JPH0789706B2 - Overcurrent relay - Google Patents

Description

Description: TECHNICAL FIELD OF THE INVENTION The present invention relates to an anti-time limit overcurrent relay used for overload protection.

[Technical Background of the Invention] In recent years, various types of devices have been proposed for overload protection of electric power devices such as electric motors and transformers, transmission lines, and the like by using integral calculations by electronic devices. For example, the electronic overload protection device proposed in Japanese Patent Laid-Open No. 56-1728 integrates the square of the current value I ² during a time t _{n after} the current value I exceeds a predetermined value. , Its integral Will operate when the value exceeds the planned value.

Further, in Japanese Patent Application No. 60-122734, a value KI ² proportional to the square of the current value is calculated, and the calculated value is used to add the following equation to obtain S _n = K ′ (KI ² −S _{n -1} ) + S _n-1 (1) where S _n is the added value, S _n-1 is the calculated value up to the previous addition, K and K ′ are positive constants, and the added value S _n is greater than or _equal to a predetermined value. Then, one that works will be proposed.

Further, although it is not known by the applicant, the value of the value KI ² of the equation (1) is overloaded and the current of the part is:
A function f (I) that simulates the temperature rise characteristic has been proposed.

[Problems of the Background Art] All of the above proposals operate when the integrated value or the added value exceeds a predetermined value. This principle is suitable for protection in the case where the circuit breaker is tripped to cut off the current and flow into the protected portion when the temperature of the protected portion reaches the limit value. However, it is not always suitable for overload protection in which various operations or controls are performed before the temperature reaches the limit value.

That is, when the auxiliary electric motor of the power plant is overloaded and cannot handle the overload, it is desirable to gradually reduce the output of the generator to transfer the load to another generator and then stop the generator. . If it is stopped at full output operation, it will cause a large disturbance to the power system, and in the worst case, it may even collapse the system.

Also, in the case of overload protection of transformers and transmission lines, overload is eliminated by adjusting the output of the generator that is connected to the protected part or switching the system part that supplies the load. It is desirable to make it possible, and even in the case where it is unavoidable, it is desirable to prevent the overload portion from being cut off by eliminating the overload of the overload portion by limiting the load (cutting off a part of the load).

These operations or controls require a considerable amount of time. Therefore, in the above-mentioned proposal, the integrated value or the added value is a value sufficiently lower than the value L _t corresponding to the temperature rise limit value of the protected portion.
It will be operated when it exceeds L _c . Problems in this case will be described with reference to the drawings.

FIG. 8 shows the operating time characteristics of the relay. The horizontal axis shows the current value I and the vertical axis shows the operating time T ₀ . The curve L _t shows the operating time characteristic when the operating value of the integrated value or the added value of the relay is a value L _t (referred to as operating value) corresponding to the limit value of the temperature rise of the protected part. The curve L _c is the characteristic when the operation time of the actual operation of the relay, that is, the operation value of the integrated value or the added value is the actual value L _{c for} control (referred to as the control value). The curve T _p will be described later.

Now, when the current value is I _k as shown in the drawing, it is attempted to operate the relay earlier than the time when the temperature rise of the protected portion reaches the limit value (referred to as the limit value arrival time) by a certain time T _n required for control. To do. Then, when the current value is smaller than I _k , the relay operates at a time sufficiently earlier than the fixed time T _n , and the control starts unnecessarily quickly. Unnecessarily fast control is not preferable, especially in the case of load shedding. On the other hand, when the current value is larger than I _k , there is no margin for the time T _n , and a sufficient control time cannot be secured.

Further, FIG. 9 (a) is a diagram showing an example of the change of the integral value or the added value S _n of the relay with respect to the time t, and the vertical axis shows the integrated value or the added value S _n and the operating value L _t and the control The value L _c is shown, and the time t is shown on the horizontal axis. At time t ₀ , overload occurs, and at times t ₁ , t _2, and t ₃ , first, second, and third controls for overload elimination are performed. As a result, the integrated value or the added value S _n follows changes such as the curves k ₀ , k ₁ , k ₂ , k ₃ and k ₄ , and when this value is the control value L _c or more, control for reducing the load can be performed. Done.

The curve k ₁ is a rapid temperature increase, and the integrated value or the added value S _n rapidly reaches the increase limit value L _t, and therefore the control at the time t ₁ is considered to be appropriate. However, the curve k ₂ shows a gradual temperature rise, and the second control is performed at the time t ₂ although the margin time for the control is sufficient. This control is often unfavorable in general.

That is, this kind of control is generally a cut-off of a part of the load (hereinafter referred to as a load limit), which hinders supply to a part of the load. On the other hand, if there is enough time, the system will be switched (for example, if the transformer is overloaded, some loads will be switched to supply from other substations without interruption of power), reduction or stop of special demand load Since there is a means for starting the generator, which has been done, it is often possible to eliminate the overload without hindering the supply to the general load.

However, it is necessary to know that there is a sufficient margin for such control. Furthermore, the curve k ₃ after time t ₂
Is changing toward the operating value L _t , which is the rising limit value, or less, but the control at time t ₃ is performed.

[Object of the Invention] The present invention has been made to solve the above problems, and an object of the present invention is to provide an overcurrent relay that can operate at the most appropriate operation time for control such as overload elimination. Has an aim.

SUMMARY OF THE INVENTION The present invention obtains a value corresponding to an input current value I of a function f (I) that simulates a current-temperature rise characteristic of a power device or a power line that receives a current as an input, and obtains this function f. The addition term including the value of (I) is added, the addition processing is performed to calculate the addition value S _n , and at least one of the current value of the function f (I) or the current value I and the addition value are used. , Predetermined time t _p
The value of the subsequent added value S _n is predicted and calculated, and this is set as the predicted value P _p , and when this predicted value P _p satisfies the predetermined condition,
An operation output is generated.

As a result, for example, it is possible to obtain an anti-time limit overcurrent relay that operates before the scheduled time when the added value S _n reaches the rising limit value, and it is possible to perform appropriate overload protection for the control margin time. You can

[Configuration of First Embodiment] A first embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a diagram showing a hardware configuration of an embodiment of an overcurrent relay according to the present invention. In the figure, reference numeral 1 is an input converter for inputting an alternating current of a protected portion and generating an alternating voltage ₁ proportional thereto. 2 is a data acquisition unit (DAU),
The voltage ₁ is sampled at the scheduled period, and the data D ₂ proportional to the sampled value is generated. Reference numeral 3 denotes a processing device (CPU) which takes in the data D ₂ and performs the processing described later, and produces an output E ₃ according to the processing result. The output E ₃ may be a single output, or may be a plurality of types depending on the processing content. Since such a configuration is similar to that of a general digital relay, detailed description thereof will be omitted.

