KR102610413B1 - transformer for substation - Google Patents

Abstract

The present invention relates to a transformer for a substation with a new structure that can prevent damage due to earthquakes.
In the substation transformer according to the present invention, when an earthquake occurs and the base 1 and the lower support plate 10 move laterally, the transformer main body 2 does not move laterally and remains stationary.
At this time, the support ball 30 is inserted into the concave groove 11 of the lower support plate 10, and as the lower support plate 10 moves in the side direction, the concave groove 11 formed in the lower support plate 10 also moves laterally. direction, and at this time, the support ball 30 rises upward along the slope of the inner surface of the concave groove 11.
And, when the base (1) moves in the opposite direction, the support ball (30) and the lower support plate (10) repeatedly lower and rise, converting the lateral vibration generated in the base (1) into vertical vibration. Absorb it.
Therefore, it is possible to prevent the transformer body (2) from being damaged by moving laterally due to the kinetic energy of the base (1) and the lower support plate (10), which flow laterally due to an earthquake. There is.

Description

Transformer for substation

The present invention relates to a transformer for a substation with a new structure that can prevent damage due to earthquakes.

Generally, a substation is equipped with a plurality of transformers to adjust the voltage of electricity applied through a power plant or high-voltage line.

As shown in FIG. 1, the transformer consists of a base 1 provided on the bottom and a transformer body 2 provided on the top of the base 1.

The base (1) is made of concrete in the form of a square block.

The transformer body 2 is configured in the form of a square box with a smaller area than the base 1, and insulating oil is stored therein.

However, in such a transformer, when an earthquake occurs and the base (1) vibrates, not only physical damage occurs to the transformer body (2), but also insulation breakdown occurs as the insulating oil stored inside flows, and thus, the transformer There was a problem that the main body (2) could be damaged.

Therefore, a new method to solve these problems has become necessary.

Registered Patent No. 10-0604177,

The present invention is intended to solve the above problems, and its purpose is to provide a transformer for a substation with a new structure that can prevent damage due to earthquakes.

The present invention for achieving the above object is a transformer for a substation including a base (1) provided on the floor and a transformer body (2) provided on the top of the base (1). ) and a seismic unit (A) provided between the transformer body (2), wherein the seismic unit (A) is fixed to the upper surface of the base (1) and has a plurality of dome-shaped concave grooves ( 11) is provided on the lower side of the transformer body (2), and the lower support plate (10) is formed concave downward, and the upper support plate is formed with a protrusion (21) that protrudes downward to correspond to the concave groove (11). (20), a support ball (30) rotatably coupled to the lower end of the protrusion (21) and inserted into the concave groove (11), and a support ball (30) provided on the lower support plate (10) and the transformer body (2). It includes a pressing means 40 that presses downward to bring the support ball 30 into close contact with the concave groove 11, and a lubrication means 50 connected to the upper support plate 20, and the lower support plate 10 A discharge passage 12 is formed in the concave groove 11 to discharge the lubricant supplied by the lubricating means 50, and the support ball 30 is rotatably inserted into the lower side of the protrusion 21. A fixing groove 22 is formed to be fixed, and a lubricating passage 23 extending into the fixing groove 22 is formed inside the upper support plate 20, and the pressurizing means 40 is connected to the transformer body 2. ), a support frame 41 fixed to the lower support plate 10 to surround the upper part of the support frame 41, and a support frame 41 fixed to the support frame 41 and connected to the upper circumference of the transformer body 2 to move the transformer body 2 downward. It includes a plurality of compression coil springs 42 that pressurize, and the lubricating means 50 includes a storage cylinder 51 in which lubricating oil is stored and connected to the lubrication passage 23 through a supply pipe 52, and the storage A lubrication pump is provided in the middle of the cylinder 51 and supplies the lubricant stored in the storage cylinder 51 to the circumference of the support ball 30 inserted into the concave groove 11 through the lubrication passage 23 during operation. (53), an earthquake detection means 54 that is provided on the base 1 and detects the occurrence of an earthquake, and when an earthquake of a preset magnitude or higher is detected by receiving a signal from the earthquake detection means 54, the lubrication pump ( A transformer for a substation is provided, characterized in that it includes control means 55 for driving 53).

