KR102155107B1 - A seismic device equipped with a sensor for detecting an external force and a distribution board - Google Patents

Abstract

The present invention relates to a seismic device for distribution board having sensor for detecting external shock to prevent an accident. According to one embodiment of the present invention, the seismic device comprises: an upper housing; a lower housing fixed to face the upper housing to form an internal space with the upper housing; a seismic spring placed at the center of the internal space and fixed to the upper and lower housings to absorb an upward external shock; first to fourth leaf springs placed on both sides in pairs with respect to the seismic spring in the internal space and having an elastic curved part convexly curved toward the seismic spring; fifth and sixth leaf springs placed on both sides with respect to the seismic spring in the internal space and having an elastic curved part convexly formed in a direction from the lower housing to the upper housing; first and second sub seismic springs placed on a lower side of the elastic curved parts of the fifth and sixth leaf springs; a plurality of assembly bolts and nuts assembling the upper and lower housings, the seismic spring, the first to sixth leaf springs, and the first and second sub seismic springs; and a sensor unit sensing an external shock applied to the seismic device. Moreover, the lower housing includes guide grooves for inducing both ends of the fifth and sixth leaf springs to move in a preset direction when a vertical external shock is applied to the seismic device and the fifth and sixth leaf springs are fixed in the upper housing to place both the ends in the guide groove.

Description

A seismic device equipped with a sensor for detecting an external force and a distribution board}

The present specification proposes a seismic device equipped with a sensor that detects an external impact.

In general, distribution boards and switchboards are equipped with various circuit breakers and switchgear in an enclosure to draw and distribute power from the outside, and to selectively supply power at the same time. Such a distribution board includes an enclosure that prevents electric shock and safety accidents caused by various electricity in order to prevent the line from being exposed to the outside. In particular, distribution boards and switchboards include circuit breakers to achieve electrical safety by blocking current supply when an overload occurs in the process of distributing and supplying main power drawn from the outside to each electric load. This breaker may include a main breaker connected to the main input terminal and a plurality of branch breakers each connected to an electrical load.

On the other hand, distribution boards and switchboards have an internal type embedded in the wall of a building and an external type that is directly fixed to the wall through anchor bolts. However, in the case of the external type of distribution panel, when the distribution panel is fixed to the wall, a bolt structure that penetrates the inner side of the case of the distribution panel and is attached to the wall is used, so the rear surface of the distribution panel is in close contact with the wall and fixed. This structure may appear as a stable structure at first glance because the distribution board is completely in close contact with the wall, but has a disadvantage that is vulnerable to vibration or moisture.

In particular, since the distribution board is tightly fixed to the wall through a bolt structure, when vibration is transmitted through the wall when an earthquake occurs, the vibration is transmitted to the inside of the distribution panel through the bolt structure fixed to the wall. Accordingly, there is a problem that the vibration is transmitted to the internal structure of the distribution panel as it is, so that screws or other structures that fix various circuit devices are not only separated from the correct position, but also secondary damage is caused due to power outages and fire.

In addition, in general, the overall arrangement is a power receiving facility to receive the high voltage and special high voltage supplied from a substation, a substation facility to reduce the high and extra high voltage received from the substation to a commercial voltage, and It is a device that safely sends to lighting or electrical equipment.

In the overall arrangement, various electric devices such as transformers, switchgear, arresters, power fuses, converters, circuit breakers, detectors, and computer wattmeters are installed in the cubicle enclosure, and are provided with structures that attach and support them and conductors that connect or connect each device. .

All of these conventional arrangements are installed on the upper part of the foundation frame fixedly installed on the concrete floor, so when vibrations caused by earthquakes are transmitted as they are, various devices installed inside are damaged and short-circuited, causing power supply to be interrupted or, in extreme cases, a fire. There was this.