FIG. 2 is a flowchart showing the processing contents of the processing device 3.
When the relay is activated, first, the initial processing 4 is performed. The contents will be described later.

Next, the function value process 5 is performed to calculate the value of the function f (I) that simulates the current-temperature rise characteristic, which corresponds to the magnitude I of the input current. Then, in addition processing 6, the function f (I)
The added value S _n is calculated using the value of. Further, in the prediction process 7, the addition value S _n and the value of the function f (I) are used to detect whether or not there is a condition that satisfies the prediction value S _p of the addition value after the scheduled time T _p . If the condition is not satisfied, the detection result is N
Then, the process returns to the process 5, and the above process is repeated. When in the condition satisfying a predetermined condition, the detection result as a Y, after issuing the output E ₃ output processing 8, returns to the process 5. In the initial processing 4, an appropriate value is given to the added value S _n .

FIG. 3 is a flow chart showing details of an embodiment of the function value processing 5. First, in process 5-1, the data D ₂ is read, and the value of the function f (I) is calculated by the following equation using this data.

f (I) = K ₁ I ² (2) where is a value representing the magnitude of the amplitude, effective value, average value, etc. of the current I, and is hereinafter referred to as current value. K ₁ is a positive constant.

For example, there are the following calculation methods.

I ² = X ₀ ² + X _-3 ² (3) However, X ₀ is the latest sample, and X _-3 is the data at the sample 90 ° before X ₀ .

Reference (1) indicates that the expression (3) represents the square of the current value I.
(The Institute of Electrical Engineers of Japan, Protection and Relay Engineering, 1981) 11
The description is omitted for simplicity because it is shown in Table 6.2 on page 2.

In addition to the above, there are various means for calculating I ² .

FIG. 4 is a flow chart showing the contents of the addition process 6. First, in process 6-1, the added value S _n is stored as S _n−1 , and process 6
At -2, the added value S _n is calculated by the following equation using the stored value S _n-1 and the function value f (I) obtained in the process 5.

_{S n = K 2 {f (} I) -S n-1} + S n-1 ... (4) where, K ₂ is 0 <K ₂ "in 1 becomes constant, usually, (However, t _d is the interval of addition time, τ is the time constant of the protected part).

FIG. 5 is a flowchart showing the content of the prediction process 7. First, in process 7-1, the added value S _n obtained in process 6 is used as the predicted value.
M = 0 of P _m (where m is a subscript indicating a predicted value after time m)
The predicted value (P _m ) at _m is stored as _{m = 0} .

Then, in process 7-2, the value of the following equation is calculated.

P _{m + 1} = K ₃ {f (I) −P _m } + P _m (5) where P _m is the predicted value after time mt _Δ (where t _Δ is a fixed time), and the first time In the addition, m = 0, and in the second addition, m = 1. P _{m + 1} is time m +
The predicted value after 1, K ₃ is a constant such that 0 <K ₃ << 1, (However, τ is the time constant of the protected part).

Subsequently, in process 7-3, it is detected whether or not the value of the predicted value P _{m + 1} satisfies the condition of the following equation.

P _{m + 1} ≧ L _t (6) where L _t is an operation value and a positive constant (6) is satisfied, the detection result is set to Y, and the detection result of the process 7 is set to Y. When the expression (6) is not satisfied, the detection result is set to N, and the process proceeds to processing 7-4. In processing 7-4, 1 is added to the value of m to set m + 1 as a new value of m, and
The value of P _{m + 1 in} the equation (5) is set as a new value of P _m . Further, in processing 7-5, it is detected whether or not the new value of m satisfies the condition of the following equation.

m ≧ P (7) where P is a positive integer constant.

If the expression (7) is satisfied, the detection result of the process 7-5 is set to Y, and the detection result of the process 7 is set to N. If the expression (7) is not satisfied, the detection result in the process 7-5 is set to N, the process returns to the process 7-2 and the above is repeated.

The processing of the prediction processing 7 is summarized as follows. The predicted value is calculated one after another as in the following equation.

If the values become _{equal to} or greater than the operation value L _t in the process of successively calculating the predicted values by the equation (8), the detection result of the process 7 becomes Y. If the predicted value P _p does not reach the operation value L _t , the detection result of the process 7 is N.
Becomes In short, the predicted value P _p is the value of the added value S _n after the time p when the current value I continues.

If the detection result of the prediction process 7 is Y, the process proceeds to process 8, outputs E _3, and then returns to the function value process 5. If the detection result of the prediction process 7 is N, the process returns to the process 5 without performing the process 8. After returning to the process 5, the above process is repeated.

Finally, the initial processing 4 will be described with reference to the drawings. FIG. 6 is a flow chart showing the contents of the initial processing 4, and the same portions as those in FIG. 3 are indicated by the same symbols. First, similarly to the process 5, the current value I
The value of the function f (I) corresponding to is calculated. Subsequently, in process 4-1, the value of the function f (I) is directly used as the value of the added value S _n . It should be noted that this process is an initial process for the value of the addition value S _n and is included in the addition process 6, but is divided and described as the initial process for convenience of explanation.

[Operation of First Embodiment] Next, the operation of the first embodiment will be described with reference to the drawings.

When the relay is activated, the additional value S _n is set to the value of the function f (I) corresponding to the current value I at the time of activation by the initial processing 4. As is clear from the equation (4), the set value is an added value when the current value I is constant for a long time, and also simulates the temperature rise of the protected portion in this case. Is. Such a procedure is considered to provide the most appropriate protection when the relay is activated after a momentary interruption of the control power supply when the protected part has a small load fluctuation such as a large transformer.

FIG. 7 is a diagram for explaining the response of the first embodiment, and the horizontal axis shows time t. For simplicity, the change of the current value I is stepwise. Until time t ₀ , the current value I is constant for a long time and f (I) = S _n , so the value of the function f (I) is
The added value S _n and the predicted value P _p are equal. When the value of the function f (I) increases as shown in the figure from the time t _{0 in the} overload state, the added value S _n increases with an exponential function that gradually approaches the value of the function f (I). The predicted value P _p indicates the value of S _n after the time pt _Δ when this current value is supposed to continue, and precedes the value of S _n by the time pt _Δ as illustrated. The value of the predicted value P _p reaches the operating value L _t at time t ₁ . Although not shown, the output E ₃ is generated at this time. If overload continues, add
S _n and the predicted value P _p continue to increase.

