KR101134503B1 - Compound spring apparatus with non-linear wire rope spring and non-liner polyurethane spring for chaos elastic mount for high or low voltage switchgear and other equipment - Google Patents

Abstract

PURPOSE: A complex spring apparatus with a nonlinear wire rope spring and a nonlinear polyurethane spring for strong earthquake absorption is provided to absorb instantaneous load and horizontal pressure vibration by a nonlinear polyurethane spring. CONSTITUTION: A nonlinear wire rope spring(1) removes the vibration of a distribution panel or electrical devices. A wire rack(2) fixes the nonlinear wire rope spring at regular intervals to wind the nonlinear wire rope spring into the shape of a helical coil at regular intervals. The wire rack comprises an upper wire rack(21) and a lower wire rack(22). A polyurethanes spring(3) absorbs instantaneous and dynamic pressure due to strong earthquake, thereby reducing the amplitude of the nonlinear wire rope spring. An upper base(4) is fixed on the top of the upper wire rack. A lower base(5) is fixed to the lower part of the lower wire rack.

Description

Compound Spring Apparatus with Non-linear Wire Rope Spring and Non-liner Polyurethane Spring for Chaos Elastic Mount for High or Low Voltage Switchgear and Other Equipment}

The present invention relates to a spring device which is installed in the lower part of an electrical device such as a switchboard or a transformer to reduce the vibration caused by the earthquake to the elasticity of the spring to prevent damage to the switchboard or the electrical device. Weaving wire ropes made of many thin metal wires in multiple layers and winding the non-linear wire rope springs with flexural elasticity firmly in the transverse direction between the upper wire restraint receiving groove and the lower wire restraint receiving groove to prevent tension and flow in the front and rear directions. It is installed in the non-linear wire rope spring to serve as a stabilizer, to reduce the shaking in up and down, left and right oscillation, to stabilize the posture, and to control the movement and non-linearity of the non-linear wire rope spring. Non-linear pole with inclination Combination of polyurethane springs combined with steel seismic absorption type nonlinear wire ropes and nonlinear polyurethane springs that provide stable support by supporting nonlinear polyurethane springs to support wire elasticity that weakens with time due to weight such as switchboards. It relates to a composite spring device.

In general, a switchboard is an electrical installation that safely supplies industrial power to a user. The switchboard is a device used for monitoring, controlling, and protecting an electric system when the power sent from a power plant or substation is distributed to a customer.

Such a switchboard is composed of a structure that attaches and supports unit devices such as a circuit breaker or a protective relay, and a collection of conductors that connect and connect the unit devices, and safely stores and stores these various electric devices in a rectangular steel enclosure. .

However, since the switchboard is fixedly installed on the ground, when an earthquake occurs, deformation may occur in the enclosure provided in the switchboard due to the vibration of the earthquake wave, or various electrical devices installed inside the switchboard may be damaged, and in some cases, the switchboard may fall down. there was.

In this case, it is impossible to stably supply power where power is needed, and there are problems that problems such as electric shock may occur due to a short circuit.

Accordingly, even if the switchboard is vibrated by an earthquake or the like, the switchgear enclosure is not deformed and the internal electrical equipment is not damaged. It is required.

On the other hand, in order to solve the above problems, the 'earthquake-resistant switchgear using a non-directional elastic support' published by the inventors 10-1038672 and 10-1049407 to support the load of the switchboard between the ground and the switchboard. In addition, an elastic support for absorbing or cushioning vibrations or shocks transmitted from the ground is installed, and a rotation support is installed to support the switchboard. When an earthquake occurs, the rotation support is tilted so that the weight of the switchboard is applied to the elastic support. It is a structure that can safely protect against external shocks such as earthquakes.

However, the earthquake-proof switchgear using the non-directional elastic support having the structure as described above requires the normal operation of the rotational support by using the rotational support so that the weight of the switchboard exerts the seismic function by applying the weight to the elastic support. This is essential, but as the use time elapses, the rotation support may not work smoothly.