In order to solve the above problems, Korean Patent Registration No. 10-2064501 includes an enclosure disposed in an installation target area and an electric component installed therein; And four seismic devices interposed between the installation target area and the enclosure, each installed in a vicinity corresponding to each vertex of the enclosure, and buffering an external force transmitted to the enclosure, wherein the seismic device comprises: An upper plate fixedly installed on one side of the bottom surface of the upper plate; a lower plate spaced apart from the upper plate and supported on the ground; And a buffer unit interposed between the upper plate and the lower plate, wherein upper and lower ends of the buffer unit are connected to one side of the upper plate and the lower plate, respectively, and a pillar portion disposed perpendicular to the ground; the pillar; A coil spring installed so as to surround the part, and the upper and lower ends thereof are supported on the bottom surface of the upper plate and the upper surface of the lower plate, respectively, and have elasticity in the vertical direction; And a support having elasticity in the vertical direction, the upper part and the lower part being respectively coupled to the upper and lower parts of the column part, and having a pair installed opposite to each other with the column part interposed therebetween, and two sets of supports installed in a direction perpendicular to each other. Including a frame, wherein the support frame has a cross section in the shape of a \'ㄷ\' shape, so that each corner is formed on one side of the bent upper and lower portions, and a vertical area is formed to be curved with a preset curvature, and the upper and lower portions are respectively The bottom surface of the upper plate and the upper surface of the lower plate are in surface contact, and the upper plate and the lower plate are formed by stacking a pair of metal plates, respectively, and an end of the support frame on one side of the support frame in surface contact A switchboard with a seismic device, characterized in that the support groove is formed by being inserted, has been proposed.

Korean Patent Registration No. 10-2007908 discloses a switchgear seismic device installed between a switchgear and a concrete structure to absorb vibrations or shocks generated by an earthquake, comprising: a lower die; A circular first and second plate-shaped body having a different diameter on the upper part of the lower die and forming an incision in the lower center is positioned so as to be overlapped on the inside and outside, but pressing in the vertical direction is in contact with each other in the vertical direction and the horizontal direction is separated from each other. First and second leaf springs having an elliptical structure; A buffer member vertically installed at at least one or more positions inside the first leaf spring; And an assembly member that couples the lower die, the first and second leaf springs, and the buffer member to each other, and the first and second leaf springs are installed to cross each other orthogonally, and the buffer member has a side circumference in the vertical direction. An elliptical plate spring type switchgear seismic device is known, which is composed of a cushion tube forming a corrugation in the cushion tube) and a plurality of cushion balls embedded in the cushion tube.

However, the switchgear seismic devices shown in the patent documents disclosed in the above patent publications are configured to absorb the shock applied to the seismic device by the components of the seismic devices. However, the strength or displacement of the shock applied to the seismic device It is a structure that cannot detect the shock, and it is a structure that cannot install sensors that detect the displacement of the seismic device due to impact, and there is no suggestion of this.

Therefore, in this specification, it is intended to propose a seismic device for power distribution boards equipped with a sensor that detects external shocks to prevent safety accidents by mitigating external shocks applied to switchboards, distribution boards, and switchboards (hereinafter collectively referred to as switchboards). to be.

According to an embodiment of the present invention, in the seismic device provided with a sensor for detecting an external impact, the upper housing; A lower housing fixed to face the upper housing to form an inner space together with the upper housing; A vibration-proof spring located at the center of the inner space and fixed to the upper and lower housings to absorb external shocks in the vertical direction; First to fourth leaf springs located on both sides of the anti-vibration spring in the inner space, and having elastic bent portions convexly curved in the direction of the anti-vibration spring; Fifth and sixth leaf springs located on both sides of the vibration-proof spring in the inner space and having elastic curved portions convexly curved from the lower housing toward the upper housing; First and second sub-vibration isolating springs respectively positioned under the elastic curved portions of the fifth and sixth leaf springs; A plurality of assembly bolts and nuts for assembling the upper and lower housings, the anti-vibration spring, the first to sixth leaf springs, and the first and second sub anti-vibration springs; A sensor unit that senses an external shock applied to the seismic device, wherein the lower housing includes both ends of the fifth and sixth leaf springs as the external shock in the vertical direction is applied to the seismic device. Guide grooves for guiding them to move in a set direction are formed, and the fifth and sixth leaf springs may be fixed to the upper housing so that both ends thereof are located inside the guide groove.