In the substation transformer according to the present invention, when an earthquake occurs and the base 1 and the lower support plate 10 move laterally, the transformer main body 2 does not move laterally and remains stationary.

At this time, the support ball 30 is inserted into the concave groove 11 of the lower support plate 10, and as the lower support plate 10 moves in the side direction, the concave groove 11 formed in the lower support plate 10 also moves laterally. direction, and at this time, the support ball 30 rises upward along the slope of the inner surface of the concave groove 11.

And, when the base (1) moves in the opposite direction, the support ball (30) and the lower support plate (10) repeatedly lower and rise, converting the lateral vibration generated in the base (1) into vertical vibration. Absorb it.

Therefore, it is possible to prevent the transformer body (2) from being damaged by moving laterally due to the kinetic energy of the base (1) and the lower support plate (10), which flow laterally due to an earthquake. There is.

1 is a front view showing a conventional transformer for a substation;
Figure 2 is a front cross-sectional view showing a transformer for a substation according to the present invention;
Figure 3 is an enlarged front cross-sectional view of the main part of Figure 2;
4 is a plan view of a transformer for a substation according to the present invention;
Figure 5 is a plan cross-sectional view showing the lower support plate of the transformer for a substation according to the present invention;
Figure 6 is a block diagram of a transformer for a substation according to the present invention;
Figure 7 is a front cross-sectional view showing the operation of the transformer for a substation according to the present invention.

Hereinafter, the present invention will be described in detail based on the attached illustration drawings.

2 to 7 show a transformer for a substation according to the present invention, which is provided with a base 1 provided on the bottom and a transformer body 2 provided on the top of the base 1, unlike the prior art. same.

The base (1) is made of concrete in the form of a square block.

The transformer body 2 is configured in the form of a square box with a smaller area than the base 1, and insulating oil is stored therein.

And, according to the present invention, an earthquake-resistant unit (A) is provided between the base (1) and the transformer body (2).

The earthquake-resistant unit (A) is fixed to the upper surface of the base (1) and has a lower support plate (10) on the upper surface of which a plurality of concave grooves (11) configured in a dome shape are concave downward, and the transformer body (2). An upper support plate 20 is provided on the lower side and has a protrusion 21 protruding downward to correspond to the concave groove 11, and is rotatably coupled to the lower end of the protrusion 21 and the concave groove ( A support ball 30 inserted into 11) and a pressurizing means provided on the lower support plate 10 to press the transformer body 2 downward so that the support ball 30 is in close contact with the concave groove 11 ( 40) and a lubricating means 50 connected to the upper support plate 20.

The lower support plate 10 is configured in the shape of a square plate with the same area as the base 1, and is fixed to the upper surface of the base 1 by fixing bolts so as not to move.

Four of the concave grooves 11 are formed close to the corners of the upper surface of the lower support plate 10.

Additionally, a discharge passage 12 is formed in the concave groove 11 to discharge the lubricating oil supplied by the lubricating means 50.

The discharge passage 12 extends downward from the center of the bottom surface of the four concave grooves 11, merges into one and extends to one side of the lower support plate 10, and has a collection container 13 for collecting lubricating oil. connected.

The upper support plate 20 is configured in the shape of a square plate with the same area as the transformer body 2, and is fixed to the lower side of the transformer body 2 with a fixing bolt.

The protrusion 21 is formed to be located on the upper side of the concave groove 11, and has a cone shape whose diameter decreases toward the bottom and whose lower end is flat.

The fixing groove 22 is formed concave upward in the central portion of the lower side of the protrusion 21.