In addition, the 'earthquake-resistant switchgear using the electromagnetic force support and the non-directional elastic support' published by the present inventors Patent No. 10-1054686, the coil spring mount provided on the non-directional elastic support is external such as earthquake by the electromagnetic force support When the impact is not applied in normal times, it may be pressed by the load of the switchboard so that the appearance may not be deformed or lose its elasticity. The upper cover is pushed up by a certain height, so when only the non-linear wire rope spring is installed, the wire elastic force and the supporting force become weaker with time due to the product load, and thus the non-linear wire rope spring deflection can be prevented. In order to get complicated, malfunctions occur Even if the problems and their solutions, and the above two problems that must be maintained during power outages were a problem that required a lot of additional system cost.

The present invention for solving the above problems is installed in the lower part of the switchboard or electrical equipment to reduce the amplitude of the vibration generated by the earthquake to the elasticity of the spring to prevent damage to the switchboard or electrical equipment, the upper part such as the switchboard Combined spring device combining strong earthquake absorption type nonlinear wire rope and nonlinear polyurethane spring, which prevents non-linear wire rope spring sagging due to weakening of wire elasticity and supporting force over time by the installed device load In providing.

The composite spring device combining the strong earthquake absorption type nonlinear wire rope and the nonlinear polyurethane spring of the present invention is installed in the lower part of a switchboard or an electric device to reduce the amplitude of vibration caused by an earthquake to the elasticity of the spring to reduce the amplitude of the switchboard or the electric. It is a device to prevent damage to the equipment.

The spring device is made of a plurality of thin metal wire is wound around the coil, wound in the form of a spiral cylindrical coil non-linear wire rope spring to eliminate the vibration of the switchboard or electrical equipment generated by the earthquake; The nonlinear wire rope spring is fixed up and down at a predetermined interval so that the non-linear wire rope spring is wound in a spiral coil shape at regular intervals to evenly transmit the vibration generated by the earthquake to the nonlinear wire rope spring, the nonlinear wire rope A wire holder composed of an upper wire holder through which the upper coil portion of the spring passes and a lower wire fixture through which the lower coil portion of the nonlinear wire rope spring passes; It is installed inside the elliptic column coil formed by the nonlinear wire rope spring, and receives the load of the switchboard or the electric device installed on the upper side like the nonlinear wire rope spring, and the instantaneous dynamic pressure due to the strong earthquake causes the nonlinear wire rope spring. Polyurethane spring to reduce the amplitude of the non-linear wire rope spring by buffering the force applied to the; An upper base fixedly coupled to an upper portion of the upper wire holder and to which a switchboard or an electric device having a base frame formed thereon is coupled; It is fixedly coupled to the lower portion of the lower wire holder, it is composed of a lower base which is installed on the base plate formed on the base of the device.

The non-linear wire rope spring is vertical to the left and vertical to the right when viewed from the front and rear in the longitudinal direction of the coiled shape in order to offset the same size when the vibration caused by the earthquake occurs on the left side or on the right side Is a structure inclined at an angle.

The polyurethane spring is made of a material having a tensile strength of 50N / ㎜ and a compressive strength of 80N / ㎜ or more, and has a space between the non-linear wire rope and the left and right to absorb the shock generated during the left and right vibration, and the non-linear wire rope and polyurethane spring and It is a structure to reduce wear caused by friction.

The upper wire fixing plate has an upper wire fixing plate having an upper portion engaged with the upper base and a lower portion contacting the non-linear wire rope spring; An upper wire coupling plate fastened to the upper wire coupling plate, an upper portion of which is in contact with the nonlinear wire rope spring, and a lower portion of which is in contact with the polyurethane spring; An upper wire holder fastening bolt for fastening the upper wire fixing plate and the upper wire coupling plate; It consists of an upper base fastening bolt for fastening the upper wire holder and the upper base and the polyurethane spring.

