JP2561062B2 - Overcurrent relay - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an overcurrent relay having an anti-time limit characteristic used for overload protection.

[0002]

2. Description of the Related Art In recent years, various types of electronic circuits have been proposed for overload protection of electric motors and transformers. For example, the electronic overload protection device proposed in Japanese Patent Laid-Open No. 56-1728 integrates the square of the current i of the equipment i ² for the purpose of accurately simulating the thermal behavior of the equipment to be protected. , Its integration result,

[0003]

[Equation 1] This is a method of shutting off the main circuit when the value exceeds the allowable value determined by the device.

As explained by the inventor using FIG. 3 of the above-mentioned publication, when a relatively large overcurrent lasts for a short time and then changes to a value close to the rated current, the conventional method is used. It turns out that this is an effective method compared to the method.

According to the above-mentioned proposal, since the integral calculation is started after i> i _n , the result of the integral calculation shows that the steady-state current, which is supposed to have heated the equipment before the overload, is large. It can be said that it has not been added to anything.

That is, in general, although the equipment has a characteristic of allowing a large short-time overload as the steady-state load is smaller, in the proposed method, the operating state before the overload is no load. The protection operation is performed in the same operation time regardless of whether the load is the rated load or not, which is a serious problem in performing the overload protection.

In order to solve the above-mentioned problems, the inventors of the present invention have previously disclosed, in Japanese Patent Application No. 60-122734, "First means for calculating a value KI ² proportional to the square of the current, and the first means. second means for calculating the sum S _n by adding by using the calculated value of the unit, and the third means produce an output when the calculated value of the second means is equal to or larger than a predetermined value In each case, the addition by the second means is performed by the calculated value KI ^{2 by} the first means.
When the value K proportional to the difference between the current previous calculated value S _n-1 of the second means _{^{'(KJ 2 -S n-1}} ), where K, K' is a positive constant) and the calculated local point earlier The present invention has been filed as a subject of "Overcurrent relay characterized by adding value S _n-1 ".

In the above application (hereinafter referred to as the prior invention), when performing overload protection of a power device whose temperature rise value is proportional to the square of the current, the operating time is changed according to the preload condition before the overload occurs. It provides excellent protection in conformity with the temperature rise of protected electric power equipment. However, there is some room for improvement in this prior invention as well.

[0009]

That is, in the above-mentioned invention of the prior application, power equipment whose temperature rise value is proportional to the square of the current can be protected with high performance, but another power equipment having a different relation with the current is used. Is unsuitable for the protection of.

For example, reference document 1 ("Transformer Technical Committee: Oil-filled Transformer Operation Guidelines", Technical Report No. 99 of the Institute of Electrical Engineers of Japan, Showa
Published June 46, p. In (30), the maximum steady-state winding temperature θ _H of the transformer is given by the following equation.

[0011]

[Equation 2] Where θ _{a is the} ambient temperature, θ _{ON is} the maximum oil temperature rise at the rated load, θ _{qN is} the difference between the maximum winding temperature and the maximum oil temperature at the rated load,
R: Ratio of load loss to no load loss at rated load, K: Ratio of actual load to rated load, m: A constant determined by the cooling system, generally 0.8, n: For safety in forced oil circulation
Set to 1.0, but 0.8 for natural circulation.

In the above, R >> 1, m = n = 0.8 and K = I /
Assuming I _N (where I _N is the rated current), equation (1) is

[0013]

(Equation 3) The temperature rise is proportional to the 1.6th power of the current.

Further, in order to calculate the value KI ² proportional to the square of the current, a square operation in a multiplier or a digital calculator having a hardware configuration is required, which makes the hardware circuit or the operation complicated. In addition, the above-mentioned prior invention has a drawback that requires some supplementary improvement.

The present invention has been made in order to solve the above-mentioned problems, and provides an appropriate overload protection for electric power equipment other than the one whose temperature rise is proportional to the square of the current. In addition to providing an overcurrent relay, it is possible to perform overload protection with a simpler configuration (reducing the calculation load) by simulating the square of power equipment in which the temperature rise is proportional to the square of the current. It is an object of the present invention to provide a possible anti-time limit overcurrent relay.

[0016]

The present invention obtains a function f (I) of a current value I, which receives a current I as an input and simulates a current-temperature rise characteristic of a power device or a power line to be protected,
Based on the obtained function f (I) and the added value S _n-1 before the current time which is internally held, K '(f (I) -S _n-1 )
+ S _n-1 (where K'is a positive constant) is calculated, this added value is set to S _n , and the added value S _n is used to determine the operation / non-operation, and this processing is repeated. It was done.

Then, the ambient temperature of the object to be protected or the object to be protected is corrected, the initial value of the operation is optimized, the number of digits of the operation is reduced, and the test time is shortened.

The function f (I) has, for example, a temperature rise characteristic of I
^In the case of ^1.8 or I ² , there is a case of directly calculating this, but as shown in FIG. 3, different functions f ₁ (I) to f ₇ (I) are applied according to the magnitude of the current value I. By doing so, a simple calculation can be executed. Further, as shown in FIG. 5, when the current value is below a specific value, it is proportional to I ^1.6, and above the specific value, I ^1.6.
It also includes various functions that simulate temperature rise characteristics proportional to ² . Further, the function f) I) is expressed in the form of the following equation as shown in FIG.

[0019]

## EQU00004 ## f (I) = f '(I) + f "(I) (3) Also includes a function represented by the sum of a plurality of functions f' (I) and f" (I).