At this time, the upper end of the fixing groove 22 is configured in a hemispherical shape corresponding to the diameter of the support ball 30, and the vertical depth of the fixing groove 22 is smaller than the diameter of the support ball 30. Thus, the lower peripheral surface of the support ball 30 inserted into the fixing groove 22 is configured to protrude downward from the protrusion 21.

In addition, a lubrication passage 23 extending into the fixing groove 22 is formed inside the upper support plate 20.

As shown in FIG. 5, the lubrication passage 23 has a supply portion 23a with one end extending to one side of the upper support plate 20, and a supply portion 23a that branches off from the horizontal passage and extends to the top of each fixing groove 22. It consists of a connected branch portion (23b).

As shown in FIGS. 2 and 4, the pressurizing means 40 includes a support frame 41 fixed to the lower support plate 10 to surround the upper part of the transformer body 2, and the support frame 41. It is fixed to and connected to the upper surface circumference of the transformer body (2) and uses a plurality of compression coil springs (42) that press the transformer body (2) downward.

The support frame 41 includes a horizontal portion 41a whose lateral width is longer than the width of the transformer main body 2, extends downward from both ends of the horizontal portion 41a, and has both ends of the lower support plate 10. ) consists of a vertical portion (41b) fixed to the upper surface of the.

The compression coil spring 42 extends in the vertical direction, with its upper end fixed to the lower side of the horizontal portion 41a and its lower end fixed to the upper surface of the transformer body 2.

The lubricating means 50 is provided with a storage cylinder 51 that stores lubricating oil inside and is connected to the lubrication passage 23 through a supply pipe 52, and in the middle of the storage cylinder 51, and is provided in the storage cylinder 51 when operating. A lubrication pump (53) is provided on the base (1) to supply the lubricant stored in (51) to the circumference of the support ball (30) inserted into the concave groove (11) through the lubrication passage (23). It consists of an earthquake detection means 54 that detects the occurrence of an earthquake, and a control means 55 that receives a signal from the earthquake detection means 54 and drives the lubrication pump 53 when an earthquake of a preset magnitude or higher is detected.

The lubricant is a liquid with a slight viscosity.

The lubrication pump 53 uses a high-pressure pump that can pressurize lubricating oil at high pressure and supply it to the lubricating passage 23 through the supply pipe 52.

The earthquake detection means 54 uses a seismometer or vibration sensor capable of detecting when the base 1 vibrates due to an earthquake.

The control means 55 receives a signal from the earthquake detection means 54 in a state in which the lubrication pump 53 is stopped, and when vibration exceeding a preset level is detected by the earthquake detection means 54, the control means 55 is shown in FIG. 7. As shown, the lubricating pump 53 is driven to supply the lubricating oil stored in the storage cylinder 51 to the lubricating passage 23.

When lubricating oil is supplied to the lubricating passage 23 in this way, the lubricating oil is supplied to the inner upper side of the fixing groove 22 and flows downward through the space between the support ball 30 and the fixing groove 22, thereby causing the support ball ( By minimizing the friction force generated when 30) rotates inside the fixing groove 22, the support ball 30 can rotate smoothly inside the fixing groove 22.

In the substation transformer constructed in this way, when an earthquake occurs and the base 1 and the lower support plate 10 move laterally as shown in FIG. 7, the transformer body 2 does not move laterally and remain stationary.

At this time, the support ball 30 is inserted into the concave groove 11 of the lower support plate 10, and as the lower support plate 10 moves in the side direction, the concave groove 11 formed in the lower support plate 10 also moves laterally. direction, and at this time, the support ball 30 rises upward along the slope of the inner surface of the concave groove 11.

And, when the base (1) moves in the opposite direction, the support ball (30) and the lower support plate (10) repeatedly lower and rise, converting the lateral vibration generated in the base (1) into vertical vibration. Absorb it.

Therefore, it is possible to prevent the transformer body (2) from being damaged by moving laterally due to the kinetic energy of the base (1) and the lower support plate (10), which flow laterally due to an earthquake. There is.

