JPH0225761A - Optical current transformer - Google Patents

Abstract

PURPOSE:To measure a current with high accuracy even in the environment in which vibration and a temperature variation are large by placing an elastic body having an adhesive property in a gap between a containing case and a Faraday effect material and fixing the Faraday effect material to the inside of the containing case. CONSTITUTION:A Faraday effect material 1 is fixed to the inside of a containing case 4 which becomes roughly a shape of a rectangular parallelopiped by coupling a seat 4a, holding plates 4a, 4c and 4d and side plates 4e, 4f with bolts. Subsequently, two planes of an incident surface 2 and a light-emitting surface 3 of a light beam are stuck to the surfaces of the seat 4a and the holding plate 4d with adhesive agents 14a, 14d, and elastic bodies 15a, 15b in which adhesive agents 14b, 14c are applied to both faces are placed in a gap between other two surfaces and the holding plates 4b, 4c. In such a way, it is prevented that mechanical stress is applied to the Faraday effect material 1, and also, the optical axis can always be kept constant, therefore, an optical current transformer which can measure a current with high accuracy even in the environment in which vibration and a temperature variation are large can be obtained.

Description

Detailed Description of the Invention [Objective of the Invention] (Industrial Application Field) The present invention utilizes the Faraday effect to detect the rotation angle of the polarization plane of a linearly polarized wave in a magnetic field caused by an electric current, and thereby It takes an optical current transformer to detect the value.

In particular, high accuracy even in environments with large temperature changes and vibrations.
Regarding optical current transformers with high reliability and excellent long-term reliability.

(Prior Art) Conventionally, wound wire current transformers have been mainly used as large current measuring devices, but they have drawbacks such as large size, high cost, and distorted transient current waveforms. Therefore, in recent years, instead of this method, a method of optically measuring current using a Faraday effect material has been attracting attention. Although such current measuring instruments are small and can faithfully reproduce transient current waveforms, they have the drawback of increasing errors due to vibrations and temperature changes that occur in the field. Amorphous solids such as lead glass, commonly used as Faraday effect materials, are optically isotropic.

However, when stress is applied, glass also becomes optically anisotropic and exhibits birefringence. This is a cause of measurement error. Stress occurs when a temperature change occurs in glass, but if glass is firmly fixed to a substance with a different coefficient of thermal expansion, or if substances with different coefficients of thermal expansion are firmly fixed to glass, The stress inside the glass that occurs due to temperature changes is considerably larger than that in the case of a single glass. Therefore, it is preferable to fix the Faraday effect material without firmly fixing anything to the Faraday effect material while maintaining its flexibility.6 (Problem to be solved by the invention) However, in this case, The optical axis changes easily,
The drawback was that it was susceptible to vibration. In order to improve the above drawbacks, for example, published patent publication No. 60-210
As shown in 770, a method has been proposed in which an optical device is housed in a storage case together with an elastic body. When this method is applied to a circular integral type in which a Faraday effect material is arranged around a typeface as shown in Japanese Patent Publication No. 58-153174, the deviation of the optical axis due to vibration occurs because the Faraday effect material is large. In order to prevent this, it was necessary to fix a light transmitting device such as a polarizer or a lens, and a light receiving device such as an analyzer or lens to the Faraday effect material.

In the light intensity modulation methods that have been proposed so far, 1
Even if optical components such as those mentioned above are bonded to the Faraday effect material, the temperature characteristics will not deteriorate, and errors due to incomplete alignment of the optical axis will not be a problem. Ta.

However, in the phase modulation method that has been proposed in order to obtain a large dynamic range, in which the type of light is incident on a Faraday effect material, it is necessary to make fine adjustments to the angles of the three polarizers, the intensity balance of the three lights, etc. The case that houses the analyzer lens, analyzer lens, etc. is a large structure, and must be made of metal such as stainless steel in order to obtain processing precision.If this case is glued to Faraday effect material, the difference in thermal expansion coefficient Stress was generated in the Faraday effect material when the temperature changed, causing birefringence and causing errors.

An object of the present invention is to provide an optical current transformer that can measure current with high accuracy even in environments with large vibrations and temperature changes.

[Structure of the invention]

(Means for Solving the Problems) According to the present invention, an elastic body is disposed in the gap between the surface of the substantially rectangular Faraday effect material and the inner surface of the storage case.

As an elastic body, a rubber plate coated with adhesive on both sides, or
Using an adhesive elastic material such as elastic adhesive resin,
It is characterized by fixing the Faraday effect material inside the storage case.

(Function) Since the Faraday effect material is flexibly bonded and fixed, there is no need to apply initial stress bias.

Mechanical stress is less likely to occur even when the temperature changes, and measurement errors due to temperature changes can be eliminated.

Furthermore, due to the difference in thermal expansion coefficient between the Faraday effect material and the storage case material, even if the gap between the Faraday effect material surface and the inner surface of the storage case widens due to temperature changes, the elastic body disposed in between will not move. It is less likely to fall off or the Faraday effect material will be misaligned.

