JPH06289943A - Load protection device - Google Patents

Abstract

PURPOSE:To protect a load under different conditions and to unnecessitate exchange by detecting current flowing in the prescribed load, giving an excessive characteristic to output obtained by powering the detected quantity with a prescribed exponent so as to convert it, comparing the converted output with prescribed quantity and breaking current. CONSTITUTION:Current i<2> output from an X-Y multiplier 12 through a resistance 11 is supplied to a comparator 19 through a low pass filter 15 and it is compared with rated current Ic<2>. While current i<2> is less than rated current Ic<2> a '1' signal is inputted from the comparator 19. Thus, the '1' signal is supplied to the R-terminal of FF 22 and the '1' signal is outputted from the output terminal Q, FET 23 is left in an on state as it is and current continuously flows through the load 24. When current i<2> reaches rated current Ic<2>, a '0' signal is outputted from the comparator 19. Thus, logic '0' is supplied to the input terminal R of FF 22 and it is reset. The '0' signal is outputted from the output terminal Q, FET 23 becomes an off state and current does not flow through the load 24.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a load protection device for preventing an excessive current from flowing through a load inserted in an electric circuit.

[0002]

2. Description of the Related Art As is well known, a fuse inserted in an electric circuit melts and cuts off a circuit when a current larger than a specified current flows, thereby preventing an excessive current from flowing through a load.

[0003]

By the way, in general, such a fuse has a large variation in quality, the accuracy is not guaranteed, the characteristic deteriorates due to long-term use, it takes time to replace it, and it is expensive. Has the drawback of. Also,
The fusing characteristic is unique, and it is impossible to change the breaking condition each time according to the characteristics of the circuit. The present invention has been made in view of the above-mentioned circumstances, and an object of the present invention is to provide a load protection device which does not require replacement and whose breaking characteristics can be changed.

[0004]

In order to solve the above problems, according to the present invention, a detecting means for detecting a current flowing through a predetermined load and a detection amount of the detecting means are raised to a power of a predetermined exponent. A current control for comparing the output of the calculating means for outputting, a converting means for giving a predetermined transient characteristic to the output of the calculating means, the output of the converting means and a specified amount, and for interrupting the current when the output exceeds the specified amount. And means.

[0005]

According to the above construction, the current flowing through the predetermined load is detected by the detecting means. Then, the calculating means exponentiates the detection amount of the detecting means by a predetermined exponent and outputs the result, and the converting means gives a predetermined transient characteristic to the output. Then, the current control means compares the output of the conversion means with the specified amount, and when the output becomes equal to or more than the specified amount, the current is cut off. Therefore, it becomes possible to protect the load under different conditions depending on the power condition of the calculation means, the transient characteristic of the conversion means, and the specified amount to be compared.

[0006]

Embodiments of the present invention will be described below with reference to the drawings.

§1. First Embodiment FIG. 1 is a block diagram showing the configuration of a load protection device which is an embodiment of the present invention. In the figure, reference numeral 1 is a current detector that detects a current flowing through the circuit, and is specifically a resistor or various sensors. By the way, the time (t) -current (i) characteristics of the conventional physical fuse are as follows when a certain time T _B is satisfied, in the case of t << T _B ... i ² t = A (constant) t >> T _B In the case of, it is known that i = I _c (fuse rated current value). The following elements are provided to simulate such a characteristic.

Reference numeral 2 is an n-th power calculator that outputs the input value raised to the nth power, and 3 is a general first-order low-pass filter.
The transfer function H (s) related to the Laplace transform of such a low-pass filter is generally represented by a time constant τ,

[Equation 1] Is expressed as Further, n coefficient "n" th power calculator can be arbitrarily set, for example, set to "2", these n-th power multiplier 2, by a low-pass filter 3, to the input value i ² of the physical fuse The characteristic is simulated.

[0009] Then, 4 is a precomputed comparator for outputting binary by comparing the outputs of the n power and the low-pass filter 3 of the rated current value I _c, large better the rated current value Ic ⁿ If so, the value “TRUE” is output, and otherwise, the value “FALSE” is output. Reference numeral 5 is an output holder having a function of holding a predetermined value supplied from the comparator 4. Once the value “FA
When "LSE" is supplied, the value "FALSE" is continuously output unless a reset signal is supplied from the outside. Also,
Reference numeral 6 denotes a cutoff switch interposed between the circuits, and the on / off state is switched by an output signal supplied from the output holder 5. Here, the output signal is the value "TRU
If "E", it is turned on, while the value "FALSE"
In the case of, the circuit is turned off and the circuit is cut off.