At this time, the control means 55 receives the signal from the earthquake detection means 54, confirms that the base 1 and the lower support plate 10 are moving, and drives the lubrication pump 53 to support the support ball 30. By minimizing the friction generated when rotating inside the fixing groove 22, the support ball 30 is allowed to rotate smoothly when the support ball 30 slides inside the concave groove 11, so that the support ball (30) 30) and the concave groove 11 or the fixing groove 22 have the advantage of preventing performance deterioration due to wear.

In addition, a discharge passage 12 for discharging the lubricant supplied by the lubrication means 50 is formed in the concave groove 11 of the lower support plate 10, so that the support ball ( The lubricating oil supplied to 30) flows downward and is then discharged to the outside through the discharge passage 12, so the lubricating oil supplied to the support ball 30 is first collected in the concave groove 11 and then discharged through the discharge passage (11). It is collected into the collection bin (13) through 12).

Therefore, the lubricant collected in the concave groove 11 is mixed with dust or other contaminants and hardens, preventing the support ball 30 from moving smoothly due to hardened foreign substances when moving inside the concave groove 11. There is an advantage in preventing this from happening.

In particular, as the pressing means 40 elastically presses the transformer body 2 downward, the transformer body 2 moves excessively in the vertical direction, causing the support ball 30 to move in the concave groove 11. It has the advantage of preventing separation and rapidly reducing the flow of the transformer main body (2).

1. Expectation 2. Transformer main body
10. Lower support plate 20. Upper support plate
30. Support ball 40. Pressurizing means
50. Lubrication means

Claims (1)

A base (1) provided on the floor,
In the substation transformer including a transformer body (2) provided on the upper part of the base (1),
It further includes an earthquake-resistant unit (A) provided between the base (1) and the transformer main body (2),
The earthquake-resistant unit (A) is
A lower support plate (10) fixed to the upper surface of the base (1) and having a plurality of dome-shaped concave grooves (11) concave downward on the upper surface;
An upper support plate (20) provided on the lower side of the transformer body (2) and having a protrusion (21) protruding downward to correspond to the concave groove (11) on the lower side;
A support ball (30) rotatably coupled to the lower end of the protrusion (21) and inserted into the concave groove (11),
Pressing means (40) provided on the lower support plate (10) and pressurizing the transformer body (2) downward so that the support ball (30) comes into close contact with the concave groove (11);
It includes a lubricating means (50) connected to the upper support plate (20),
A discharge passage 12 is formed in the concave groove 11 of the lower support plate 10 to discharge the lubricant supplied by the lubrication means 50,
A fixing groove 22 is formed on the lower side of the protrusion 21 into which the support ball 30 is rotatably inserted and fixed,
A lubrication passage 23 extending into the fixing groove 22 is formed inside the upper support plate 20,
The pressurizing means 40 is
A support frame (41) fixed to the lower support plate (10) to surround the upper part of the transformer body (2),
It is fixed to the support frame (41) and is connected to the upper surface circumference of the transformer body (2) and includes a plurality of compression coil springs (42) that press the transformer body (2) downward,
The lubricating means (50) is
A storage cylinder (51) in which lubricating oil is stored and connected to the lubrication passage (23) through a supply pipe (52),
It is provided in the middle part of the storage cylinder 51 so that during operation, the lubricant stored in the storage cylinder 51 is supplied to the circumference of the support ball 30 inserted into the concave groove 11 through the lubrication passage 23. A lubrication pump (53),
An earthquake detection means (54) provided on the base (1) and detecting the occurrence of an earthquake,
When an earthquake of a preset magnitude or higher is detected by receiving a signal from the earthquake detection means 54, the lubrication pump 53 is driven to supply the lubricant oil stored in the storage cylinder 51 to the lubrication passage 23. A transformer for a substation, characterized in that it includes control means (55) that causes lubricant to flow downward between the support ball (30) and the fixing groove (22).

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