A lower wire fixing plate having a lower portion fixed to a lower base and an upper portion contacting the non-linear wire rope spring; A lower wire coupling plate fastened to the lower wire fixing plate, a lower portion of the lower wire fixing plate and a non-linear wire rope spring, and an upper portion of the lower wire fixing plate being in close contact with the polyurethane spring; A lower wire holder fastening bolt for fastening the lower wire fixing plate and the lower wire coupling plate; It is composed of a lower base fastening bolt for fastening the lower wire holder and the lower base.

The upper wire fixing plate has a plurality of semi-circular wire rope spring through-holes through which the non-linear wire rope spring passes, and a lower wire coupling plate fastening bolt hole for inserting an upper wire fixing plate fastening bolt for fastening with the upper wire coupling plate. And an upper base fastening bolt hole through which an upper base fastening bolt for fastening with the upper base passes.

The upper wire coupling plate has an odd number of semicircular wire rope spring passing holes through which the non-linear wire rope spring passes, and an upper wire fixing plate fastening bolt hole to which the upper wire fixing plate fastening bolt for fastening with the upper wire fixing plate is fastened. The upper base fastening bolt hole through which the upper base fastening bolt for fastening to the upper base is formed.

The lower wire fixing plate fastening bolt hole for inserting a plurality of semi-circular wire rope spring through-holes through which the non-linear wire rope spring passes, and a lower wire fixing plate fastening bolt for fastening with the lower wire coupling plate. And a lower base fastening bolt hole through which a lower base fastening bolt for fastening with the lower base passes.

The lower wire fixing plate fastening plate hole for fastening the plurality of semi-circular wire rope spring passing holes through which the non-linear wire rope spring passes, and the lower wire fixing plate fastening bolt for fastening with the lower wire fixing plate. And a lower base fastening bolt hole through which a lower base fastening bolt for fastening with the lower base passes.

The polyurethane spring has an elliptic cylinder shape that is the same as that of the non-linear wire rope springs formed therein, and an upper portion of the rectangular upper wire coupling plate into which the upper wire coupling plate is inserted is formed in a longitudinal direction, and a lower wire at the bottom thereof. The lower wire coupling plate insertion groove into which the coupling plate is inserted is formed in the longitudinal direction, and the upper wire coupling plate insertion groove has a poly for fastening with the upper base fastening bolt to simultaneously couple the upper base, the upper wire holder and the polyurethane spring. Urethane spring bolt fixing hole is formed.

The lower wire coupling plate fastening bolt hole formed in the upper wire fixing plate is formed with a bolt head insertion part for preventing the bolt head of the upper wire fixing plate fastening bolt from being formed, and the upper base fastening bolt hole formed in the upper wire coupling plate. A female screw for screwing the bolt is formed, and the upper wire fixing plate fastening bolt hole formed in the upper wire coupling plate is formed with a female screw for screwing the upper wire holder fastening bolt.

The lower wire fixing plate fastening bolt hole formed in the lower wire fixing plate is formed with a bolt head inserting portion which prevents the bolt head of the lower wire fixing plate fastening bolt from being formed, and the lower wire fixing plate fastening bolt hole formed in the lower wire coupling plate has the lower portion. A female screw for screwing the wire fixing bolt to the fastening bolt is formed, and the lower base fastening bolt hole formed in the lower wire coupling plate is formed with a bolt head inserting portion that prevents the bolt head of the lower base fastening bolt from protruding.

The polyurethane spring bolt fixing hole has a screw is a structure that can be screwed with the upper base fastening bolt.

The problem to be solved of the present invention can be solved by the combination type spring device combining the above-described strong earthquake absorption type nonlinear wire rope and nonlinear polyurethane spring.