In the configuration of FIG. 1, the coefficient n in the n-th power calculator 2 is set to "2", and the current i (t) which is a staircase wave is set.
The operation when (FIG. 4 (A)) is supplied to the current detector 1 will be described. The staircase wave i (t) suddenly becomes 0 at time t = 0.
Becomes a constant i. First, the current output from the current detector 1 i (t) is supplied is the current i ² (t) to the low-pass filter 3 by the n-th power calculator 2. Then, the output of the low-pass filter 3 is supplied to the comparator 4 and compared with the rated current value Ic ² .

FIG. 4B is a diagram showing the time change of the output lp (t) of the low-pass filter 3. As shown,
The output lp (t) gradually rises with the passage of time, and becomes equal to the rated current value Ic ² at the time t _c . That is, before time t _c , the value “TRUE” is output from the comparator 4 and supplied to the output holder 5. Then, the value “TRUE” is supplied from the output holder 5 to the cutoff switch 6, so that the cutoff switch 6 is turned on.
The circuit is connected.

Then, as shown in FIG. 4C, the value "FALSE" is output from the comparator 4 at the moment when the time reaches "t _c ".
Is output and is supplied to the output holder 5. Then, when the value “FALSE” is supplied from the output holder 5 to the cutoff switch 6, the cutoff switch 6 is turned off,
The circuit is broken.

Here, the relationship between the current value i ² and the interruption time tc shown in FIG. 4B is derived by using the Laplace transform method. As described above, since the current i (t) is a step wave, the current value i is constant and the current value i ² is also constant. In this case, the s-function related to the Laplace transform is "I ² (s) = i ² /
s ". The output Lp (s) of the low-pass filter 3 is given by the s-function and the transfer function (equation (1)) of the low-pass filter 3 described above.

[Equation 2] Is expressed as Next, the equation (2) is subjected to the inverse Laplace transform to obtain the relationship as shown in the following equation (3).

[Equation 3]

Here, at time t = tc (cut-off time), the output lp of the low-pass filter 3 as described above.
(T) becomes equal to Ic ² (square of rated current value). Therefore, substituting these into equation (3),

[Equation 4] Is derived. Then, by modifying the equation (4),

[Equation 5] Then, the equation (5) shows the ratio between the rated current value Ic and the current i at the time t = tc. In FIG. 5, the abscissa represents the "cutoff time / time constant" (tc / τ), and the ordinate represents the current ratio (i
/ Ic), the actual measurement value (solid line) of the conventional fuse and the simulation value (broken line) by the equation (5) are compared.

Further, the coefficient in the n-th power computing unit 2 is "n".
Similarly, when determining the relationship between the cutoff time tc and the current value i ⁿ when a,

[Equation 6] Is derived. Similar to FIG. 5, FIG. 6 shows changes in the current ratio (i / Ic) at different values n with respect to the horizontal axis tc / τ on the vertical axis. As shown in the figure, the solid line (n =
Compared to 2.0, broken line 1 (n = 1.0), broken line 2 (n =
In 0.5), the curve is gradually steep. The value n is
It may be set according to the application of the circuit. For example, in the case of a circuit having a large inrush current and a small steady-state current, n = 1.0 is better than general n = 2.0. It is suitable.

FIG. 2 is an example in which the block configuration of FIG. 1 is embodied mainly in analog technology. In the figure, the resistor 11 detects the current flowing through the load 24. The XY multiplier 12 outputs the result of multiplying the X and Y inputs. The resistor 13 and the capacitor 14 form a primary low-pass filter 15. Reference numeral 19 is a comparator, which compares the rated current Ic ² set by the power supply 18 and the resistors 16 and 17 with the output of the low-pass filter 15. When the rated current Ic ² is larger, “1” is given. Signal, otherwise outputs "0" signal. Then, this output is an RS flip-flop (hereinafter abbreviated as FF).
22 is supplied to the reset terminal R.

A control signal from a microcomputer (not shown) is supplied to the set terminal S of the FF 22. From the output terminal Q of the FF22, the reset terminal R
A signal corresponding to the state of the set terminal S is output.
Then, the field effect transistor (hereinafter, abbreviated as FET) 23 is turned on or off by this output signal.

In the above structure, the FF 22 is set in advance by a control signal from the microcomputer. The current i ² output from the XY multiplier 12 via the resistor 11 is supplied to the comparator 19 via the low pass filter 15 and compared with the rated current Ic ² . Here, while the current i ² is equal to or less than the rated current Ic ² , the comparator 19 outputs the “1” signal. Therefore, the "1" signal is supplied to the R terminal of the FF22, and the "1" signal is supplied from the output terminal Q
The 1 "signal is output. That is, the FET 23 remains in the ON state, and the current continues to flow in the load 24.