The operating time (time to generate the output E ₃ ) T ₀ when the current value I is kept at zero for a long time and then changes to a certain constant value is shown by a broken line E ₃ in FIG. In the figure, the solid line L _t is the time when the added value S _n reaches the operating value L _t , as described above. Dashed line E ₃ is a constant value T _n not Kanse distance between the solid line L _t is the current value I.

Comparing the broken line E ₃ with the solid line L _c showing the operating time characteristics of the conventional device, the current value of the device of this embodiment is higher than that of the conventional device.
There is a range in which control is not started unnecessarily quickly when I _k or less and sufficient control time can be secured even when the current value is I _k or more.

FIG. 9B is a diagram for explaining the response when the overload is sequentially reduced by the control, and the overload phenomenon until time t ₁ is the same as that in FIG. 9A. Until time t ₀ ,
The current value I is constant for a long time, and the added value S _n and the predicted value P _p are both on the straight line k ₀ . Overload occurs at time t ₀ , and the added value
S _n changes in the same manner as in FIG. 9 (a) and follows the curve k ₁ . The predicted value P _p precedes this by a time p and follows the curve k ₁ ′. When the predicted value P _p becomes equal to or higher than the operating value L _t , the output E ₃ is generated, which causes the first control at the time t ₁ . By this control, the temperature rise and the change of the added value S _n shift from the curve k ₁ to k ₂ , and the predicted value P _p sharply decreases at the time t ₁ and then follows the curve k ₂ ′.

The predicted value P _p is smaller than the operating value L _t for a while, and the output E ₃
Does not occur. The predicted value P _p eventually becomes greater than or equal to the operating value, producing the output E ₃ . As a result, the second control is performed at time t ₂ . By this control, the added value S _n and the predicted value P _p
Follow k ₃ and k ₃ ′.

Compared with the case of the conventional device shown in FIG. 9 (a), the above-mentioned reaction is sufficiently delayed at the time t ₂ when the second control is performed, and it takes a long time during this time, but Fewer other controls can be performed. Further, after the time t ₂ when the second control is performed, when the added value S _n is changing toward the operating value L _t or less, the output E ₃ is not generated, and the output E ₃ does not occur. Further, there is no need to instruct the third control.

As described above, in the first embodiment, the added value S _n after the scheduled time p
Since it is designed to operate when the predicted value P _p for predicting is greater than or equal to the predetermined value L _t , it can be operated before the scheduled time when the temperature rise value of the protected part reaches the upper limit value, and It is possible to provide an overcurrent relay for overload protection having excellent characteristics such that it does not operate when the temperature rise value is below the upper limit value.

[Second Embodiment (Second Embodiment of Function Value Processing)] In the first embodiment, the function f (I) calculated in the processing 5-2 in FIG. 3 is expressed by the equation (2). It is assumed to be proportional to the square of the current value I, I ² . This squared function is generally well known as the one that most faithfully simulates the current temperature rise characteristic. However, there are cases where the current temperature rise characteristic needs to be a function other than the equation (2).

FIG. 10 is a diagram showing a second embodiment of such a function f (I). In the figure, the horizontal axis is the current value I and the vertical axis is the value of the function f (I). The function f (I) is divided by the values r ₁ , r ₂ and r ₃ of the current value I, and f ₁ (I), f
Either ₂ (I), f ₃ (I) or f ₄ (I) is used.

Each of the functions f ₁ (I), f ₂ (I) and f ₃ (I) is a linear function and is represented by a straight line as shown in the figure. Calculate the value of the corresponding function. The dashed curve shows I ^1.6 , the function f ₁ (I), f
₂ (I) and f ₃ (I) each approximately simulate I ^1.6 in a considerable range. By such a simulation, the function in the figure simulates I ^1.6 when I <r _{3 and} is proportional to I ² when I ≧ r ₃ .

Current values I such as the functions f ₁ (I), f ₂ (I) and f ₃ (I)
To calculate the value of the linear function of, it is convenient to calculate the current value I without squaring. An example of this calculation method is shown as sampling 12 times during one cycle of the current.

However, X _n is the data at the time of sampling n times before the latest time of sampling. Since the fact that the equation (10) represents the current value I is shown in Tables 6 and 2 of the above-mentioned reference document 1, the explanation is omitted for simplicity. In addition to the above, there are various means for calculating the current value I.

The above embodiments are merely examples of the function f (I) simulating the current temperature rise characteristic of the protected portion, and the function f (I) of the present invention can be variously modified and implemented. is there.

Third Embodiment (Second Embodiment of Addition Processing) Next, a second embodiment of addition processing 6 will be described with reference to the drawings. FIG. 11 is a flow chart showing the processing contents of this embodiment.
The same parts as those in FIG. 4 are indicated by the same symbols. First, processing 6-1
In step 6-3, the added value S _n is stored as S _n-1 , and the calculated difference value Δ _n is stored as Δ _n-1 . Then calculates a difference value delta _n by the following equation in the process 6-4.

Δ _n = f (I) + Δ _n-1 −S _n-1 (11) Further, in process 6-5, it is detected whether or not the following expression is satisfied.

| Δ _n | ≧ K ₄ (12) where K ₄ is a positive constant.

If the equation (12) is established, the addition value S _{n is} calculated by the following equation in process 6-6.
To calculate.

_{S n = K 2 Δ n +} S n-1 ... (13) Then, the value of the difference value delta _n in process 6-7 to a value of the following equation.

Δ _n = O (14) When the equation (12) is not satisfied, the addition value S _n-1 is set in the processing 6-8.
Save as S _n . In this case, the difference value Δ _n is (11)
It is saved as the value of the expression.

When the value of the difference value Δ _n-1 stored in the process 6-3 is zero as described above, the value of the addition value S _n calculated by the equation (13) is
It is equal to the value calculated by the equation (4). That is, when the absolute value of the difference value Δ _n is large and the condition that the expression (12) is satisfied continues,
The value of the sum S _n of the present embodiment, the sum of the embodiment of Figure 4 S _n
Is the same as that of the embodiment shown in FIG.

However, when the absolute value of the difference value Δ _n is small and the equation (12) is not satisfied, the addition value S _n and the difference value Δ _n are saved as the previous values and are saved at the time of the next processing. The difference value Δ _n is calculated again by using the respective values as S _n-1 and Δ _n-1 . This operation is repeated until the absolute value of the difference value delta _n satisfies the equation (12), the difference value delta _n has a integral value ΣΔ value of the difference value of the processing time until then. The difference value Δ _n is (12)
When the equation is satisfied, the value of the addition value S _n is changed and the value of the difference value Δ _n is set to zero by the equation (13) for the first time.