According to the composite spring combining the steel seismic absorption type nonlinear wire rope and nonlinear polyurethane spring of the present invention, the steel earthquake acts as a stabilizer as an assistant between the nonlinear wire rope and the wire rope having the elasticity and tension of the nonlinear wire rope during the earthquake. Non-linear polyurethane springs which reduce shaking during left and right vibrations and shocks, stabilize posture, controllability and elasticity of nonlinear wire rope springs, viscoelastic materials, and are not linear, and whose behavior is nonlinear due to strain and deformation speed. In combination with non-linear polyurethane springs that absorb instantaneous loads, left-right pressure vibrations, and are not significantly affected by external environmental factors, the wire elastic force and bearing capacity of the non-linear wire rope springs are increased over time by the product load. The weakening caused the sag of the nonlinear wire rope spring, but the nonlinear polyurethane spring is installed, and thus the bearing force function can be more effectively exhibited.

1 is a perspective view of a spring device combined according to a composite spring device combining a strong earthquake absorption type nonlinear wire rope and a nonlinear polyurethane spring
Figure 2 is a cross-sectional view of the spring device according to the composite spring device in combination with the earthquake-absorbing non-linear wire rope and non-linear polyurethane spring
Figure 3 is an exploded perspective view of the spring device according to the composite spring device combining the strong earthquake absorption type nonlinear wire rope and nonlinear polyurethane spring
Figure 4 is an example perspective view applied to the switchboard according to the composite spring device combining the strong earthquake absorption type nonlinear wire rope and nonlinear polyurethane spring
5 is a state wound in the form of a wire rope coil
Figure 6 is an exploded perspective view of the wire holder according to the composite spring device combining the earthquake-absorbing nonlinear wire rope and nonlinear polyurethane spring
7 is a schematic diagram of the upper wire fixing plate according to the composite spring device combining the strong earthquake absorption nonlinear wire rope and the nonlinear polyurethane spring
8 is a schematic diagram of the upper wire coupling plate according to the composite spring device combining the strong earthquake absorption type nonlinear wire rope and nonlinear polyurethane spring
9 is a schematic diagram of a lower wire fixing plate according to a composite spring device combining a strong earthquake absorbing nonlinear wire rope and a nonlinear polyurethane spring;
10 is a schematic diagram of a lower wire coupling plate according to a composite spring device combining a strong earthquake absorbing nonlinear wire rope and a nonlinear polyurethane spring;
11 is a schematic diagram of a polyurethane spring according to a combined spring device combining a strong earthquake absorbing nonlinear wire rope and a nonlinear polyurethane spring.
12 is a diagram illustrating the state of the spring device at the time of the pulling force action according to the combined spring device combining the earthquake-absorbing nonlinear wire rope and the nonlinear polyurethane spring.
13 is an explanatory view of the spring device state at the time of pressing force action according to the combined spring device combining the strong earthquake absorption type nonlinear wire rope and the nonlinear polyurethane spring.
14 is a diagram illustrating the state of the spring device when the left and right vibration occurs according to the combined spring device combining the strong earthquake absorption type nonlinear wire rope and the nonlinear polyurethane spring.
15 is an explanatory view of the spring device state when the front and rear vibration occurs according to the composite spring device combining the strong earthquake absorption type nonlinear wire rope and the nonlinear polyurethane spring.
16 is a diagram illustrating the state of the spring device when instantaneous dynamic pressure is applied due to a strong earthquake according to the combined spring device combining the strong earthquake absorption type nonlinear wire rope and the nonlinear polyurethane spring.
17 is a diagram illustrating the state of the spring device when all-weather vibration occurs according to the composite spring device combining the strong earthquake absorption type nonlinear wire rope and the nonlinear polyurethane spring.
18 is a diagram showing the complex spring displacement according to the composite spring device combining the strong earthquake absorption nonlinear wire rope and the nonlinear polyurethane spring.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS First, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

In addition, the terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or custom, and the definition thereof is defined as “strong earthquake absorbing nonlinear wire rope and nonlinear poly according to the present invention. It should be made based on the contents throughout the present specification for describing the "composite spring device combining the urethane spring".