On the other hand, when the current i ² reaches the rated current Ic ² , the comparator 19 outputs a "0" signal. Therefore,
The logic "0" is supplied to the input terminal R of the FF22 and the FF2
2 is reset, and the output terminal Q outputs a "0" signal. That is, the FET 23 is turned off, the circuit is cut off, and no current flows through the load 24. To reconnect the circuit, the FF 22 may be set again by the control signal from the microcomputer.

The load protection device described above may be used in combination with a conventional physical fuse so that the circuit is cut off before the physical fuse is blown. As a result, even when the reliability of the elements forming the load protection device is not sufficiently high, the function as a dual safety device against a load can be expected.

§2. Second Embodiment FIG. 3 shows an embodiment of the present invention, which is configured as a digital circuit. In the figure, the controller 30 produces a control output i proportional to the current flowing through the load 47.
The squarer 31 squares the input data and outputs it. Also,
The delay calculator 34 delays the input data by a predetermined time and outputs it. The multipliers 33, 35 and 36 respectively multiply the input data by a predetermined coefficient and output it to the adders 32 and 37. Each of these adders, delay calculators, and multipliers constitutes a first-order digital low-pass filter 38 as a whole.

A sign inverter 39 outputs data obtained by inverting only the positive and negative signs of input data. Further, 41 is an adder, which adds the sign inverter 39 and the rated data Ic ² supplied from the outside. Reference numeral 42 is a sign discriminator that outputs a binary signal depending on whether the input data is positive or negative, and outputs a "1" signal if it is positive and a "0" signal if it is negative. The sign inverter 39, the adder 41, and the sign determiner 42
The comparator 43 is configured to compare the output of the low-pass filter 38 and the rated data Ic ² .

Reference numeral 44 is a multiplier, which multiplies the input data (control output i) by the output of the comparison section 43 and outputs the result. That is, when the comparator 43 supplies the multiplier 44 with the "1" signal, the input data is output as it is, but when the "0" signal is supplied, "0" is output. Reference numeral 45 denotes a PWM (pulse width modulation) generator, which controls the conduction state of the FET 46 by a pulse signal whose pulse width is modulated according to the output of the multiplier 44. This controls the current flowing through the load 47.

In the above structure, the control output i output from the controller 30 is squared by the squarer 31 and supplied to the low-pass filter 38. The output of the low-pass filter 38 is the rated data Ic ² in the comparison unit 43.
Compared to. While the output of the low-pass filter 38 is equal to or less than the rated data Ic ² , the comparison unit 43 outputs the “1” signal, so that the control output i is supplied to the PWM generator 45 via the multiplier 44 and is supplied to the control output i. The current flowing through the load is controlled accordingly.

On the other hand, when the output of the low pass filter 38 becomes the rated data Ic ² or more, "0" is output from the comparison section 43. As a result, the FET 46 is turned off via the multiplier 44 and the PWM (pulse width modulation) generator 45, and no current flows through the load 47. In order to reconnect the circuit, the controller 30 may supply an appropriate control output i.

Unlike the conventional fuse, the embodiment described above is electronically cut off, so that the breaking accuracy is improved, it is less affected by the ambient temperature, and the characteristic deterioration due to long-term use is hardly seen. . Therefore, there is an advantage that the cost performance is improved as it is repeatedly used.

[0027]

As described above, according to the present invention, different conditions are caused depending on the power condition of the calculating means, the transient characteristic of the converting means, and the size of the specified amount compared by the current controlling means. It is possible to protect the load with, and it is possible to obtain a load protection device that does not require replacement and whose breaking characteristics can be changed.

[Brief description of drawings]

FIG. 1 is a diagram showing a block configuration of a load protection device according to a first embodiment of the present invention.

FIG. 2 is a diagram showing a configuration of a load protection device according to a first embodiment of the present invention.

FIG. 3 is a diagram showing a configuration of a load protection device according to a second embodiment of the present invention.

FIG. 4 is a diagram showing a simulation example of a fuse in the first embodiment of the present invention.

FIG. 5 is a diagram showing a simulation result of a fuse in the first embodiment of the present invention.

FIG. 6 is a diagram showing various simulation results in the first embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 current detector (detection means) 2 n power calculator (calculation means) 3 low-pass filter (conversion means) 4 comparator (current control means) 5 output holder (current control means) 6 cutoff switch (current control means) 11 Resistance (detection means) 12 XY multiplier (calculation means) 15 Low-pass filter (conversion means) 19 Comparator (current control means) 22 RS flip-flop (current control means) 23 FET (current control means)

Claims (1)

[Claims] 1. A detection means for detecting a current flowing through a predetermined load, a calculation means for exponentiating a detection amount of the detection means by a predetermined exponent, and outputting the output of the calculation means with a predetermined transient characteristic. A load protection device comprising: a conversion unit; and a current control unit that compares the output of the conversion unit with a specified amount and shuts off the current when the output exceeds a specified amount.