In addition, the first and second leaf springs are positioned adjacent to each other so that the elastic curved portion faces the vibration-proof spring, and the third and fourth leaf springs are positioned adjacent to each other so that the elastic curved portion faces the vibration-proof spring, The first and second leaf springs and the third and fourth leaf springs may be positioned to face each other around the vibration-proof spring.

In addition, the fifth and sixth leaf springs may be positioned on both sides of the vibration-proof spring where the first to fourth leaf springs are not located, and may be positioned to face each other around the vibration-proof spring.

In addition, an upper surface of the anti-vibration spring may be fixed by contacting the upper housing and a lower surface thereof to the lower housing.

In addition, the first to fourth leaf springs have one end fixed to the upper housing so that the upper region of the elastic bent part is in contact with the upper housing, and the other end of the elastic curved part is in contact with the lower housing. It can be fixed to the lower housing.

In addition, the fifth and sixth leaf springs may be fixed to the upper housing such that a maximum curved point of the elastic curved portion contacts the upper housing and both ends of the elastic curved portion contact the bottom surface of the guide groove.

In addition, the movable ranges of both ends of the fifth and sixth leaf springs may be limited to the inside of the guide groove.

In addition, the sensor unit may include a vibration sensor, a touch sensor, a pressure sensor, and/or a proximity sensor.

In addition, when the sensor unit includes the touch sensor, the touch sensor may be disposed inside the guide groove.

In addition, when the sensor unit includes the touch sensor, the touch sensor may be disposed in the entire or part of the movable range of both ends of the fifth and sixth leaf springs in the guide groove.

In addition, when the touch sensor is disposed in a part of the movable range, the touch sensor may be disposed at a predetermined interval within the movable range.

In addition, the touch sensors may be disposed at narrow intervals toward the side from the center of the movable range.

In addition, when the touch sensor is disposed in a part of the movable range, the touch sensor may be disposed in a movable range region where both ends of the fifth and sixth leaf springs contact when the fifth and sixth leaf springs are fully extended. I can.

In addition, according to another embodiment of the present invention, there is provided a seismic device for a switchgear installed with a sensor for detecting an external shock, the seismic device for absorbing an external shock; And a seismic device accommodating unit having an inner space formed under the dust panel for accommodating the seismic device. Including,

The seismic device receiving portion: an upper frame portion accommodating an upper portion of the seismic device and fixing the upper housing; A lower frame part accommodating a lower part of the seismic device, the lower housing being fixed, and movable in a direction toward the upper frame part or away from the upper frame part according to the external impact; The seismic device comprises: an upper housing; A lower housing fixed to face the upper housing to form an inner space together with the upper housing; A vibration-proof spring located at the center of the inner space and fixed to the upper and lower housings to absorb external shocks in the vertical direction; First to fourth leaf springs located on both sides of the anti-vibration spring in the inner space, and having elastic bent portions convexly curved in the direction of the anti-vibration spring; Fifth and sixth leaf springs located on both sides of the vibration-proof spring in the inner space and having elastic curved portions convexly curved from the lower housing toward the upper housing; First and second sub anti-vibration springs respectively positioned under the elastic curved portions of the fifth and sixth leaf springs; A plurality of assembly bolts and nuts assembling through the upper and lower housings, the anti-vibration spring, the first to sixth leaf springs, and the first and second sub-vibration springs; A sensor unit for sensing an external shock applied to the seismic device, wherein when the external shock in the vertical direction is applied to the seismic device, the lower housing has both ends of the fifth and sixth leaf springs in a predetermined direction. Guide grooves for guiding it to be movable are formed, and the fifth and sixth leaf springs may be fixed on the lower housing so that both ends thereof are located inside the guide groove.

Although not specifically mentioned in the present invention, the output of the sensor unit may be connected to a seismic detection and alarm device or a control unit provided in the switchgear by electrical or communication means.

According to an embodiment of the present invention, since the seismic device mitigates various impacts applied to the switchboard from the outside, there is an effect that safety accidents can be prevented in advance.

In addition, the seismic device detects an external shock and is electrically or communicatively connected to a seismic detection or alarm device installed in the switchboard (not shown or explained because it is a known technology used in this field), so it may be caused by an external shock such as an earthquake. It has the effect of being able to recognize and prepare for secondary accidents in advance.

