the output signal to bypass the overcurrent to a low impedance side other than the load, thereby increasing responsiveness and connecting to a low impedance load. To provide an overcurrent protection circuit that can provide reliable overcurrent protection even when used in a conventional overcurrent protection device such as a fuse, heating coil, PTC, etc. It is in.

(Means for Solving the Problems) In order to achieve the above object, the present invention first connects an overcurrent detection circuit 1 in series between terminals L L IL2 forming a signal transmission path as shown in FIG. . Here, the terminal LL indicates the line side, and the terminal L2 indicates the load side.

Next, an overcurrent bypass circuit 2 that closes the switch element by the output signal from the overcurrent detection circuit 1 and bypasses the overcurrent is connected to the zero point between the point X on the signal transmission path and the terminal L3. Alternatively, it may be located on the terminal L□ side or the terminal □ side of the overcurrent detection circuit 1.

One end of a load is connected to terminal L2, and terminal L2 is connected to the other end of the load. For example, when the load is connected between the lines of the signal transmission line, the overcurrent bypass circuit 2
is connected between the lines and is connected to the terminal.

is connected to the signal transmission path that forms a pair with the terminals L1 and L2. Further, for example, when a load is connected between the signal transmission path and the ground, the overcurrent bypass circuit 2 is connected between the ground and the terminal L3 is grounded.

With this configuration, the intended purpose of the present invention is achieved, but as shown in FIG. It is also possible to connect a conventional overcurrent protection element 10 such as a fuse, heat coil, or PTC.

(Function) In the configuration shown in FIG. 1, when an overcurrent flows into the signal transmission line from the terminal L1 on the line side, the overcurrent detection circuit 1 detects this and sends an output signal to the overcurrent bypass circuit 2. do. In the overcurrent bypass circuit 2, this output signal closes internal switching elements such as relay contacts and transistors, thereby bypassing the overcurrent to the terminal L1 side. This prevents overcurrent from flowing into the terminal L2 on the load side.

In addition, in the configuration shown in FIG. 2, the functions of the overcurrent detection circuit 1 and the overcurrent bypass circuit 2 are the same as in the case of FIG. The overcurrent is ultimately cut off by blowing the fuse, operating the heating coil, or high resistance of the PTC.

(Example) The present invention will be described in detail below with reference to the drawings.

First, FIG. 3 shows a first embodiment of the present invention. In the figure, 3 is a current transformer inserted into the signal transmission path, and a relay coil 4 is connected to the output end of the current transformer. The current transformer 3 and relay coil 4 constitute an overcurrent detection circuit 1. The overcurrent bypass circuit 2 includes a contact 4a that is closed when the relay coil 4 is energized, and both ends of the contact 4a are connected to a point and a terminal, respectively. It is also assumed that terminal L2 is connected to one end of the load, and terminal L2 is connected to the other end of this load.

Its operation is such that a constant current flows through the current transformer 3 due to the inflow of overcurrent into the signal transmission path, and the contact 4a of the relay coil 4 closes, bypassing the overcurrent from the terminal L1 to the terminal side. . Therefore, if you connect the terminal RI to the other end of the load,
The overcurrent will escape to the other end of the load through the overcurrent bypass circuit 2 without flowing into the load from the terminal L2.

Next, FIG. 4 shows a second embodiment of the present invention, in which signals are exchanged between the overcurrent detection circuit 1 and the overcurrent bypass circuit 2 using a photocoupler. Also, as shown in Figure 2, fuses and heating coils,
It also includes an overcurrent protection element 10 such as PTC.

Note that an overvoltage protection element such as an arrester Arr may be further provided in the preceding stage (on the line side) of the overcurrent protection element IO. In Figure 4, an arrester Arr with a fail-safe function that shorts out when heated is used as this overvoltage protection element.
This shows the case where .

That is, in the figure, Li□, L21 are terminals on the line side,
L engineering 2. L2□ is a terminal on the load side, and for example, a PTC5 as an overcurrent protection element 10 is connected between terminals L1 and L11.
a and a resistor R□ are connected in series. Here, the point x1 between the resistor R and the terminal L1□ is
Indicates the connection point corresponding to point X in the diagram (point x2 in the diagram
(The same applies to) A series circuit of a light emitting diode (LED) and a light emitting diode (LED) connected in antiparallel to the resistance R2 is connected to both ends of the resistor R1.

An overcurrent detection circuit 1 is configured by the LED 2.

Note that these overcurrent protection element 10 and overcurrent detection circuit 1 are also connected between the other terminals L x t t L z i, and the components thereof are PTC5b, resistor R1゜R49 light emitting diode LED, , LED4 It is.

On the other hand, as the overcurrent bypass circuit 2, terminals L1□, L
2□, diodes D1 to D6 are connected to form a bridge, and phototransistors T1. T,
, T, , T4, and a phototransistor T□
is a light emitting diode LED, and phototransistor T2 is a light emitting diode LED.

The phototransistor T is a light emitting diode LED.

Furthermore, the phototransistor T4 is a light emitting diode LED4.
and each constitute a photocoupler. Note that the terminal E is grounded, for example.

In this example, the terminals L 1 L t L 2
L and the ground terminal E, even if an overcurrent enters from any direction, the phototransistor element or T2. The collector and emitter of T, , T are conductive, and the overcurrent is L□1→x1→D→T□
~T4→D6→E route, or E→D.

→ T1 to T4 → D3 → x1 → L engineering, or L2
□ → X2 → D2 → T □ ~ T4 → D6 → E route, or E → D5 → T □ ~ T4 → D4 → X2 → L21 route, or, -+ X1 → 1) 1-+ 'r □-T, -+
D44
Since the current is bypassed through the first path, there is no possibility that this overcurrent will flow into the load side.

Although not shown, an effective bypass circuit can be constructed by appropriately connecting a Darlington transistor or the like to the phototransistor in order to lower the impedance and increase the current capacity of the bypass circuit.

(Effects of the Invention) As described above, according to the present invention, the overcurrent detection circuit detects a certain overcurrent and immediately bypasses the load.
Compared to conventional overcurrent protection devices that utilize the temperature rise caused by the accumulation of current and time, the response can be dramatically improved and the load can be reliably protected. .

Further, even for a low impedance load, it is possible to eliminate the inconvenience that an overcurrent flows before the overcurrent protection element or the like operates.

Furthermore, by using the present invention in combination with a conventional overcurrent protection element, the operation of the overcurrent protection element can be ensured, and the load can be more reliably protected from overcurrent.

[Brief explanation of drawings]

FIGS. 1 and 2 are block diagrams showing a schematic configuration of the present invention, and FIGS. 3 and 4 are circuit diagrams showing first and second embodiments of the present invention, respectively. 1... Overcurrent detection circuit 2... Overcurrent bypass circuit 10... Overcurrent protection element

Claims (1)

[Claims] An overcurrent detection circuit that detects overcurrent flowing into the signal transmission path, and an overcurrent bypass that operates to bypass the overcurrent to a low impedance circuit connected in parallel with the load based on the output signal of the overcurrent detection circuit. An overcurrent protection circuit characterized by comprising a circuit.