[0020]

【Example】

(First Embodiment) An embodiment 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, 1 is an input converter, which receives an AC current I from a power system (not shown) that is protected from overload, and a DC voltage e proportional to the amplitude of the input.
Yields ₁ . Since this converter is known, detailed description thereof will be omitted. For example, an AC voltage proportional to the AC current I is generated by a current / voltage converter (transactor TL),
After rectifying this voltage with a full-wave rectifier R _f , a low-pass filter LP
The voltage e ₁ is obtained by passing F. Reference numeral 2 denotes a data acquirer, which samples the voltage e ₁ at a predetermined cycle and then outputs data d ₂ proportional to the sampled value.
Cause This data becomes the amplitude value I of the current I. Reference numeral 3 denotes a processing device, which performs a process described below using the data d ₂ and produces an output e ₃ in accordance with the processing result. This output e ₃ is used, for example, to cut off the protected part to cut off the current, or to cut off part of the load supplied with current from the protected part to reduce the current in the protected part.

FIG. 2 is a flow chart showing the processing of one embodiment of the processing device 3, and FIG. 3 is a diagram showing an example of the functions used in the calculation of the present invention. In FIG. 2, processing step 4 is a step relating to the initialization procedure. The initial value of the added value S _n is the value [f corresponding to the assumed current value I _N of the function f (I).
(I)] _Set to _IN . The details of this processing will be described later in the section of the ninth embodiment. The addition process 5 represents the part of the addition process that is the essence of the present invention, and the processes in process steps 5-1 to 5-5 are sequentially performed. First, in processing step 5-1, the added value S _n is stored as S _n−1 , and in processing step 5-2, the data d ₂ is stored.
The value I of is read. In processing step 5-3, the amplitude value I is divided into which part is divided by r ₁ to r ₆ on the horizontal axis of FIG. In processing step 5-4, the functions f ₁ (I) to f ₇ (I) shown in FIG.
The value of (I) is calculated. In processing step 5-5, the added value S _n is calculated according to the following equation.

[0022]

## EQU5 ## S _n = K {f (I) -S _n-1 } + S _n-1 (4) where K is a constant 0 <K << 1 Then, the process proceeds to step 6 and the added value S _n is used. And perform the determination process. An example of this determination process is shown by the following equation.

[0023]

S _n ≧ L _t (5) However, L _t is a constant, and a value slightly above the rated current value I _R, for example, a value of the function f (I) for 1.15I _R is selected.

If the equation (5) is satisfied in the judgment processing step 6, the output e ₃ is generated in the processing step 7, and then the processing returns to the processing step 5-1. If the formula (5) is not satisfied in the judgment step 6, the process immediately returns to the processing step 5-1 and the same processing as the above is repeated.

The division of the amplitude value I and the function f applied in the above
The relationship (I) is shown below.

[0026]

(Equation 7) Examples of the values of r _{1 to} r ₆ and the functions f ₁ (I) to f ₇ (I) are shown below when the value I is normalized by the rated current value I _R of the protected device, for example.

[0027]

## EQU8 ## r ₁ = 0.2, r ₂ = 0.46, r ₃ = 0.8, r ₄ = 1.1, r ₅ = 1.56, r ₆ = 2 (7) f ₁ (I) = 0.2 I (8) f _{2 (I) = 0.66I-0.092} ... (9) f 3 (I) = 1.26I-0.368 ... (10) f 4 (I) = 1.9 I-0.88 ... (11) f 5 (I) = 2.66I- 1.716 (12) f ₆ (I) = 3.56 I-3.12 (13) f ₇ (I) = 12 I-24 (14) Next, the operation of the embodiment will be described with reference to the drawings. The function f (I) in the above embodiment simulates and approximates the value of I ² . The value of I ² is shown by the dashed line in FIG.
₁ (I) to f ₇ (I) approximate the value of I ² with a straight line in each division range. On the other hand, the added value S _n is expressed by the equation (4).

[0028]

[Equation 9] _{S n -S n-1 = K} (f (I) -S n-1) ... is (15). As described above, the function f (I) imitates and approximates I ² .

[0029]

[Equation 10] Becomes The left side of the equation (16) represents the increase / decrease of the added value Sn at the time (Δt) when the processing of FIG.

Here, if this time Δt is set to an extremely short time, the equation (16) can be approximated by the following equation.

[0031]

[Equation 11] When the current value I changes using this approximate expression, the added value S
Explain how _n changes. If the value of the current I is held at I ′ for a long time, the value of the added value S _n will eventually converge to I ′. After that, if the current value I changes to I ″, the value of S in equation (17) is

[0032]

## ^EQU12 ## S = {(I ") ^2- (I ') ² } (1-e- ^Kt ) + (I') ² (18) However, t is the time after the current change.

This change situation is shown in FIG. (A) drawing I 'I after = 0 i.e. no load "and when it becomes, (b) drawing I' = I _R or I followed rated load"
That is the case. (C) The figure shows the case of intermittent overload. In any case, the value of S follows the current value I ² exponentially, simulating the temperature change of the device in which the temperature rise is proportional to the square of the current value. The time T _{0 at which} the value of S reaches the value that produces the output e _3, that is, the operating value L _t , is shorter as the value of the pre-current I ′ is larger, and is shorter after a short recovery due to overload in advance.

As described above, this embodiment is characterized in that the operating characteristics change with the same tendency as the characteristics of the time when the temperature of the protected equipment reaches the assumed constant dangerous value, depending on the magnitude of the load at steady state. Is equipped with. Moreover, data processing (8)
Since only the linear function as shown in the equation (14) is handled, it is not necessary to handle the quadratic function as in the invention of the prior application, and the processing is simple.

(Second Embodiment) In the embodiment described above, the function f
Although (I) is set to simulate the square of the current value I (I ² ), various other characteristics such as the current value 1.6 (I ^1.6 ) can be simulated. FIG. 5 shows an example of such a function f (I). In the figure, the alternate long and short dash line is I
^1.6 , the broken line shows the characteristic of I ² , and the function applied at the partition points r _{1 to} r ₅ is selected from f ₁ (I) to f ₆ (I). Function f when current value I is equal to or less than partition point r _3
1 (I) to f ₃ (I) imitate I ^1.6 ,
The functions f ₄ (I) to f ₆ (I) when r ₃ or more imitate I ² .