Hereinafter, with reference to the drawings a preferred embodiment of the "complex spring device combining a strong earthquake absorption type non-linear wire rope and non-linear polyurethane spring" according to the present invention will be described in detail. The following examples are merely illustrative of the present invention and are not intended to limit the scope of the present invention.

1 is a perspective view of a spring device combined according to a composite spring device combining a strong earthquake absorption nonlinear wire rope and a non-linear polyurethane spring, Figure 2 is a combination of a strong earthquake absorption nonlinear wire rope and a non-linear polyurethane spring Figure 3 is a cross-sectional view of the spring device according to the spring device, Figure 3 is an exploded perspective view of the spring device according to the composite spring device combined with a strong earthquake absorbing nonlinear wire rope and a non-linear polyurethane spring, Figure 4 is a strong earthquake absorbing nonlinear wire rope and Example of application to a switchboard according to a composite spring device combining a non-linear polyurethane spring is a perspective view, Figure 5 is a state diagram wound in the form of a wire rope coil, Figure 6 is a combination of a strong earthquake absorption type non-linear wire rope and non-linear polyurethane spring 7 is an exploded perspective view of the wire holder according to the hybrid spring device, and FIG. Schematic diagram of the upper wire fixing plate according to the composite spring device combining the strong earthquake absorption nonlinear wire rope and the nonlinear polyurethane spring, Figure 8 is a composite spring device combining the strong earthquake absorption nonlinear wire rope and nonlinear polyurethane spring Fig. 9 is a schematic diagram of the upper wire coupling plate, and Fig. 9 is a schematic diagram of the bottom wire fixing plate according to the composite spring apparatus combining the strong seismic absorption nonlinear wire rope and the nonlinear polyurethane spring, and Fig. 10 is the strong earthquake absorption nonlinear wire rope and nonlinear A schematic diagram of a lower wire coupling plate according to a composite spring device combining polyurethane springs, and FIG. 11 is a schematic diagram of a polyurethane spring according to a composite spring device combining a strong earthquake absorbing nonlinear wire rope and a nonlinear polyurethane spring. 12 is a strong earthquake absorbing nonlinear wire rope and Fig. 13 is a diagram illustrating the state of the spring device when the pulling force is applied according to the combined spring device in which the linear polyurethane spring is combined. Fig. 13 shows the pressing according to the combined spring device in which the strong earthquake absorption type nonlinear wire rope and the nonlinear polyurethane spring are combined. Fig. 14 is a diagram illustrating the state of the spring device when the force is applied, and Fig. 14 is a view illustrating the state of the spring device when the left and right vibrations are generated according to the combined spring device combining the strong earthquake absorption type nonlinear wire rope and the nonlinear polyurethane spring. Fig. 16 is a diagram illustrating the state of a spring device when vibration occurs in front and rear according to a composite spring device combining a strong earthquake absorption nonlinear wire rope and a nonlinear polyurethane spring. FIG. 16 is a combination of a strong earthquake absorption nonlinear wire rope and a nonlinear polyurethane spring. Momentary dynamic pressure due to a strong earthquake Fig. 17 is an explanatory view of the spring device state at the time, and Fig. 17 is an explanatory view of the spring device state when all-weather vibration occurs according to the combined spring device combining the strong earthquake absorption type nonlinear wire rope and the nonlinear polyurethane spring. A diagram of the combined spring displacement of a combined spring device combining an absorbent nonlinear wire rope and a nonlinear polyurethane spring.

As shown in Fig. 1, Fig. 2 and Fig. 3, the composite spring device combining the earthquake-absorbing nonlinear wire rope and the nonlinear polyurethane spring of the present invention is installed in the lower part of the switchboard A or the electric equipment to be earthquake-proof. The vibration generated by the spring to reduce the amplitude of the elastic device to prevent damage to the switchboard or electrical equipment.