When the difference value Δ _n is small due to such processing,
Multiplication constant K ₂ is not performed, the constant K ₂ to the value of the difference value delta _n begins increases are multiplied, is performed processing (13). Since the value of the constant K ₂ is a small value such as 1 / 30,000, when the difference value Δ _n is small, it is possible to reduce the number of digits required for calculation by not performing multiplication. .

[Fourth Embodiment (Second Embodiment of Prediction Process)] The prediction process 7 is not limited to that shown in FIG. 5 and can be variously modified. Such an embodiment will be described with reference to the drawings. FIG. 12 is a flow chart showing the processing of this embodiment, and the same portions as those in FIG. 5 are indicated by the same symbols.

First, in the process 7-1, as in the case of Figure 5, the additional value S _n
To save as a predicted value (P _{m) m = 0} in the m = 0 of the predicted value P _m. Next, the previous current value data I _n saved in the process 7-6 is saved as I _n-1 , the latest current value I is calculated in the process 7-7, and this value is saved as I _n . .
Next, in process 7-8, the current change value I _d is calculated by the following equation.

I _d = I _n −I _n−1 (15) In process 7-9, the maximum value of the change value I _d is set to 0. That is,
If the value of I _d calculated by equation (15) is negative, then I _d
, But if positive, it is modified to a value or zero.

In the process 7-10, the current value I _n which is calculated in the process 7-7,
The predicted current value I _m is taken in as the predicted value (I _m ) _{m = 0 at m = 0} . In process 7-11, the predicted current value I _{m + 1} is calculated by the following equation.

I _{m + 1} = (m + 1) I _d + I _m (16) In process 7-12, f (I) _{m +} of the value of the function f (I) when the current value I is the predicted current value I _{m + 1.} Calculate ₁ . In process 7-13, whether or not the function value f (I) _{m + 1} is greater than or equal to the operation value is detected by the following equation.

f (I) _{m + 1} ≧ L _t (17) When the expression (17) is satisfied, the predicted value P _{m + 1} is calculated by the following expression in process 7-14.

P _{m + 1} = K ₃ {f (I) _{m + 1} −P _m } + P _m (18) Subsequently, the process proceeds to process 7-3, and the subsequent processes are the same as those in the case of FIG. That is, when the expression (6) is satisfied, the processing 7
The detection result of is set to Y, and when it is not established, in processing 7-4, 1 is added to the time m to set m + 1 as a new m, and (1
Let P _{m + 1 in} equation (8) be the new value of P _m . Further, when the new value of m satisfies the expression (7) in the process 7-5, the detection result in the process 7 is set to N, and when not satisfied, the process 7-11 and subsequent steps are repeated.

When the expression (17) is not satisfied in the processing 7-13, the result of the processing 7 is set to N without performing the processing after the processing 7-14.

In the above process, when the expression (17) is satisfied, the predicted values are calculated one after another as the following expressions.

However, f (I _n + I _d ) is the value of the function f (I) when the current value I is I _n + I _d , and the others are the same.

When the predicted values are calculated one after another by the equation (19), if the values become the operation values L _t or more, the detection result of the process 7 becomes Y. If none of the predicted values P _{1 to} P _p reaches the operation value L _t , the detection result of the process 7 becomes N.

If the expression (17) is not satisfied, the expression (6) is not satisfied in the processing 7-3, so that it is not necessary to perform the processing after the processing 7-14.

The values of the current values I _n + I _{d to} I _n + pI _d in equation (19) are all 0 when the current value is not decreasing because the maximum value of the change value I _{d in} equation (15) is set to 0. Equal to I _n . The response in this case is exactly the same as that of the embodiment shown in FIG. When the current value is decreasing, the change value I _d becomes negative, and the current value I _n + I _{d to} I _n + pI _d
Gradually decreases, and the predicted values P _{1 to} P _p are sequentially calculated using the value of the function f (I) for this value. This calculated value is a predicted value, assuming that the current decreasing tendency of the current continues.

For example, if there are generators on both sides of the protected part and overloads are being eliminated by increasing or decreasing the output of these generators, the above calculation method Since the change is predicted and the predicted value is calculated,
It is possible to calculate an extremely appropriate predicted value.

[Fifth Embodiment (Third Embodiment of Prediction Process)] A third embodiment of the prediction process will be described with reference to the drawings. Thirteenth
The figure is a flow diagram showing the processing of this embodiment. First,
In the process 7-15, and calculates the predicted value P _p after the time t _p by the following equation.

_{P p = {f (I)} -S n} K 6 + S n ... (20) However, K ₆ is a predetermined value, usually the value of the following expression, t _p is the time constant is a constant.

K ₆ = 1−e ^{−tp / τ} (21) Next, in process 7-16, it is detected whether or not the following expression is satisfied.

P _p ≧ L _t (22) If the expression (22) is satisfied, the detection result of the process 7 is set to Y, and if not, the detection result of the process 7 is set to N.

Next, the operation of this embodiment will be described. Equation (20) is the function f
When the value of (I) is constant, the predicted value P changes with time t in the following equation, and the value of the predicted value P _p after the time P _t when the initial value of the predicted value P is the added value S _n It is shown.

From such a relationship, the predicted value P _{p of} Expression (20) is equivalent to the predicted value P _{p of} Expression (8). That is, the change P _Δ of the prediction value P in the prediction calculation of the equation (8) is If you say The initial value of P is the added value S _n . The predicted value P _{p of the} equation (8) obtained by performing the addition operation p times is substantially equal to the predicted value P _{p of the} equation (20) solving the equation (23) when the time t _p is made equal to pt _Δ .

As described above, in the present embodiment, the predicted value P _p after the scheduled time t _p when the current value I does not change can be calculated without repeating a large number of addition operations as shown in FIG.

[Sixth Embodiment (Fourth Embodiment of Prediction Process)] A fourth embodiment of the prediction process will be described with reference to the drawings. 14th
The figure is a flow diagram showing the processing of this embodiment. Process 7
At -17, it is detected whether the value of the function f (I) satisfies the following equation.

f (I) ≧ L _t (25) If the expression (25) is not satisfied, the detection result of the process 7 is set to N, but when it is satisfied, the process moves to the process 7-18, and the function z of the following formula is obtained.
The value of (t) is calculated.

Then, in process 7-19, it is detected whether or not the value of the function f (t) satisfies the following equation.

z (t) <1-K ₆ (27) If the expression (27) is satisfied, the detection result of the process 7 is set to Y, and if not, the detection result of the process 7 is set to N.