1 is a perspective view of a seismic device according to an embodiment of the present invention.
2 and 3 are exploded perspective views of a seismic device according to an embodiment of the present invention.
4 is a perspective view of a seismic device according to an embodiment of the present invention.
5 is a diagram illustrating a distribution board in which a seismic device according to an embodiment of the present invention is installed.
6 is a diagram illustrating a seismic device equipped with a touch sensor according to an embodiment of the present invention.

The technology to be described below may be modified in various ways and may have various embodiments, and specific embodiments will be illustrated in the drawings and described in detail. However, this is not intended to limit the technology to be described below with respect to a specific embodiment, and it should be understood to include all changes, equivalents, and substitutes included in the spirit and scope of the technology described below.

Terms such as 1st, 2nd, A, B, etc. may be used to describe various components, but the components are not limited by the above terms, only for the purpose of distinguishing one component from other components. Is only used. For example, without departing from the scope of the rights of the technology described below, a first component may be referred to as a second component, and similarly, a second component may be referred to as a first component. The term and/or includes a combination of a plurality of related listed items or any of a plurality of related listed items.

In terms of the terms used in the present specification, expressions in the singular should be understood as including plural expressions unless clearly interpreted differently in context, and terms such as "includes" are specified features, numbers, steps, actions, and components. It is to be understood that the presence or addition of one or more other features or numbers, step-acting components, parts or combinations thereof is not meant to imply the presence of, parts, or combinations thereof.

Prior to the detailed description of the drawings, it is intended to clarify that the division of the constituent parts in the present specification is only divided by the main function that each constituent part is responsible for. That is, two or more constituent parts to be described below may be combined into one constituent part, or one constituent part may be divided into two or more according to more subdivided functions. In addition, each of the constituent units to be described below may additionally perform some or all of the functions of other constituent units in addition to its own main function, and some of the main functions of each constituent unit are different. It goes without saying that it may be performed exclusively by.

In addition, in performing the method or operation method, each of the processes constituting the method may occur differently from the specified order unless a specific order is clearly stated in the context. That is, each process may occur in the same order as the specified order, may be performed substantially simultaneously, or may be performed in the reverse order.

1 is a perspective view of a seismic device according to an embodiment of the present invention. 2 and 3 are exploded perspective views of a seismic device according to an embodiment of the present invention. 4 is a perspective view of a seismic device according to an embodiment of the present invention. In particular, FIGS. 3 and 4 are views excluding the upper housing for convenience of description.

1 to 4, the seismic device 100 is largely an upper housing 110-1, a lower housing 110-2, a vibration isolation spring 120, and first to sixth leaf springs 130-1 to 130 -4, 150-1 to 150-2), first and second sub-vibration springs 140-1 to 140-2, and a plurality of assembly bolts and nuts (not shown).

The upper and lower housings 110-1 and 110-2 are disposed/fixed to face each other, and may form a constant inner space in which seismic accessories are disposed. The upper and lower housings 110-1 and 110-2 may have grooves of a certain shape/size for fixing seismic accessories. In particular, in the lower housing 110-2, guide grooves 160-1 to guide the movable range so that both ends of the fifth and sixth leaf springs 150-1 and 150-2 can be movable/moved in a preset direction. 160-4) is formed, which will be described later. The seismic accessories can be coupled/assembled with the upper and lower housings 110-1 and 110-2 by being pinched in the grooves of the upper and lower housings 110-1 and 110-2 formed in this way, and a plurality of assembly bolts and nuts It may be fixed to the upper and lower housings 110-1 and 110-2.

The anti-vibration spring 120 may be configured in the form of a spring having an elastic force in a specific direction (eg, vertical direction). The anti-vibration spring 120 may be located at the center of the inner space of the upper and lower housings 110-1 and 110-2, and the assembly bolt passes through the anti-vibration spring 120 to the upper and lower housings 110-1 and 110-2. By being combined with, it may be fixed to the upper and lower housings 110-1 and 110-2. In particular, the anti-vibration spring 120 has the upper and lower housings 110-1 and 110 so that the upper surface is in contact with the upper housing 110-1 and the lower housing 110-2 so as to absorb external shocks in the vertical direction. Can be fixed to -2). Therefore, as the external impact in the vertical direction is applied to the seismic device 100, the distance between the upper and lower housings becomes close, and a vibration-proof spring (which is in contact with the upper and lower housings 110-1 and 110-2 in the vertical direction) 120) is elastically compressed to alleviate the impact.