The function f (I) can be selected freely within a range simulating the current-temperature rise characteristic of the equipment to be protected, and various other selections are possible. Also, the function f (I)
However, the current value is not limited to the one expressed by a linear expression, and a quadratic expression or the like can be relatively easily calculated.

That is, f (I) = I ² is more complicated than the linear expression, but the calculation is not so difficult,
In the case of the simulation of FIG. 2, it is possible to omit the process 5-3 and calculate the entire range of the current value with f (I) = I ² . Also,
The function f for the case segment point r ₃ or more current values of Figure 5
It is also possible to calculate (I) as I ² . In this case, there is no difference in that the calculation of I ^1.6 is simple.

(Third Embodiment) FIG. 6 is a diagram showing another embodiment of the function f (I). In the figure, the current value is the division point r
_{When it is 3} or less, I ^1.6 is simulated, and when r ₃ or more, I ² is simulated, and the broken line shows I ^1.6 . The function f (I) is

[0039]

[Mathematical formula-see original document] f (I) = f '(I) + f "(I) (19), and the function f' (I) on the right side is over the entire region of the current value I.

[0040]

[Equation 14] And the function f ″ (I) is

[0041]

(Equation 15) It is assumed that.

When the values of the equations (20) and (21) are plotted on FIG. 6, the x mark is shown, which is in good agreement with the broken I ^1.6 curve. The function f (I) that simulates the temperature rise as described above
Does not have to be a single function for each region of the current value I, but can be synthesized from a plurality of functions.

(Fourth Embodiment) A fourth embodiment will be described with reference to the drawings. FIG. 7 is a diagram showing this hardware configuration, and the same portions as those in FIG. 1 have the same symbols. An input converter ₈ generates an AC voltage e ₈ proportional to the AC input current I. This voltage e ₈ is guided to the data acquisition device 2, and the instantaneous value of the voltage e ₈ is sampled at a predetermined cycle, and the data d ₂ proportional to the sampled value is generated. This data d ₂ is processed by the processing device 3. That is, it differs from FIG. 1 in that the data d ₂ does not directly indicate the current value I.

The processing of this embodiment differs from the processing of FIG. 2 only in the contents of the addition processing. FIG. 8 is a flowchart showing only this addition processing 5 ', which is the same as FIG. 2 except that a processing step 5-6 for calculating the current value I from the data d ₂ is added after the processing step 5-2.

When the example of the processing steps 5-6 is shown as being obtained 12 times in one cycle of the data d ₂ input current I, the following equation is obtained.

[0046]

[Equation 16] However, X- _n is the data at the time of sampling n times before the latest sample. In processing step 5-6, the current value is 2
The power (I ² ) is calculated as necessary, and examples of the processing include the following.

[0047]

[Expression 17] I ² = X ₀ ² + X ₋₃ ² (23) where X ₀ is the latest sample and X ₋₃ is the sample three times before (90 ° before when the sampling interval is 30 °) Data of.

These are the current value I or its square (I ² ).
Since it is shown in Reference Document 2 (published in 1981 by the Institute of Electrical Engineers of Japan, Protection and Relay Engineering), the explanation is omitted for simplicity. In addition to the above, there are various calculation means shown in the reference document 1.

As described above, the input current value I can be sampled as it is as an AC waveform to obtain data, and can be calculated from the data. This method is the same as in the embodiment of FIGS. 1 and 2. The same effect can be obtained even if this method is applied to another embodiment.

(Fifth Embodiment) In the fifth embodiment, the operating value L _t of the above embodiments is corrected by the ambient temperature value θ. This will be described with reference to the drawings. FIG. 9 is a diagram showing a hardware configuration, and the same parts as those in FIG. 1 are indicated by the same symbols.
P is a power source, CT is a current transformer, M is a protected device such as a power transformer, 9 is a temperature sensor, and 10 is a data acquirer. A temperature sensor 9 detects the ambient temperature of the protected device M or its contents, and a voltage e ₉ showing a linear characteristic with respect to the temperature, together with a voltage e ₁ proportional to the magnitude of the current I, a data acquisition device.
Added to 10. The data acquirer 10 supplies the data d ₂ indicating the current value I and the data d ₉ indicating the temperature value θ to the processing device 3.

The processing contents of the processing device 3 are shown in FIG. FIG.
2 are designated by the same symbols. The difference from FIG. 2 is that the data d ₉ by the processing step 11 is added after the addition processing 5.
Is added to the operation value processing in the processing step 12. In the operation value processing step 12, the operation value L _t is calculated by the following equation.

[0052]

L _t = L ₀ −K ₀ θ (24) where L ₀ is the operating value when the ambient temperature is the reference value, K ₀ is a constant, and θ is (ambient temperature value−ambient temperature reference value) .

The operating value L _t becomes small when the ambient temperature is high, which shortens the operating time. It also changes when the ambient temperature is low.

As described above, this embodiment has the effect of being able to perform appropriate overload protection against changes in ambient temperature.

(Sixth Embodiment) In the sixth embodiment, the function f (I) up to the fourth embodiment is corrected by the ambient temperature value .theta. Will be explained. The hardware configuration of this embodiment is similar to that of the fifth embodiment and is shown in FIG. The difference from the fifth embodiment is the processing content of the processing device 3, and FIG. 11 is a flowchart showing this processing content. 2 and 11 are designated by the same reference numerals.

In FIG. 11, in the initial processing, data d ₉ representing the ambient temperature value θ is first fetched in processing step 11. Next, in processing step 13, the added value S _n is set to the following equation.

[0057]

S _n = [f (I)] _IN + f (θ) (25) where f (θ) is a function of the ambient temperature value θ, and the higher the θ, the larger the value. The function K ₀ θ similar to the equation (24) is used. Following this initial processing, addition processing 5 ″ is performed.