The operation of this embodiment will be described. Assuming that the change of the predicted value P is represented by the equation (23), the value of the function f (I) is constant, and the initial value of the predicted value P is S _n , the predicted value P _t after the time _t is It is shown by the formula.

_{P t = {f (I)} -S n} (1-e -t / τ) + S n ... (28) Therefore, the conditions predicted value P _t reaches the operating value L _t after time t is, L _t = _{{f (I) -S n}} (1-e -t / τ) + S n ... (29) Therefore, Conditions under which the predicted value _{P p} after the scheduled time t _p is equal to or greater than the operating value L _t is,
Since the time t calculated by the equation (30) is longer than the scheduled time t _p , the following equation is obtained.

1-e- ^{t / τ} ≤ 1-e- ^{tp / τ} (31) Therefore, if the function z (t) of the equation (26) satisfies the equation (27) (however, the value of the constant K ₆ is (21 ), The predicted value P _p is greater than or equal to the operating value L _t .

In addition, since the added value S _{n in the} equation (26) is smaller than the operation value L _t , L _t −S _n is positive, so that the value of the function f (I) is the added value.
Less than S _n, f (I) when -S _n is negative, the function z (t)
The value of becomes negative and equation (27) holds. But (25)
When the expression is satisfied, therefore f (I) -S _n is to perform the process only when a positive 7-18. Therefore, the function f (I)
Even if the value of the function z (t) becomes negative in a state where the value of is smaller than the operation value L _t and the predicted value P _p cannot exceed the operation value L _t , the detection result of the prediction process 7 is set to Y. There is no such thing.

As described above, according to the present embodiment, the fact that the time when the predicted value P reaches the operation value L _t is the scheduled time t _p or less is a function z of the time t.
It is detected by the value of (t). This detection is predicted
It is a means to detect the condition that P _p becomes the operating value L _t or more,
It has the same effect as the embodiment of FIG.

As described above, the present invention detects the condition that the predicted value P _p is the operation value L _t or more, and produces an operation output,
Various modifications can be made, and it is not always necessary to directly calculate the predicted value P _p .

[Seventh Embodiment (Fifth Embodiment of Prediction Process)] Next, a fifth embodiment of the prediction process will be described. In all of the embodiments of the prediction processing described above, it is detected that the prediction value P _p is equal to or _larger than the constant value L _t, or it is detected that this condition is satisfied.

However, the present invention is not limited to the form in which the fixed value L _t or more. That is, the detection in the processing 7-16 in FIG.
Instead of equation (2), for example, the following equation can be used.

P _p ≧ L _t −K ₅ (θ _c −θ _r ) ... (32) where K ₅ is a positive constant, θ _c is ambient temperature, and θ _r is reference temperature.

Equation (32) is based on Equation (22) and has a correction term K ₅ (θ _c −
θ _r ) is added, and a term obtained by multiplying the difference between the ambient temperature value θ _c and the reference temperature value θ _r by a constant K ₅ is added.
Since the constant K ₅ and the reference temperature value θ _r are given as constant values in the equation (32), the ambient temperature value θ _c is detected by using a temperature sensor, and the detected value is digitalized (32) The calculation of the formula can be easily performed.

Equation (32) shows that when the ambient temperature θ _c is equal to the reference temperature θ _r ,
It is the same as the expression (22) and responds in exactly the same way as the embodiment of FIG. When the ambient temperature is high and there is little margin for temperature rise, the predicted value P _p produces a smaller operation output, and when the ambient temperature is low and there is more margin for temperature rise, the larger predicted value
Since an operating output is generated at P _p , appropriate protection can be provided against changes in ambient temperature.

As described above, the present invention not only generates the operation output by detecting the condition that the predicted value P _p is the constant value L _t or more, but also the predetermined condition or more in which other conditions are added as in Expression (32). It is possible to detect the occurrence of the above and generate an operation output. As the predetermined condition, not only the ambient temperature but also various conditions such as atmospheric pressure or wind speed can be added.

[Eighth Example (Sixth Example of Prediction Process)] Next, a sixth example of the prediction process will be described. This processing is used in processing 7-15 in the processing flow of FIG. 13 (20).
The predetermined value K _{6 of the} formula is set as the following formula instead of the formula (21).

As a result, the predicted value P _p is shown by the following equation.

In this process, the change in the added value at the time of prediction will continue to change,
The predicted value P _p is calculated as a straight line. The accuracy of equation (33) is inferior to that of equation (21), but t _p / τ
When is sufficiently smaller than 1, the error is small and it can be sufficiently applied. Further, this process has an advantage that the calculation process of the predetermined value K ₆ is easier than the formula (21).

[Ninth Embodiment (Seventh Embodiment of Prediction Process)] Next, a description will be given of the seventh embodiment of the prediction process with reference to the drawings. FIG. 15 is a flow chart showing the processing of this embodiment, and the same parts as in FIG. 13 are indicated by the same symbols.

First, in process 7-20, the value of the predetermined time t _p is calculated by the following equation.

t _p = K ₇ I (35) where K ₇ is a positive constant.

Next, the predetermined value K ₆ is calculated using the value of the predetermined time t _p calculated in process 7-21. This calculation is normally performed using either equation (21) or equation (33). In addition, it was calculated by equation (33)
When the value of t _p / τ is below a certain value, it can be used as it is, and when it exceeds a certain value, the value of equation (21) can be used.

The subsequent processing is exactly the same as that of the embodiment shown in FIG.
The predicted value P _p is calculated at −15, and is determined at processing 7-16.

In this embodiment, the predicted value after the predetermined time t _p shown by the equation (35)
It is to calculate P _p . Generally, when overload is recovered by, for example, a change in the output of a generator, the time required to recover to the rated load is longer as the degree of overload is remarkable. Therefore,
In many cases, it is preferable to make the predetermined time longer as the overload becomes remarkable as in the example of the equation (35), and to promptly instruct the treatment. In the present embodiment, it is possible to take an appropriate response in such a case. I can.

As described above, there are various means for changing the predetermined time, and for example, there is a method using the following formula.

t _p = K ₇ (I−K ₈ ) ... (36) where K ₈ is a positive constant related to the rated current value or operating value T _t of the protected part, and is zero when t _p is negative. To do.

If the constant K ₈ in the equation (36) is the rated current value of the protected part,
The predetermined time t _p is proportional to the difference between the overload current value and the rated current value, which is more rational from the equation (35). Further, since the operating value T _t is generally settled in a constant relationship with the rated current value, by setting the constant K ₈ to a value related to the operating value T _t ,
The constant K ₈ will be indirectly related to the rated current value.