The first to sixth leaf springs 130-1 to 130-4 and 150-1 to 150-2 are composed of elastic plates having their own elastic restoring force, and absorb external shocks in the vertical direction like the vibration-proof spring 120 It can be placed in the interior space to be able to.

In more detail, each of the first to fourth leaf springs 130-1 to 130-4 may have an elastic curved portion that is convexly curved in the direction of the anti-vibration spring 120. The first to fourth leaf springs 130-1 to 130-4 may be located on both sides of the anti-vibration spring 120 in two in the inner space. More specifically, the first and second leaf springs 130-1 and 130-2 are located adjacent to each other so that the elastic curved portion faces the vibration-proof spring 120, and the third and fourth leaf springs 130-3, 130-4) Also, the elastic curved portions are located adjacent to each other toward the vibration-proof spring 120, but the first and second leaf springs 130-1 and 130-2 and the third and fourth leaf springs 130-1 , 130-4) may be positioned so as to face each other around the anti-vibration spring 120. For example, the first and second leaf springs 130-1 and 130-2 are in the west direction around the vibration-proof spring 120, and the third and fourth leaf springs 130-3 and 130-4 are Each of the anti-vibration springs 120 may be located in the east direction.

The first to fourth leaf springs 130-1 to 130-4 have one end fixed to the upper housing 110-1 so that the upper region of the elastic curved portion is in contact with the upper housing 110-1, and the elastic curved portion The other end may be fixed to the lower housing 110-2 so that the lower region is in contact with the lower housing 110-2. Therefore, as the external impact in the vertical direction is applied to the seismic device 100, the distance between the upper and lower housings 110-1 and 110-2 becomes close, and the upper and lower housings 110-1 and 110-2 The first to fourth leaf springs 130-1 to 130-4 which are in contact with each other in the direction are elastically compressed to reduce the impact.

Each of the fifth and sixth leaf springs 150-1 and 150-2 has an elastic curved portion convexly curved from the lower housing 110-2 to the upper housing 110-1. The fifth and sixth leaf springs 150-1 and 150-2 may be located on both sides of the anti-vibration spring 120 in the inner space. In particular, the fifth and sixth leaf springs 150-1 and 150-2 may be positioned so as to face each other around the vibration-proof spring 120, and the first to fourth leaf springs 130-1 to 130-4 ) May be located on both sides of the anti-vibration spring 120 is not located. For example, when the first to fourth leaf springs 130-1 to 130-4 are located on both sides in the east and west direction, the fifth leaf spring 150-1 is centered on the anti-vibration spring 120 In the south direction, the sixth leaf spring 150-2 may be respectively located in the north direction around the vibration-proof spring 120.

When an external impact in the vertical direction is applied to the lower housing 110-2, the fifth and sixth leaf springs 150-1 and 150-2 are compressed. Guide grooves 160-1 to 160-4 for guiding both ends of the leaf springs 150-1 and 150-2 to be movable/moved in a predetermined direction (or movable range) may be formed. In this case, both ends of the fifth and sixth leaf springs 150-1 and 150-2 may be fixed to the upper housing 110-1 so as to be located inside the guide grooves 160-1 to 160-4 ( Since it must be moved from the guide grooves 160-1 to 160-4 of the lower housing 110-2, it is not fixed to the lower housing 110-2), the fifth and sixth leaf springs 150-1, 150 The movable range of both ends of -2) is limited to the inside of the guide groove. In particular, the fifth and sixth leaf springs 150-1 and 150-2 have guide grooves 160-at both ends while the maximum bending point (or the peak of curvature) of the elastic curved portion is in contact with the upper housing 110-1. 1 to 160-4) may be fixed to the upper housing 110-1 in a form in contact with the bottom surface. Therefore, as the external shock in the vertical direction is applied to the seismic device 100, the distance between the upper and lower housings 110-1 and 110-2 becomes close, and the upper and lower housings 110-1 and 110-2 The fifth to sixth leaf springs 150-1 and 150-2, which are in contact with each other in the direction, are elastically compressed to mitigate the impact.