Processing step 5-1 in addition processing 5 "
The contents from 5 to 5-4 are the same as those of the process 5 in FIG. 2, and thereafter the process steps 5-7, 5-8 and 5-9 are sequentially performed. First, in processing step 5-7, the data d ₉ is read, and in processing step 5-8, the function f (I, θ) of the following equation is calculated.

[0059]

F (I, θ) = f (I) + f (θ) (26) That is, the function f (I) of the current value is corrected by the function f (θ) of the ambient temperature value θ, and the function f (I, θ) has a larger value as the ambient temperature is higher.

In processing step 5-9, the added value is calculated by the following equation.

[0061]

S _n = K {f (I, θ) -S _n-1 } + S _n-1 (27) The function f (I, θ) is used for this addition process,
This is similar to the above-described embodiment (equation (4)).

Also in this embodiment, the operating time is shortened if the ambient temperature is high, and is prolonged if the ambient temperature is low, and has the same effect as that of the fifth embodiment.

(Seventh Embodiment) The seventh embodiment is different from the above-described embodiments in that the added value S _n can be forcibly set to a specific value by external control, and It makes the test convenient. That is, when testing the above-mentioned relays, in order to test the operating time, the operating time after the current value I is kept at zero and the rated current value I _R for a long time is often measured. However, the operation time is a long time such as 700 seconds, and it takes a very long time for the added value S _n to reach the value corresponding to that value even if the current value is set to the above value after passing a certain current. . When testing the operating value, it takes a very long time for the added value S _n to reach the operating value.
The purpose of this embodiment is to solve such a problem.

This embodiment will be described with reference to the drawings. Figure 12
Is a diagram showing a hardware configuration of the present embodiment, and the same portions as those in FIG. 1 are denoted by the same symbols. The difference between FIG. 1 and FIG.
14 is added, and the signal s ₁₄ from this commander 14 is added to the processing device 3.

FIG. 13 is a flowchart showing the processing contents of this embodiment. 2 are designated by the same symbols. The difference between FIG. 2 and FIG. 2 is processing steps 15 and 16 before addition processing 5.
Is the point to be added. In processing step 15, the presence or absence of the signal s ₁₄ from the command unit 14 is detected. Without signal s ₁₄ ,
The process proceeds to the addition processing 5 as it is and responds in the same manner as the embodiment of FIG. When the signal s ₁₄ is present, the addition value S _n is set to the predetermined value A in the process 16, and the determination process of the process 6 is performed. That is, when the signal s ₁₄ is present, the added value S _n is suddenly changed to the scheduled value A, and when the signal s ₁₄ is removed, the state where the added value S _n is the scheduled value A is shifted to normal processing.

[0066] When the value of the function f (I) corresponding to the predetermined value A zero or rated current I _R, the length measurement of the operation time after the current is kept long time zero or rated current I _R It can be done without waiting time. Also, the planned value A
Operation value of the sum of L _t (1-0.02) or L _t (1 + 0.
02) is convenient for measuring the operating value I _{t of the} current. As described above, in the present embodiment, the added value S _n is forcibly changed suddenly to the predetermined value A by the external control, and this has an advantage that the test can be streamlined.

(Eighth Embodiment) In the eighth embodiment, (5)
In addition to the output e ₃ caused by the expression conditions, the output e ₃ resulting in the following condition 'provided, tripping the circuit breaker by the output e _3, the output e _3' so as to prevent the insertion of the circuit breaker by The purpose is to protect the electric motor from overload.

[0068]

[Equation 22] S _n ≧ L _c (28) However, L _c is a positive constant smaller than L _t, that is, when the electric motor is started, a large current of several times or more of the rated current flows for some time. Therefore, the temperature of the electric motor needs to be sufficiently low in order to turn on the circuit breaker to start the electric motor. For this reason, if the temperature of the electric motor is not sufficiently low, and if it is started immediately, overheating will be remarkable, and therefore, when the output e ₃ is generated during startup and the circuit breaker is expected to be cut off, the output e ₃ 'Causes the circuit breaker to be closed.

This embodiment will be described with reference to the drawings. Figure 14
Is similar to FIG. 1 except that produce an output e ₃ 'in addition to the output e ₃ a diagram showing a hardware configuration of the overcurrent relay to be used in this embodiment. FIG. 15 is a diagram showing a configuration example of the control part of this embodiment. In the figure, 17 and 18 are auxiliary relays, 17a is 17 normally open contacts, and 18b is 18 normally closed contacts. 19a is a normally open contact of a manually operated switch, 20t and 20c
Is a circuit breaker tripping mechanism and closing mechanism, and 21 is a power supply device.

When the added value S _n is equal to or greater than the constant value L _c , the output e ₃ ′ is generated and the relay 18 operates, and the contact 18b opens. In this state, the breaker is not closed even if the contact 19a of the switch is closed. When the added value S _n is greater than or _equal to the operating value L _t , the output e ₃ is generated and the relay 17 operates to close the contact 17a. As a result, the trip mechanism 20t operates and the breaker is cut off.

When the circuit breaker is turned on, the added value S _n is a constant value L _c
It is possible only when it is smaller than that, and the closing mechanism is urged by closing the contact 19a.

In the control portion of FIG. 15, the blocking of the circuit breaker when the output e ₃ ′ is present is performed by releasing the closing circuit, but various other means are possible. That is, for example, a mechanism for mechanically locking the closing of the breaker is provided and this mechanism is operated by an electromagnetic magnet.

FIG. 16 is a diagram showing another example of the control unit. In the figure, the same parts as those in FIG. 15 are indicated by the same symbols. 22 is a lamp and 23 is a display character, and the characters shown are displayed. Although not shown, there is an operation handle for the circuit breaker near these.
Explaining the parts different from FIG. 15, the output e ₃ ′ is generated and the contact
When 18b is opened, the lamp 22 goes out. This lamp 22
In the vicinity of, for example, there is a display character "Please do not turn on when the lamp is off", and it is displayed that turning off is prohibited. There are various other displays that mean such a prohibition of input, and examples thereof will be shown below.