Furthermore, by reducing the gap between the three faces including one vertex of the substantially rectangular parallelepiped, the effect of preventing displacement of the Faraday effect material is further increased.

(Example) An example of the present invention will be described below with reference to FIGS. 1 to 4. Figure 1 is a cross-sectional view taken in a direction perpendicular to the central axis of the conductor.
and an exit surface 3, and a seat 4a.

It is composed of holding plates 4b, 4c, 4d and side plates 4e, 4f (not shown in FIG. 1), and is fixed within the storage case 4. The storage case 4 includes a seat 4a, a press plate 4b,
4c.

4d and the side plates 4e and 4f are connected with bolts to form a substantially rectangular parallelepiped shape.

Polarizers 5a, 5b, 5c are provided near the light incident surface 2.
, lenses 6a, 6b, 6c, and optical fiber ferrules 7a, 7b.

A light transmitting optical head 8 that accommodates an analyzer 9° prism 10.7C is fixed to a storage case 4, and a 9° prism 10. Lens 11. A light receiving head 13 housing an optical fiber ferrule 12 is fixed to a housing case 4.

Faraday effect material including a light entrance surface 2 and a light exit surface 3 1. The two planes are bonded to the surfaces of the seat 4a and the presser plate 4d using adhesives 14a and 14d with a thin adhesive layer, and between the other two planes parallel to the two planes and the presser plates 4b and 4c. A gap is formed between them, and this gap is filled with elastic bodies 15a and 15b such as rubber plates coated with adhesives 1.4b and 14c on both sides. A conductor 16 through which a current to be measured flows passes through the center of the Faraday effect material 1.

FIG. 2 shows a cross-sectional view of the conductor 16 in a plane parallel to its central axis. One of the two planes (not shown in FIG. 1) of the Faraday effect material 1 is bonded to the surface of the side plate 19a of the storage case 4 with a thin adhesive layer using an adhesive 14a, and the other surface is bonded to the side plate 19b. form a gap with adhesive 1
Elastic body 15c, such as a rubber plate coated with 4f on both sides, 1
5d fills this gap. Figure 3 shows the principle of this optical current transformer. Polarizers 5a, 5b, and 5c are placed spatially offset by 120°C, and the radiation that passes through these polarizers is The light thus generated becomes linearly polarized waves spatially shifted by 120° C., as shown at 20 in FIG. 3(a). The optical signals sent through the optical fibers 17a, 17b, and 17c are rectangular waves with a constant frequency as shown in FIGS.
The phase is shifted by 0°C.

Such light is passed through the Faraday effect material 1.

Analyzer9. If it is taken into the receiving fiber 18 through the lens 11, the light intensity of this composite wave will have a waveform as shown in (8).If this light intensity is converted into an electrical signal and only its fundamental wave component is extracted, (f) become that way. If a current is flowing through the conductor 16, the plane of polarization of the linearly polarized wave will rotate due to the Faraday effect, so the phase of the fundamental wave will be 2 times the Faraday rotation angle F compared to the phase when no current is flowing. The phase is shifted by a factor of 2, that is, 2F. By measuring this deviation as shown in (g), the conductor 1
You can know the current flowing through 6. Such a phase modulation method has no limitation on the magnitude of the Faraday rotation angle, and can obtain a large dynamic range.

The operation of the embodiment will be explained with reference to FIGS. 1 and 2. The Faraday effect material 1 is adhered to the seat 4a, the holding plate 4d, and the side plate 19a with a thin adhesive layer, and these surfaces serve as a reference, and the Faraday effect material 1 is always located at the same location in the storage case. This is due to aging of the elastic bodies L5a, 15b, 15c.

This holds true even if the elastic force of 15d changes.

If the temperature of the parts configured as shown in Figures 1 and 2 at room temperature is, for example, the minimum ambient temperature specified by the standard -
Consider the case where the temperature drops to 20°C.

The temperature change is about 40 dag, and a storage case made of metal such as aluminum and having a side of about 150 am will shrink by about 0.2 nsa. The lead glass that forms the Faraday effect material has almost no thermal expansion or contraction, so the gap between the Faraday effect material and the storage case is approximately 0.
．． This means that it is reduced by 2oi. This displacement compresses the soft elastic bodies 15a, 15b, 15c, and 15d to absorb the gap reduction caused by this temperature drop.
Application of large mechanical stress to the Faraday effect material 1 can be prevented.

Conversely, consider the case where the temperature rises. As for the temperature rise value, the maximum ambient temperature specified by the standard is 40℃, and the conductor 1
Adding the temperature rise value due to energization in step 6, the temperature may rise to about 100°C. In this case, the temperature change is about 80 degrees
, and in a storage case made of metal such as aluminum and having a side of about 150 mm, the gap will increase by about 0.4 mm. Faraday effect material 1 even if the gap widens
and the storage case 4 are glued together, so the elastic body 15
a, 15b, 15c, and 15d will not shift or fall off, and therefore will not block the optical path.