First and second sub-vibration springs 140-1 and 140-2 may be additionally provided to assist/reinforce the external shock relaxation function of the fifth and sixth leaf springs 150-1 and 150-2. have. The first and second sub-vibration isolating springs 140-1 and 140-2 may be configured in the form of springs having an elastic force in a specific direction (for example, in the vertical direction), like the vibration isolating spring 120 described above, The fifth and sixth leaf springs 150-1 and 150-2 may be positioned below the elastic curved portions, respectively. The first and second sub-vibration isolating springs 140-1 and 140-2 and the fifth and sixth leaf springs 150-1 and 150-2 penetrate them (especially, the fifth and sixth leaf springs 150- In the case of 1, 150-2), it may be coupled to the upper housing 110-1 by an assembly bolt penetrating through the elastic curved portion. The first and second sub-vibration springs 140-1 and 140-2 are in contact with the lower housing 110-2, but are not elastically curved portions of the fifth and sixth leaf springs 150-1 and 150-2 It may be arranged to be separated by a preset distance. That is, the first and second sub-vibration springs 140-1 and 140-2 are applied to the fifth and sixth leaf springs 150-1 and 150-2 according to an external impact of more than a preset size. After being compressed to a height or less, they may be arranged in a form supporting them in the vertical direction. Accordingly, the seismic device 100 of the present invention is primarily by the fifth and sixth leaf springs 150-1 and 150-2, and secondly, as the intensity of the external impact increases. And it discloses a structure in which the impact is further relieved by the second sub-vibration-proof springs 140-1 and 140-2.

In addition, although not separately shown in the drawings for convenience of description, the seismic device 100 is for stably coupling/assembling the above-described seismic accessories to the upper and/or lower housings 110-1 and 110-2. It may further include a plurality of assembly bolts and nuts.

The above-described seismic device can be applied to various electric devices that require a seismic function, such as a switchboard. Hereinafter, a description will be given of how the seismic device can be installed in these devices in detail and how to mitigate external shocks. Hereinafter, for convenience of explanation, the switchgear is mainly described, but the present invention is not limited thereto, and may be applied to other electric devices in the same/similar manner.

5 is a diagram illustrating a switchgear installed with a seismic device according to an embodiment of the present invention.

Referring to FIG. 5, the switchboard 500 may include a seismic device 100 for absorbing an external shock, and a seismic device accommodating part in which an inner space for accommodating the seismic device is formed.

Since the seismic device 100 corresponds to the seismic device described above with reference to FIGS. 1 to 4 above, a duplicate description will be omitted.

The seismic device receiving unit may be provided under the switchboard 500 and may include an upper frame part 510 and a lower frame part 520.

The upper frame part 510 is formed under the switchboard 500, accommodates the upper part of the seismic device 100, and may correspond to a frame part to which the upper housing 110-1 of the seismic device 100 is fixed. have. The lower frame part 520 may correspond to a frame part accommodating the lower part of the seismic device 100 and fixing the lower housing 110-2 of the seismic device 100.

That is, since the lower frame part 520 is fixed/coupled to the seismic device 100, not the upper frame part 510 of the seismic device storage unit, as the seismic device 100 is compressed or restored by an external shock, the lower side The frame unit 520 may also be movable in a direction toward the upper frame unit 510 or away from the upper frame unit 510 (ie, in a vertical direction).

Therefore, the seismic device 100 may be movable in the vertical direction to alleviate/absorb external shocks, and the seismic device receiving portion fixed to the seismic device 100 is also together with compression/restore of the seismic device 100 Can be compressed/restored (i.e., run together in the vertical direction)

Such a seismic device 100 may be electrically connected in electrical communication with a seismic detection device or an alarm device provided in the switchboard by sensing an external shock, and a control unit (not shown) that controls a breaker constituting the switchboard.