Lamp lighting without output e ₃ ′: “Batch enabled” “Batch OK” Lamp lighting with output e ₃ ′: “Batch disabled” “Batch disabled” FIG. 17 is a flowchart showing the processing of this embodiment. is there. The difference from FIG. 2 is that after the addition processing 5, the judgment processing 24 and the output e
₃ 'it is only that the generation process has been added. Process 24 is (2
This is a part for determining the equation (8), and if the equation (28) is not satisfied and S _n <L _c , the process immediately returns to the process 5. S _n ≧ L _c
If so, an output e ₃ ′ is produced in process 25, and then the same process as in FIG. 2 is performed.

The operation of the above embodiment will be described with reference to the drawings. FIG. 18 is a diagram for explaining the reaction of the eighth embodiment. In the figure, a power failure occurs at time t ₁ and the circuit breaker is released due to undervoltage protection. As a result, the function f (I) becomes zero and the added value S _n gradually decreases. Power failure is restored at time t _2, the sum value S _n is for greater than a predetermined value L _c, on of the circuit breaker is inhibited until time t ₃ when the S _n <L _c.

[0076] the breaker turned on time t ₄ immediately after feeding inhibition is solved, starting current of the motor flows. Therefore, the function f (I) has a large value as shown in the figure for a short time, and the added value S _n also increases at a considerable speed. However, the added value S
_n does not exceed the operating value L _t , and the shutoff operation is not performed.

As described above, at the time t ₃ , the addition value S _n is at the limit so that the added value S _n will exceed the operating value L _t if the input is earlier than this, and the input is made depending on the disappearance of the output e ₃ ′. By performing the operation, there is no fear of failure in the operation, and the operation can be restarted most quickly.

As described above, while the condition of the expression (28) is satisfied, the closing of the circuit breaker is blocked (or the prohibition is displayed), so that the closing fails (interrupted by the starting current at the time of closing). ) Can be done without fear.

(Ninth Embodiment) The ninth embodiment relates to the initialization procedure of process 4. In the invention of earlier application,
The added value S _{n is set} to 0 in the initialization procedure. This means that when restarting due to a momentary interruption of the relay control power supply, the added value S _{n of the} initial value always becomes 0 regardless of the operating state of the protected equipment, and if overload occurs immediately after this, appropriate protection is provided. There are drawbacks that cannot be achieved. The present embodiment improves this point and adds value S _n during the initialization procedure depending on the protected device and the control power supply.
The object is to improve so that the initial value of can be made a preferable value.

The first example of the initial processing of the added value S _n is a method of setting the initial value as the value of the function f (I) corresponding to the current value I at that time. The flowchart of FIG. 19 shows an example of this processing, and the same portions as those in FIG.

First, in process step 4-1, the data d ₂ indicating the current value I is fetched. Next, in process 4-2, this current value I is _fetched as the initial power supply value I _IN , and process 4-3
And the value [f (I)] _IN for the current value I _IN of the function f (I)
Is calculated. In this process, when the function f (I) is divided by the current value I as shown in FIG. 3, the current value I is processed 5-3.
Then, calculate using an appropriate function. Subsequently, in processing step 4-4, the value of the added value S _n is set to [f
(I)] The value of _IN is set, and the initial processing 4 ends.

In this embodiment, the initial value of the additional value S _n (hereinafter referred to as the initial additional value [S _n ] _IN ) is a function f (I) corresponding to the current value I of the protected device when the initial processing is performed. And the addition process 5 starts from S _{n of} this value.

Such an initial process is performed when the protected device is a device such as a large transformer whose load fluctuation is usually gentle and the power supply of the overcurrent relay is supplied from a storage battery. Is suitable. In such a case, the relay performs the initial processing in the following cases, and in any case, the most appropriate protection can be performed as described below.

(I) When both the relay and the protected device are activated from a long sleep state. First, after the relay is activated and the initial addition value [S _n ] _IN becomes a value corresponding to the current value 0, the protected device is activated.

(Ii) During operation of the protected equipment, one of the duplicated relays is inspected, and then the operation is started.

(Iii) During the operation of the protected equipment, the power supply of the relay is momentarily cut off due to a work error or the like and is restored. In both cases (ii) and (iii), the initial addition value [S _n ] _IN is the value of f (I) corresponding to the current value I of the protected device in operation.

In any case, the initial addition value [S _n ] _IN simulates the temperature rise value of the protected equipment during operation at the time of initial processing. The added value S _{n of the} relay simulates the temperature rise of the protected device at the start of operation, and has a feature that an appropriate overload state can be started immediately.
If no special consideration is given to the initial sum,
Since the addition value S _n reaches the above value after the addition processing 5 has been performed for a long time, the time in which appropriate overload protection can be performed is delayed.

The second example of the initial processing of the added value S _n is a function f for supporting the initial value with the rated current value I _R of the protected device.
This is a method of setting the value of (I). FIG. 20 is a flow chart showing an example of this processing, and the same portions as those in FIG. 19 are indicated by the same symbols. Figure 19
20 is the same as FIG. 19 except that the processes 4-1 and 4-2 in FIG.

In process 4-5, the rated current value I _R is fetched as the initial current value I _N , and in processes 4-3 and 4-4, the initial addition value [S _n ] _IN of the function f (I) is obtained. Rated current value I _R
Is set to the value corresponding to.

Such a process is suitable when the protected device is an electric motor whose load changes drastically and the power supply of the overcurrent relay is an uninterruptible power supply such as a storage battery. In such a case, there are many cases in which almost no load occurs immediately after the rated load continues, and it is often dangerous if the current value at the time of initial processing is used as a reference. Therefore, it is safest and appropriate to perform overload protection assuming that the rated current state continues in advance, such as immediately after there is an abnormality in the control power supply of the relay.