The predetermined time t _p can be related not only to the current value I as described above but also to the ambient temperature, and the following equation is an example.

_{t p = K 7 {I-} K 8 + K 9 (θ c -θ r)} ... (37) where K ₉ is a positive constant.

The formula (37) is designed so that when the ambient temperature is high and the margin of temperature rise is small, the prediction time P _p is made longer and the treatment is instructed at a faster time.

As described above, the predetermined time t _p can be changed in various ways according to various conditions such as the current value I and the ambient temperature θ _c . Such a change of the predetermined time t _p is
The present invention is not limited to the above-described embodiment and can be similarly applied to other embodiments.

[Tenth Example (Second Example of Initial Processing)] Next, a second example of the initial processing will be described. In this embodiment, the value of the added value S _n at the time of the initial processing is set to the following expression instead of the value shown in FIG.

S _n = K ₉ L _t (38) However, K ₉ is a positive constant and is usually a value of 1 or less.

If the load current fluctuates drastically, the load current suddenly decreases after being kept at a value that is approximately the rated current of the protected part, and after the sudden decrease, there is an abnormality such as a momentary interruption in the control power supply. It is possible that initial processing will occur. If an overload occurs immediately after this, in the embodiment of FIG. 6, the added value S _n of the initial processing is small, so underprotection occurs and a transient temperature rise is caused.

In this embodiment, the value of the added value S _n at the time of the initial processing is set to a value having a predetermined relationship with the operation value L _t , thereby eliminating or reducing the fear of insufficient protection as described above.

Further, the value of the sum S _n at the time of initial processing and the following _{equation, S n = K 9 f (} I R) ... (39) However, f (I _R) when the current value I is the rated current I _R is Function f of
Even if the value of (I) is used and there is a predetermined relationship with the rated current value I _R , the same effect as in the case of expression (38) is obtained.

[Eleventh Embodiment (Third Embodiment of Initial Processing)] Next, a third embodiment of the initial processing will be described with reference to the drawings. FIG. 16 is a flow chart showing the processing of this embodiment, and the same parts as in FIG. 6 are indicated by the same symbols. First, a function value process is performed in process 5, and the value of the function f (I) corresponding to the current value I is calculated. Next, in process 4-2, the value of the added value S _n is set to the following expression.

S _n = f (I) and the maximum value of K ₉ L _t (40) In this embodiment, the value of the added value S _n at the time of initial processing is expressed by the formula (40) and the value of the constant K ₉ is, for example, 0, By setting the value to about 5 to 0.7, the risk of insufficient protection in the embodiment of FIG. 6 is reduced. That is, it is intended to reduce the degree of transient temperature rise in case of emergency.

Moreover, even _if the value of the added value S _n at the time of initial processing is set as the following equation, (40)
It has the same effect as the expression.

S _n = f (I) and K ₉ f the maximum value of (I _R) ... (41) above, the present invention the value of the sum S _n at the time of initial processing, the initial process when the current value I, the rated A value that is related to at least one of the current value I _{R and the} operation value L _t so that the most appropriate protection can be performed when the relay is restarted due to a momentary interruption of the control power supply, etc. Is.

[Twelfth Embodiment (Third Embodiment of Function Value Processing)] In the embodiments described above, the function f (I) is a function having only the current value I, that is, a variable having only the current value I. did. The function f (I) is not limited to this, and may include other variables. The following equation shows an example of such a function.

f (I) = K ₁ I ² + K ₅ (θ _c −θ _r ) ... (42) Equation (42) is a correction term K ₅ (θ _c − depending on the ambient temperature in Equation (2).
θ _r ) is added. K ₁ I ^{2 in} the first term simulates the temperature rise from the ambient temperature θ _c due to the electric current.
The term K ₅ (θ _c −θ _r ) is the reference temperature θ _r of the ambient temperature θ _c.
Therefore, the function f (I) in the equation (42) simulates the temperature rise from the reference temperature θ _r . This embodiment thus gives the function f (I)
By making both the current value I and the ambient temperature θ _c as variables, more appropriate overload protection can be performed for those having only the current value I as variables.

The function f (I) of the current value I is not limited to the above, and more appropriate protection can be performed by adding variables such as wind speed and atmospheric pressure.

When the temperature rising part of the protected equipment is cooled by another medium such as oil, the ambient temperature θ _c can be applied as the temperature of the medium, and the flow velocity of the medium can be added as a variable. By doing so, the effect can be further improved.

As described above, the present invention can apply the function f (I) as at least the variable including the current value I.

In addition, the present embodiment is applied to the function value processing, and the initial processing is
The values of the function f (I) at the time of initial processing in the case of FIG. 16 or FIG. 16 are calculated by using the values of all variables of the function f (I) as values at the time of initial processing.

[Thirteenth Embodiment (Third Embodiment of Addition Processing)] Next, a third embodiment of addition processing will be described with reference to the drawings. FIG. 17 is a flow chart showing the processing of this embodiment, and the same portions as those in FIG. 2 are indicated by the same symbols. Reference numeral 9 is an addition value correction process, which constitutes a part of the addition process.
For the sake of convenience, it is illustrated as being externally added to the addition process.

FIG. 18 is a diagram showing the details of the added value correction process.
In process 9-1, the added value S _n is S _n <L _s (43) However, it is detected whether L _s is a constant value. If the equation (43) is satisfied, the addition value S _n is forcibly corrected to S _n = L _s (44) in the process 9-2. If the expression (43) is not satisfied, the process 9-2 is not performed.

That is, when the addition value S _n is smaller than a predetermined value L _s is the additional value S _n is forcibly corrected to a constant value L _s, the addition value S _n when more than a predetermined value L _s is the additional value S _n is Not fixed.

The effect of this embodiment will be described with reference to the drawings. FIG. 19 is a diagram for explaining the response of the present embodiment, and shows the change in the added value S _n when the current value I is immediately set to zero after operating at time t ₀ . After time t ₀ , the addition value S _n decreases exponentially,
A constant value L _s is reached at t ₁ . After that, the added value S _n is maintained at the constant value L _s by the correction process. If this correction process is not performed, the added value S _n changes as shown by the broken line, and it takes a long time to reach a constant value of zero.

When testing the operating time, it is common to measure the current value I by suddenly changing it from zero to a certain constant value. At this time, accurate measurement cannot be performed unless the added value before the sudden change is constant. In this embodiment, since the after time t ₁ additional value S _n is constant value L _s, after time t ₁ can be tested again. If there is no correction process and the added value S _n changes as shown by the broken line, the added value S _n is still changing at time t ₂ and it is difficult to test.