The sensor unit 620 provided in the seismic device of the present invention shown in FIGS. 4 and 6 can sense an external shock, and a control unit that controls the seismic detection device or alarm device and a circuit breaker constituting the switchgear. Can be provided. For example, the sensor unit 620 may include a vibration sensor, a touch sensor, a pressure sensor, and/or a proximity sensor to sense an external shock suitable for characteristics of each sensor. In particular, a vibration sensor and a pressure sensor may be installed in a seismic device and used to directly sense a physical external shock (eg, earthquake, sinkhole, etc.) applied to a switchboard or the like. In addition, the touch sensor, the pressure sensor, and/or the proximity sensor may be installed at a specific location of the seismic device and used to indirectly sense a physical external impact applied to a switchboard or the like. For example, a touch sensor, a pressure sensor, and/or a proximity sensor may indirectly sense a physical external impact applied to a switchboard or the like by sensing how much the seismic device is currently compressed. This embodiment will be described later with reference to FIG. 6.

6 is a description based on a touch sensor (that is, one of the sensors used in the sensor unit 620) according to an embodiment of the present invention, so that the same reference numerals as the sensor unit 620 are used below. Hereinafter, it is a diagram illustrating a seismic device equipped with a touch sensor 620).

6, the touch sensor 620 is formed in the lower housing 110-2 to set the movable range of the fifth and sixth leaf springs 150-1 (only the fifth leaf spring is shown in this drawing). It may be installed on the inner floor of the guide grooves 160-1 and 160-2. The reason why the touch sensor 620 is installed inside the guide grooves 160-1 and 160-2 is, through the touch sensor 620, both ends 180-of the fifth and sixth leaf springs 150-1 This is because the degree of compression of the seismic device can be indirectly derived by sensing where the position of 1, 180-2) is. In the seismic device, as both ends 180-1 and 180-2 of the fifth and sixth leaf springs 150-1 move from the center of the guide grooves 160-1, 160-2 to the side (in the direction of the arrow in the drawing) ) It can be determined that the degree of compression of the seismic device is increased, and accordingly, the strength of the external impact can be determined to increase gradually.

The touch sensor 620 is disposed in the entire or part of the movable range of both ends 180-1 and 180-2 of the fifth and sixth leaf springs 150-1 within the guide grooves 160-1 and 160-2. Can be.

As an embodiment, when the touch sensor 620 is installed in the entire interior of the guide grooves 160-1 and 160-2, the seismic device always operates at both ends 180- of the fifth and sixth leaf springs 150-1. Since it is possible to determine where 1, 180-2) is located, it has the advantage of being able to derive/monitor the intensity of external impact in real time in more detail.

As another embodiment, the plurality of touch sensors 620 may be disposed at predetermined intervals within the movable range of the guide grooves 180-1 and 180-2. In this case, the plurality of touch sensors 620 may be disposed at narrow intervals from the center of the movable range to the side (in the direction of the arrow in the drawing). In the case of this embodiment, the manufacturing cost is cheaper than the case where the touch sensor 620 is provided over the entire movable range.

In another embodiment, when the fifth and sixth leaf springs 150-1 are maximally opened, the touch sensor 620 is configured to be at both ends 180-1 and 180 of the fifth and sixth leaf springs 150-1. It may be disposed only in the movable range regions 170-1 and 170-2 that -2) touches. That is, this embodiment corresponds to an embodiment in which only the maximum force that the earthquake-resistant device can withstand is applied (that is, when the earthquake-resistant device is compressed to the maximum). In this embodiment, the sensing operation is simple and the manufacturing cost is the lowest.

In addition, as shown in Fig. 4, the touch sensor 620 may be installed on the first to fourth leaf springs 130-1 to 130-4.

In FIGS. 4 and 6, the touch sensor 620 has been described for convenience of description, but the present invention is not limited thereto, and a pressure sensor and/or a proximity sensor may be used instead of the touch sensor.

When the touch sensor 620 is installed all over the inside of the guide groove, the seismic device provides sensing information on the external impact to the switchboard only when both ends of the fifth and sixth leaf springs move beyond a predetermined distance inside the guide groove. It will be input to the control unit that controls the seismic detection device or alarm device and the circuit breaker constituting the switchgear. If, on the contrary, when the touch sensor is installed only in a part of the guide groove, sensing information on the external shock is immediately transmitted when both ends of the fifth and sixth leaf springs are sensed, a seismic detection device or an alarm device provided in the switchboard, and a switchboard. It will be input to the control unit that controls the circuit breaker.