The third example of the initial processing of the adder S _n is a method of setting the initial value as the operation value L _t . FIG. 21 is a flow chart showing an example of this processing, and the only difference from FIG. 19 is the content of processing step 4.

In the processing step 4, only the processing 4-6 is executed, and the processing makes the added value S _{n the} value of the motion value L _t . This value of the addition value S _n establishes the equation (5) in the determination process 6 and causes the output e ₃ to be generated in the process 7.
However, if the value of f (I) with respect to the current value I is smaller than the operation value L _t , the value of the addition value S _{n in} the addition process 5 is the operation value L _t.
Since it is smaller than _t, no output e ₃ is produced.

Such processing is suitable when the equipment to be protected is an electric motor and the power source of the relay is supplied from the same power source as the power source for driving the electric motor. That is, for example, if there is a power outage and many motors are started at the same time, the overcurrent at the time of start-up will cause the overcurrent relay to operate at another location and shut off at the power supply side. May be supplied. In such a case,
It is safest to set the initial addition value [S _n ] _IN as the operating value L _t when the relay performs initial processing because the power is re-supplied because the protected device has just experienced an overload at startup. And is appropriate.

The above is just a few examples of the method of determining the initial addition value [S _n ] _IN by associating it with the current value I, the rated current value I _R or the operating value L _t during the initial processing. For example, as a method for associating with the current value I at the time of initial processing, the processing 4 in FIG.
-2, there is a method of giving the initial current value I _IN as the following equation.

[0095]

## EQU23 ## I _IN = 1.2 I (29) This is intended to be protected on the slightly safe side. There are the following examples of such protection-oriented protection.

[0096]

[Expression 24] I _IN = I and the larger one of 0.5 I _R (30) In this example, when the current value I at the time of initial processing is small, the initial current value I _IN is set to 0.5 times the rated current value I _R. By doing so, one tries to avoid danger.

The rated current value I _R is not held as data stored in the relay, and the operating current value I _t or the added value S _n
In many cases, only the operation value L _{t of} is stored. When the operating current value I _t is stored, the process of FIG. 20 4-5
The rated current value is given by the following equation, for example.

[0098]

I _R = 0.85 I _t (31) Further, when the operation value L _t of the added value S _n is stored, for example, in processing step 4-6 of FIG.

[0099]

By setting S _n = 0.7 L _t (32), the initial addition value [S _n ] _IN can be set to a value related to the rated current value I _R.

As described above, in this embodiment, the initial addition value [S _n ] _IN is set to the current value I at the initial processing, the rated current value I _R ,
By setting at least one of the value of the function f (I) corresponding to the value proportional to the operating current value I _t or the value of the operating value L _t of the added value, the control power of the relay is interrupted again and the like. It provides the most appropriate protection when booting.

(Tenth Embodiment) In each of the above-mentioned embodiments,
A single-phase current is used for simplification of description, but instead of this, a two-phase or three-phase current is introduced, and for example, the input converter 1 of FIG. It is also possible to obtain the output e ₁ proportional to the amplitude value of the maximum one.

Further, the input converter 8 of FIG. 7 is provided for each of the three phases, and all the outputs thereof are introduced into the input converter 2 so that the current data of each phase can be obtained. It can be applied by deriving the maximum value of the current value of each phase at -6 or by deriving the value of the reverse phase current.

(Eleventh Embodiment) The eleventh embodiment relates to the calculation process of the added value S _{n in} the processing step 5-5, and is intended to compress the number of digits required for calculation.
That is, the value of the constant K in the equation (4) becomes a small value of 1 / 30,000 when 50 times are added per second and the time constant is 10 minutes. Therefore, 1 / of the value of {f (I) -S _n-1 }
It is necessary to prepare the number of digits that can accurately calculate the value of 30,000. If the function f (I) is I ^2, and the current value I when the short-circuit current passes is set to 20 times the nominal operating value I _s to sufficiently simulate the temperature rise at this time, {f (I) − S
The value of _n-1 } reaches 400I _s ² . Also To the current value I can operate reliably when 1.01 times the nominal operating value I _s, the value of {f (I) -S n- 1}

[0104]

[Equation 27] At the time of, the value of the expression (4) {f (I) -S _n-1 } needs to be added. For this, 400I _s ² to 0.02I _s
^The number of calculation digits must be prepared up to ² / 30,000.

The purpose of this embodiment is to improve this point and to achieve sufficient accuracy with a smaller number of digits.
FIG. 22 is a flow chart showing the processing of this embodiment. A portion of the figure is used instead of the calculation processing of the added value S _n of the processing 5-5 of FIG. 2 or FIG. The configuration is similar to that of FIG.

In process 5-5-1, the saved difference value addition value ΔS _n is saved as ΔS _n-1 . Process 5-5
At −2, the difference value addition value ΔS _n is calculated by the following equation.

[0107]

[Expression 28] ΔS _n = f (I) + ΔS _n-1 −S _n-1 (33) In process 5-5-3, it is detected whether or not the difference value addition value ΔS _n satisfies the following equation. To do.

[0108]

[Expression 29] | ΔS _n | ≧ K _s (34) However, the addition threshold value K _s is a positive constant. When this condition is satisfied, the processing 5-5-4 and 5-
At 5-5, the added value S _n and the difference value added value ΔS _n are changed to the values of the following expressions.

[0109]

[Equation 30] S _n = KΔS _n + S _n-1 (35) ΔS _n = 0 (36) Further, when the condition of the equation (34) is not satisfied in the process 5-5-2, the process 5 is performed. At -5-6, the added value S _n-1 is saved as S _n , and the difference value added value ΔS _n is saved as the value of the expression (33). Although not shown, the difference value addition value ΔS _n is set to ΔS _n = 0 in the initial processing.