This also means that the Faraday effect material 1 and the elastic bodies 15a, 15d, 15c are bonded in advance at room temperature.

Since there is no need to compress 15d and apply a stress bias, excessive compressive stress is not generated when the temperature drops.

The tensile stress acting on the Faraday effect material 1 is
5a, 15d, 15c, and 15d are soft and will be absorbed.

For example, consider a case where vibration occurs due to a faulty large current flowing through the conductor 16 or a circuit breaker operating. In the present invention, even under such a situation, the Faraday effect material 1 is Fixed at the same location, in particular the light entrance surface 2. The light output surface 3 is a seat 4a and a presser plate 4, respectively.
Since it is always in close contact with d via a thin adhesive layer, the relative position with the light transmitting optical head 8 and the light receiving optical head 13 does not change, and the optical axis does not change. Therefore, no measurement errors occur during such vibrations.

Next, consider a case where the value of the current flowing through the conductor 18 changes, the amount of heat generated by the conductor 18 changes, and the ambient temperature of the Faraday effect material 1 changes. At this time, less mechanical stress is applied to the Faraday effect material 1 due to thermal expansion and thermal contraction of the storage case 4, and measurement errors due to birefringence can be eliminated. Optical head for light transmission8. Optical head for light reception 13. Light incidence surface 2. Since the light emitting surfaces 3 are installed close to each other, and only the metal that constitutes the storage case 4 exists between them, it is possible to prevent the optical axis from shifting due to thermal expansion or contraction. can.

Even when the gap between the storage case 4 and the Faraday effect material 1 widens when the temperature drops, the Faraday effect material 1 is held in place without applying a compressive pressure bias in advance, and the elastic bodies I5a, 15b , 15c,
15d will not fall off or move, that is, there is no risk of blocking the optical path.

As described above, since the stress of the Faraday effect material 1 is reduced, measurement errors due to the photoelastic effect are also reduced.

The gas-insulated switchgear installed in substations, which is one of the applications of this optical current transformer, is guaranteed to operate without maintenance for over 20 years, and this optical current transformer also has a similar level of operation. long-term reliability is required. It is generally known that elastic bodies lose their elasticity and change shape (so-called cracking) due to aging. This may cause the position of the Faraday effect material 1 in the storage case 4 to change over a long period of time, but according to the present invention, this does not occur and an optical current transformer with high long-term reliability is provided. be able to.

In one embodiment described above, the elastic bodies 15a, 15b.

15c and 15d are explained as elastic bodies such as rubber plates coated with adhesive on both sides, but the effects of the present invention will not be impaired even if a rubber-like resin, such as silicone rubber, has rubber elasticity even after curing. do not have.

In addition, when the above-mentioned rubber-like resin is used as an adhesive, the stress caused by the expansion and contraction of the adhesive itself that occurs when the adhesive hardens or changes in temperature is absorbed, preventing local stress concentration from occurring in the Faraday effect material. Since this can be prevented, it is possible to provide a highly reliable optical current transformer that is free from adhesive exfoliation and cracking of the Faraday effect material.

〔Effect of the invention〕

As described above, according to the present invention, it is possible to prevent mechanical stress from being applied to the Faraday effect material, and the optical axis can always be kept constant, so even in environments with large vibrations and temperature changes, It is possible to provide an optical current transformer that can accurately measure current and has high long-term reliability.

[Brief explanation of the drawing]

1 and 2 are cross-sectional views showing one embodiment of the present invention, and FIG.
Figure #Kon≠I is an explanatory diagram showing the principle of an optical current transformer. 1... Faraday effect material, 2... Light incidence surface 3
...Light exit surface, 4...Storage case 4a
- Seat, 4b, 4c, 4d - Pressing plate 5a, 5b, 5cm polarizer, 6a, 6b
, 6cm lens. 7a, 7b, 7c, 12-ferrule 8... optical head for light transmission, 9... analyzer 10... prism, 13... optical head for light reception 14a
, 14b, 14c, 14d-adhesive 15a, 1
5d, 15c, -elastic body, 16-...conductor, 1
7a, 17b, 17c... optical fiber for light transmission 18
...Receiving fiber, 19a, 19b...
・Side plate 20...Polarization plane of 3 lights, 21...Temporal change agent of each signal

Claims (1)

[Claims] In the optical current transformer, a Faraday effect material is arranged near the conductor to be measured, and the Faraday effect material is installed in a storage case, and the Faraday effect material is installed in a storage case, and the Faraday effect material is installed in a storage case, An optical current transformer characterized in that an adhesive elastic body is interposed in the gap between the inner surface of the storage case and the Faraday effect material to fix the Faraday effect material inside the storage case.