Through these embodiments, the manager can more easily quickly recognize the danger situation that is being put on the switchboard, so that it can cope with safety accidents in advance, and can easily and stably manage the seismic device to prevent safety accidents in advance. The effect of being able to occur occurs.

For convenience of explanation, each drawing has been described separately, but it is also possible to design a new embodiment by merging the embodiments described in each drawing. In addition, the present invention is not limitedly applicable to the configuration and method of the embodiments described as described above, but the above-described embodiments are configured by selectively combining all or part of each embodiment so that various modifications can be made. It could be.

In addition, although preferred embodiments have been illustrated and described above, the present specification is not limited to the specific embodiments described above, and without departing from the subject matter claimed in the claims, those having ordinary knowledge in the technical field to which the specification belongs. Various modifications are possible by the person, as well as these modifications should not be individually understood from the technical idea or perspective of the present specification.

Seismic device: 100, upper housing: 110-1, lower housing: 110-2. Switchboard: 500, upper frame: 510, lower frame: 520, sensor: 620

Claims (8)

In the seismic device equipped with a sensor for detecting an external shock,
Upper housing;
A lower housing fixed to face the upper housing to form an inner space together with the upper housing;
A vibration-proof spring positioned at the center of the inner space and having upper and lower ends fixed to the upper and lower housings, respectively, to absorb external shocks in the vertical direction;
First to fourth leaf springs located on both sides of the anti-vibration spring in the inner space, and having elastic curved portions convexly curved toward the anti-vibration spring;
Fifth and sixth leaf springs located on both sides of the vibration-proof spring in the inner space and having elastic curved portions convexly curved from the lower housing toward the upper housing;
First and second sub-vibration isolating springs respectively positioned under the elastic curved portions of the fifth and sixth leaf springs; And,
A plurality of assembly bolts and nuts for assembling the upper and lower housings, the anti-vibration spring, the first to sixth leaf springs, and the first and second sub anti-vibration springs;
Including,
The fifth and sixth leaf springs are located on both sides of the anti-vibration spring in which the first to fourth leaf springs are not located, and are positioned to face each other around the anti-vibration spring,
In the lower housing, guide grooves are formed to guide both ends of the fifth and sixth leaf springs to move in a predetermined direction as the external impact in the vertical direction is applied to the seismic device,
The fifth and sixth leaf springs are fixed to the upper housing such that a maximum bending point of the elastic curved portion is in contact with the upper housing and both ends of the elastic curved portion are in contact with the inner bottom surface of the guide groove,
The movable range of both ends of the fifth and sixth leaf spring is limited to the inside of the guide groove,
Further comprising a sensor unit for sensing the external shock applied to the seismic device,
The sensor unit is a touch sensor installed over the entire movable range of both ends of the fifth and sixth leaf springs on the inner bottom of the guide groove, and by sensing the positions of both ends of the fifth and sixth leaf springs through the touch sensor Seismic device for switchgear installed with a sensor for detecting an external shock, characterized in that configured to determine the degree of compression of the seismic device. The method of claim 1,
The first and second leaf springs are positioned adjacent to each other so that the elastic curved portion faces the vibration-proof spring, and the third and fourth leaf springs are positioned adjacent to each other so that the elastic curved portion faces the vibration-proof spring,
The first and second leaf springs and the third and fourth leaf springs are located to face each other around the vibration-proof spring. The method of claim 2,
An upper surface of the anti-vibration spring is fixed in contact with the upper housing and a lower surface of the anti-vibration spring to the lower housing, respectively. The method of claim 3,
The first to fourth leaf springs,
An external impact, characterized in that one end is fixed to the upper housing so that the upper region of the elastic bent part is in contact with the upper housing, and the other end is fixed to the lower housing so that the lower region of the elastic bent part is in contact with the lower housing. A seismic-proof device for switchgear with a sensing sensor installed. delete delete delete delete

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