As described above, when the difference value addition value ΔS _n-1 stored in the process 5-5-1 is zero, the process 5-5 is executed.
The value of the sum Sn of calculated (35) by 4 is equal to the value of the sum S _n calculated by equation (4). That is, the value of the absolute value | ΔS _n |
When the state in which 5 and 5-5-5 are performed is repeated, the same operation as in the first embodiment, that is, FIG. 2 is performed.

However, when the absolute value | ΔS _n | of the difference value addition value calculated by the equation (33) is small and the equation (34) does not hold, the addition value S _n is saved as the previous value. And save the difference value addition value ΔS _n . Then, in the next process, the stored values are again calculated as the difference value addition value ΔS _n as S _n-1 and ΔS _n-1 , respectively. Absolute value of the difference value sum value in this way | [Delta] S _n | repeats this process until it reaches the value of the constant K _s, first changing the value of the sum S _n and the difference values after reaching the value of the constant K _s Addition value ΔS
_{Let n} be zero.

By the above processing, when the absolute value of the difference value addition value ΔS _{n is} a small value such as 0.02I _s ² , multiplication of the constant K is not performed, and the difference value addition value ΔS obtained by sequentially adding the difference values is performed. The absolute value of is, for example, K _S = 12I _s ²
When it reaches, the constant K is first multiplied. As a result, the minimum value of the data used for the calculation becomes 30,000 times, and the number of digits used for the calculation can be reduced.

(Twelfth Embodiment) The twelfth embodiment provides means different from the seventh embodiment for shortening the time required for the operation time test of the present invention. Will be explained. FIG. 23 is a flow chart showing the processing contents of this embodiment, and the same portions as those in FIG. 2 are indicated by the same symbols. The difference from FIG. 2 in the figure is that a determination process 26 is added after the addition process 5.

In the judgment processing 26, the S _n minimum value processing is performed.
The contents of this process, the value of (i) addition value S _n is the time less than the predetermined value L _S, modifies the value of the sum S _n to a predetermined value L _S.

(Ii) When the value of the added value S _n is greater than or equal to the predetermined value L _S , the value of the added value S _n is left unchanged without correction. This predetermined value L _S is usually a constant value.

The effects of this embodiment will be described with reference to the drawings. FIG. 24 is a diagram showing a change in the added value S _n when the relay of this embodiment is once operated and then the input current is cut off and restored. Assuming that the current is cut off at time t ₀ , the added value S _n exponentially decreases as shown in the figure, and at time t ₁ , a constant value L
After reaching _s , it does not change after that. If this means is not provided, the value of the function S _n continues to change as shown by the broken line.

In order to measure the operating time with high accuracy, the added value at the time of applying the current must be constant.
In the case of this embodiment, since the constant value L _s is reached at time t ₁ , the next operation test can be performed after this time. However, if the process 26 is not provided, it takes a longer time for the added value S _n to be negligible with respect to zero, and the waiting time for the test becomes longer.

[0118] The present embodiment as described above when the sum value S _n is smaller than the predetermined value L _S, by adding a force means for the addition value S _n to a predetermined value L _S, if flights operating time measurement It has a tightening effect. It should be noted that this addition can be made not only at all times as described above, but also at the time of an external command.

Such S _n minimum value processing can be carried out not only by the processing means described above but also by the following means, for example.

[0120]

[Equation 31] K [f (I) S _n-1 ] + S _n-1 −L _s <0 (37) and the addition value S _n is set to a constant value L _s, and the equation (37) is not satisfied ( Equation 4) is added. That is, the added value S _n
Is less than the predetermined value L _s , the added value S _n is set to the predetermined value L _s.
It is a compulsory means to To the extent possible, the means are not limited.

Further, such enforcing means is not limited to the embodiment of FIG. 2 as described above, but other embodiments such as FIG. 10 and FIG.
The embodiments shown in FIGS. 11, 12, 13, 17, and 19 to 22 can be similarly added. Also, the function f (I)
The To calculate directly squaring omits the division of the current value I of the process 5-3 of Example 2 to give, also (23) the value of the square of the current value I with I ² It goes without saying that the processes 5-6 and 5-3 in FIG. 8 may be omitted when calculating

[0122]

As described above, according to the present invention, the operating time is changed according to the magnitude of the steady-state load, so that appropriate protection can be performed according to the allowable overload capability of the protected equipment. It is a thing.

In addition, in the fifth and sixth embodiments, the operating characteristics are changed according to the ambient temperature of the protected equipment, so that appropriate overload protection can be performed according to the change of ambient temperature. It is a thing.

Further, in the seventh embodiment, since the value of the added value S _n can be changed by the external control, the overload relay of the present invention capable of performing appropriate protection in the future has excellent testability. Can be one.

Further, in the eighth embodiment, when the added value becomes equal to or _larger than the first and second operating values L _t and L _c, the first value is obtained.
And the second output is generated, the circuit breaker is tripped at the first output, and the second output is used to prevent the circuit breaker from being closed or to indicate that closing is not possible. It is possible to prevent activation in a state where load protection is performed.

In the embodiment of FIG. 9, the initial added value at the time of starting the relay is set to an appropriate value, and the protection after the recovery of the control power for the relay is set to be appropriate.

In the eleventh embodiment, addition processing is performed only when the difference value is larger than the addition threshold value.
The number of digits used in the calculation is reduced.

In the twelfth embodiment, when the added value is small, the predetermined value is forcibly set, and the test required time such as the operation time of the relay is shortened.

[Brief description of drawings]

FIG. 1 is a block diagram showing a hardware configuration of an embodiment of the present invention.

FIG. 2 is a flowchart showing data processing according to an embodiment of the present invention.

FIG. 3 is a diagram showing an example of a function used for an operation of the present invention.

FIG. 4 is a diagram for explaining a response according to an embodiment of the present invention.

FIG. 5 is a diagram showing a function used in a calculation according to a second embodiment of the present invention.

FIG. 6 is a diagram showing a function used in a calculation according to a third embodiment of the present invention.

FIG. 7 is a diagram showing a hardware configuration of a fourth embodiment of the present invention.