As described above, the present embodiment has the effect of shortening the test interval in the operation time test.

[Fourteenth Embodiment (Fourth Embodiment of Addition Processing)] Next, a fourth embodiment of addition processing will be described with reference to the drawings. This embodiment is the same as the third embodiment of the addition processing except that the processing contents of the addition value correction processing 9 are different. FIG. 20 is a flow chart showing the added value correction processing of the present embodiment, and the same parts as in FIG. 18 are shown by the same symbols.

In FIG. 20, first, in process 9-3, it is detected whether or not the correction signal is received. This correction signal is given from the outside of the relay, and the presence or absence of the correction signal is read every time data processing is performed. When the correction signal is received, the process 9-2 is performed, and the added value S _n is corrected to a constant value S _n regardless of any value. If the correction signal is not received, the process 9-2 is not performed and the added value S _n is not corrected.

In the case of this embodiment, when the correction signal is given, the added value is immediately added.
Since S _n becomes the constant value L _s , the operation time test can be performed immediately after the correction signal is given. This has the effect of significantly shortening the operating time test interval.

[Fifteenth Embodiment (Fifth Embodiment of Addition Processing)] Next, a fifth embodiment of addition processing will be described. In this embodiment, the process 6-2 is the following formula instead of the formula (4) in the process flow chart of FIG.

_{S n = K 2 {f (} I) -L t} + S n-1 ... (45) (45) formula is an addition method of the inverse time overcurrent relay conventionally used. This addition method is inferior to the above-described embodiments in that the temperature rise is simulated, but many addition methods have been used conventionally. The present invention can be applied to such addition processing.

When the addition process is the formula (45), the calculation formula of the prediction process is also different. That is, the prediction process is for predicting the future result of the addition process, and if the addition term does not include the addition value S _n-1 before the present time as in the equation (45), the prediction calculation corresponding to it. Need.

For example, when the prediction process is performed in the process flow chart of FIG. 5, the calculation of the process 7-2 is performed by the following equation instead of the equation (5).

P _{m + 1} = K ₃ {f (I) −L _t } + P _m (46) Further, when the prediction process is shown in FIG. 13, the process of process 7-15 is performed using the predicted value P _p of the following equation. Try to calculate.

P _p = {f (I) −L _t } K ₆ + S _n (47) These prediction processes change the addition value S _n of the equation (45) when the value of the function f (I) does not change. To predict. The calculation formula of the prediction process is appropriately modified according to the calculation formula of the addition process as described above.

As described above, in the addition processing of the present invention, as long as the addition value S _n is the sum of the addition value S _n−1 before the current point and the addition term, and the addition term includes the term of the function f (I). Various modifications can be made.

[Fifteenth Example (Eighth Example of Prediction Process)] Next, an eighth example of the prediction process will be described with reference to the drawings. FIG. 12 is a flow chart showing the process of this embodiment, and the same parts as in FIG. 15 are shown by the same symbols.

First, in process 7-21, the predetermined time calculated in the previous process
The predetermined value K ₆ corresponding to t _p is calculated using, for example, formula (21) or formula (33). Next, in process 7-15, the value of the predicted value P _p is calculated. The value of the predetermined time t _p is stored as t _{p-1 in} process 7-22, and it is determined in process 7-16 whether expression (22) holds. If the expression (22) is satisfied, the value of the predetermined time t _p is set to the value of the following expression in the processing 7-23, and the detection result of the processing 7 is set to Y.

t _p = t _p-1 −t _Δ (48) However, t _Δ is a constant time, which is equal to the cycle of the prediction process. When the expression (22) is not satisfied, the processing 7-24 and 7
After performing -25, the detection result of process 7 is set to N. In process 7-24, the value of the predetermined time t _p is t _p = t _p-1 + t _Δ ′ (49) where t _Δ ′ is a constant time.

In process 7-25, when the value of the predetermined time t _p calculated in process 7-24 exceeds the constant time t _k , the value of t _p is changed to the constant time t _k.
And

As described above, this embodiment is the same as the seventh embodiment of the prediction process, that is, the embodiment shown in FIG. 15, except for the calculating means of the predetermined time t _p .

In the state where there is no overload, the formula (22) does not hold and the process 7-
Since the determination of 16 does not result in Y, the predetermined time t _p is the constant time t _k that is the maximum value of the variable range.

The calculation of the predicted value P _{p in} the process 7-15 is to predict the value after the fixed time t _k . However, when the expression (22) is satisfied due to the overload and the determination in the process 7-16 becomes Y, the predetermined time t _p is shortened by the constant time t _Δ by the process 7-23 every time the prediction process is performed.

Therefore, if the constant time t _Δ is equal to the cycle of the prediction process, the predetermined time t _p is the constant time only for the time that the determination of the process 7-16 is Y, and thus the detection result of the process 7 is Y.
It becomes shorter than t _k . After that, when the judgment of the process 7-16 becomes N, the predetermined time t _p becomes longer by the constant time t _Δ ′ every time the prediction process is performed, and finally becomes the constant time t _k .

Such a change of the predetermined time t _p is effective, for example, when an external timer is started by the operation of the overcurrent relay and the load is limited by the operation of this timer. That is, when the operating time of the timer is 30 seconds, it is preferable that the overcurrent relay always operates by predicting the temperature rise value after 30 seconds. However, the overcurrent relay works once, for example 10
If it operates for a second, the timer runs 20 seconds after the time of 10 seconds. Therefore, at this point, it is preferable that the overcurrent relay also operates by predicting the temperature rise value after 20 seconds.

As described above, by changing the predetermined time t _p in response to the overcurrent relay itself, it is possible to perform a preferable response for a specific application in which a timer is used externally.

[Effects of the Invention] As described above, the present invention predicts the added value after a predetermined time, detects the condition that the predicted value is equal to or more than the predetermined value, and activates it. Provide a means for issuing a control command at an appropriate time according to the degree of overload so that the temperature rise of the protected part is kept below the allowable limit when the control takes a long time. Is.