FIG. 8 is a flowchart showing an addition processing unit of processing according to the fourth embodiment of the present invention.

FIG. 9 is a diagram showing a hardware configuration of fifth and sixth embodiments of the present invention.

FIG. 10 is a flowchart showing the processing of the fifth embodiment of the present invention.

FIG. 11 is a flowchart showing the processing of the sixth embodiment of the present invention.

FIG. 12 is a block diagram showing a hardware configuration of a seventh embodiment of the present invention.

FIG. 13 is a flowchart showing the processing of the seventh embodiment of the present invention.

FIG. 14 is a block diagram showing a hardware configuration of an overcurrent relay used in an eighth embodiment of the present invention.

FIG. 15 is a sequence diagram showing a configuration of a control part according to an eighth embodiment of the present invention.

FIG. 16 is a sequence diagram showing a configuration of a control part according to an eighth embodiment of the present invention.

FIG. 17 is a flowchart showing the processing of the eighth embodiment of the present invention.

FIG. 18 is a diagram for explaining the response of the eighth embodiment of the present invention.

FIG. 19 is a flowchart showing the processing of the ninth embodiment of the present invention.

FIG. 20 is a flowchart showing the processing of the ninth embodiment of the present invention.

FIG. 21 is a flowchart showing the processing of the ninth embodiment of the present invention.

FIG. 22 is a flowchart showing the processing of the eleventh embodiment of the present invention.

FIG. 23 is a flowchart showing the processing of the twelfth embodiment of the present invention.

FIG. 24 is a view for explaining the reaction of the twelfth embodiment of the present invention.

[Explanation of symbols]

1 ... Input converter, 2 ... Data acquisition device, 3 ... Processing device, 4
... Initial processing, 5 ... Addition processing, 8 ... Input converter, 9 ... Temperature sensor, 10 ... Data acquisition device, 14 ... Commander, 17,18 ... Auxiliary relay, 17a ... 17 normally open contact, 18b ... 18 Normally closed contact, 19
a ... Normally open contact of manually operated switch, 20t, 20c ... Breaker trip mechanism and closing mechanism, 21 ... Power supply, 22 ... Lamp,
23 ... Display character.

Claims (4)

(57) [Claims] 1. In an overcurrent relay having an anti-time-delay characteristic for over- / over-protecting a protection target, a value of a function f (I) of a current value I simulating a current-temperature rise characteristic of the protection target is calculated. first means adds using the calculated value of the first means, it is a second means for calculating the sum value S _n, addition value S _n of the second means to or greater than a predetermined value And a fourth means for calculating the function f (θ) of the ambient temperature value θ of the object to be protected or the object to be protected, and the addition of the second means is the same as the first means. A value K {f proportional to the value of the function f (I) of the first means and the function f (θ) of the fourth means minus the addition value S _n-1 of the second means before the current time point. (I) + f (θ) -S n-1} ( where, K is a positive constant) Japanese that is to adding the current previous and additional value S _n-1 Overcurrent relay to. 2. A function f (I) of a current value I simulating a current-temperature rise characteristic of a protection target in an overcurrent relay having an anti-time-delay characteristic for over-negatively over-protecting a protection target. first means adds using the calculated value of the first means, it is a second means for calculating the sum value S _n, addition value S _n of the second means to or greater than a predetermined value The third means for producing an output when the second means is provided, and the addition by the second means is the value of the function f (I) of the first means and the addition value S _{n-1 of} the second means before the present time. Value proportional to the difference between
{F (I) -S _n-1 } (where K is a positive constant) and the addition value S _n-1 before the present time are added, and the initial value of the addition value of the second means is An overcurrent relay, wherein the value is at least one of the values (i) to (iv). (I) The value of the function f (I) of the first means with respect to the value proportional to the current value I _IN during the initial processing. (Ii) A value of the function f (I) of the first means with respect to a value proportional to the rated current value I _R of the protection target. (Iii) the first relative value proportional to the operating current value I _t
The value of the function f (I) of the means. (Iv) The predetermined value of the third means. 3. In an overcurrent relay having an anti-time-delay characteristic for over- / over-protecting a protection target, a value of a function f (I) of a current value I simulating a current-temperature rise characteristic of the protection target is calculated. first means adds using the calculated value of the first means, it is a second means for calculating the sum value S _n, addition value S _n of the second means to or greater than a predetermined value And third means for producing an output when the second means is used, and the addition of the second means includes the value of the function f (I) of the first means and the difference value addition value ΔS _n-1 before the present time and the second Difference value addition value ΔS _n = f (I) + ΔS from the addition value S _n-1 before the present time of the means
_The value KΔS _n (where K is a positive constant) proportional to _n-1 −S _n-1 is added to the addition value S _n-1 before the present time, and the absolute value of the difference value addition value ΔS _n is When the absolute value of the difference value addition value ΔS becomes larger than the addition threshold value by sequentially adding the difference value addition value ΔS _n when the value is smaller than the predetermined addition threshold value without waiting for the addition. An overcurrent relay characterized by adding a value KΔS proportional to this and an addition value S _n-1 before the present time to calculate an addition value S _n . 4. An overcurrent relay having an anti-time limit characteristic for overload protection of a protection target, wherein a value of a function f (I) of a current value I simulating a current-temperature rise characteristic of the protection target is calculated. and 1 means adds using the calculated value of the first means, second means for calculating the sum value S _n, addition value S _n of the second means equal to or more than the first predetermined value The third means for producing an output when the above becomes, the addition of the second means is performed by the value of the function f (I) of the first means and the addition value S _{n- of} the second means before the present time. Value K proportional to the difference from ₁
{F (I) -S _n-1 } (where K is a positive constant) and the addition value S _n-1 before the present time are added, and the addition value of the second means is the second predetermined value. An overcurrent relay, characterized in that, when it becomes less than a value, a forcing means for adding the added value to the second predetermined value is added.