[Brief description of drawings]

FIG. 1 is a diagram showing a hardware configuration of an embodiment of the present invention, and FIG.
FIG. 3 is a flow chart showing the processing contents of one embodiment of the present invention,
FIG. 4 is a flow chart showing the function value processing of one embodiment of the present invention,
FIG. 5 is a flow chart showing an addition process according to an embodiment of the present invention,
FIG. 6 is a flow chart showing a prediction process of an embodiment of the present invention,
FIG. 7 is a flow chart showing an initial process of an embodiment of the present invention,
FIG. 8 is a view for explaining a reaction of an embodiment of the present invention,
FIG. 9 is a characteristic diagram showing operating time characteristics of one embodiment of the present invention, and FIG. 9 is a comparison of the response of one embodiment of the present invention and the response of a conventional device when overload is eliminated by control. FIG. 10 is a diagram showing the function of the second embodiment of the function value processing of the present invention, FIG. 11 is a flow chart showing the second embodiment of the addition processing of the present invention, and FIG. FIG. 13 is a flowchart showing a second embodiment of the prediction processing of the present invention, and FIG. 13 is a third flowchart of the prediction processing of the present invention.
FIG. 14 is a flow chart showing the fourth embodiment of the prediction processing of the present invention, FIG. 15 is a flow chart showing the seventh embodiment of the prediction processing of the present invention, and FIG. FIG. 17 is a flow chart showing the third embodiment of the initial processing of the present invention, FIG. 17 is a flow chart showing the processing of an embodiment using the third embodiment of the addition processing of the present invention, and FIG. FIG. 17 is a flowchart showing in detail the addition value correction processing used in the embodiment of FIG. 17, FIG. 19 is a diagram showing the response of the addition value when the embodiment of FIG. 18 is used, and FIG. 20 is the addition of the present invention. FIG. 21 is a flow chart showing in detail the addition value correction processing used in the fourth embodiment of the processing, and FIG. 21 is a flow chart showing the eighth embodiment of the prediction processing. 1 ... Input converter, 2 ... Data acquisition device 3 ... Processing device, 4 ... Initial processing 5 ... Function value processing, 6 ... Addition processing 7 ... Prediction processing, 8 ... Output processing 9 ... Addition value correction processing

Claims (22)

[Claims] 1. An overcurrent relay having an anti-time limit characteristic used for overload protection, which calculates a value of a function f (I) of a current value I simulating a current-temperature rise characteristic of a protected device. Means and the function f calculated by the first means
Second means for adding an addition term including the value of (I) and calculating the addition value S _n , and at least one of the current value of the function f (I) or the current value I and the addition value are used. A predetermined time
The value of the added value S _n after t _p is predicted and calculated, and the predicted value is calculated.
P _p, and third means for generating an output by detecting that the predicted value P _p is equal to or more than a predetermined value, and the addition value S _n of the second means is at least the function f (I ) Is an addition term including the term and the addition value S _n-1 before the present time, an overcurrent relay characterized by the above-mentioned. 2. The overcurrent relay according to claim 1, wherein the variable of the function f (I) is only the current value I. 3. The variable of the function f (I) has at least the current value I.
And the ambient temperature θ _c are both included. The overcurrent relay according to claim 1, wherein 4. The second means adds the addition value S _n to S _n = K ₂ {f (I) -S _n-1 } + S _n-1 where K ₂ is a positive constant and S _n-1 Claim 1 is a value that is an addition value before the present time.
The overcurrent relay described in the item. 5. The second means adds the addition value S _n to S _n = K ₂ Δ _n + S _n-1 where Δ _n is a difference value and Δ _n = f (I) + Δ _n-1 −S Δ
_n-1 and Δ _n-1 is the difference value before the present time, and when the absolute value of the difference value Δ _n is less than the predetermined value, the difference value Δ _n is not added before the present time. The difference value Δ _n-1 is stored as a difference value Δ _n−1 of the difference value Δn ₋₁ , and when the absolute value of the difference value Δ _n is greater than or equal to a predetermined value, addition is performed, and the difference value Δ _n−1 before the present time is set to zero. The overcurrent relay according to claim 1. 6. The addition of the second means is characterized in that the addition value S _n is S _n = K ₂ {f (I) −K ₁₀ } + S _n, where K ₁₀ is a positive constant. Claim 1 to
The overcurrent relay described in the item. 7. The overcurrent relay according to claim 1, wherein the predetermined time t _p of the third means is a constant time. 8. The overcurrent relay according to claim 1, wherein the predetermined time t _p of the third means changes according to the current value I. 9. The overcurrent relay according to claim 1, wherein the predetermined time t _p of the third means changes depending on the current value I and the ambient temperature θ _c . 10. The overcurrent relay according to claim 1, wherein the predetermined time t _p of the third means changes in response to the overcurrent relay itself. 11. The overcurrent relay according to claim 1, wherein the predetermined value of the third means is a constant value. 12. The overcurrent relay according to claim 1, wherein the predetermined value of the third means changes depending on the ambient temperature θ _c . 13. third means, the predicted value P _p after the predetermined time t _p
The overcurrent relay according to claim 1, characterized in that when the calculated value is equal to or larger than a predetermined value, the predicted value P _p of the added value is equal to or larger than the predetermined value. 14. third means calculates a time prediction value P _p is equal to or greater than a predetermined value, when the calculated time is shorter than the predetermined time t _p, the predicted value P of the summed value after a predetermined time t _p The overcurrent relay according to claim 1, wherein the condition is that _p is equal to or greater than a predetermined value. 15. third means, as the value of the current function f (I) does not change in the future, the predicted value P _p after the predetermined time t _p
The overcurrent relay according to claim 1, wherein the overcurrent relay is for detecting that the condition is equal to or more than a predetermined value. 16. A third means calculates a predicted value P _p as P _p = {f (I) −S _n } K ₆ + S _n, where K ₆ is a function of a predetermined time t _p , and this value is 16. The overcurrent relay according to claim 15, wherein the overcurrent relay is for detecting that the value is a predetermined value or more. 17. The third means comprises: However, the overcurrent relay according to claim 1, wherein L _t calculates a value of a predetermined value and detects that the value of z (t) is less than the predetermined value. 18. A third means detects that, when the current value I is decreasing, it is assumed that this decrease will continue and that the predicted value P _p after a predetermined time t _p becomes a predetermined value or more. The overcurrent relay according to claim 1, wherein the overcurrent relay is provided. 19. A first means according to claim 1, further comprising means for forcibly correcting the added value S _n .
The overcurrent relay described in the item. 20. When the addition value S _n is smaller than the predetermined value, the overcurrent relay of Claims paragraph 19, wherein further comprising means for the addition value S _n with a predetermined value. 21. The overcurrent relay according to claim 19, further comprising means for setting the addition value S _n to a predetermined value in response to an external command. 22. The second means has means for making the added value S _n relate to at least one of the following values at the time of initial processing. The overcurrent relay described in the item. (I) Function f calculated with the value of the variable as the value at the time of initial processing
Value of (I) (II) Function f calculated with current value I as rated current value I _R
Value of (I) (III) Predetermined value of third means