The spring device is made of a thin metal wire wound in multiple layers, wound in the form of a spiral cylindrical coil non-linear wire rope spring (1) to eliminate the vibration of the switchboard (A) or electrical equipment generated by the earthquake and ; The nonlinear wire rope spring 1 is fixed up and down at a predetermined interval so that the nonlinear wire rope spring 1 can be wound in a spiral coil shape at a predetermined interval to evenly vibrate the vibration generated by the earthquake. And an upper wire holder 21 through which the upper coil part of the nonlinear wire rope spring 1 passes and a lower wire fixture 22 through which the lower coil part of the nonlinear wire rope spring 1 passes. A wire holder 2; It is installed inside the elliptic column coil formed by the nonlinear wire rope spring (1), receives the load of the switchboard (A) or electrical equipment installed on the upper side as the nonlinear wire rope spring (1), A polyurethane spring (3) which reduces the amplitude of the nonlinear wire rope spring (1) by buffering the force exerted by the dynamic pressure due to the nonlinear wire rope spring (1); An upper base (4) fixedly coupled to an upper portion of the upper wire holder (21), to which a switchgear or an electric device having a base frame formed thereon is coupled; It is fixedly coupled to the lower portion of the lower wire holder 22, and consists of a lower base (5) installed on the base plate formed on the base of the device in the lower portion.

That is, the spring device is composed of a non-linear wire rope spring (1), a wire holder (2), a polyurethane spring (3), an upper base (4) and a lower base (5).

The non-linear wire rope spring (1) is produced by winding a plurality of thin metal wire is wound, wound in the form of a spiral cylindrical coil serves to eliminate the vibration of the switchboard (A) or electrical equipment generated by the earthquake. .

The wire holder 2 is fixed evenly up and down the non-linear wire rope spring (1) at regular intervals so that the non-linear wire rope spring (1) is wound in a spiral coil shape of a predetermined interval evenly to the vibration generated by the earthquake. A lower portion through which the upper wire holder 21 and the lower coil portion of the non-linear wire rope spring 1 pass, passing through the non-linear wire rope spring 1 and passing through the upper coil portion of the non-linear wire rope spring 1. It consists of the wire holder 22.

The polyurethane spring 3 is installed inside an elliptic cylinder coil formed by the nonlinear wire rope spring 1, and loads the load of the switchboard A or an electric device installed on the nonlinear wire rope spring 1. As a result, the instantaneous dynamic pressure due to the strong earthquake buffers the force applied to the nonlinear wire rope spring 1 and serves to reduce the amplitude of the nonlinear wire rope spring 1.

The upper base 4 is fixedly coupled to the upper portion of the upper wire holder 21, the switchboard or electrical equipment is coupled to the base frame is formed on the top of the non-linear wire rope spring (1) ) And polyurethane spring (3).

The lower base 5 is fixedly coupled to the lower portion of the lower wire holder 22, is installed on the base plate formed on the base of the device at the bottom, and serves to support the load of the switchboard (A) or electrical equipment.

The upper wire holder 21 has an upper wire fixing plate 211 which is connected to the upper base and the upper base 4 and the lower portion is in contact with the non-linear wire rope spring 1; The upper wire coupling plate 211 is fastened to the upper portion, the upper portion is in contact with the upper wire fixing plate 211 and the non-linear wire rope spring (1), the lower portion is in contact with the polyurethane spring (3) Plate 212; An upper wire holder fastening bolt 213 for fastening the upper wire fixing plate 211 and the upper wire coupling plate 212; It consists of an upper base fastening bolt 214 for fastening the upper wire holder 21 and the upper base 4 and the polyurethane spring (3).

The lower wire holder 22 has a lower wire fixing plate 221 which is fastened to a lower base and a lower base to be in contact with the non-linear wire rope spring 1; The lower wire fixing plate 221 is fastened to the lower portion, the lower portion is in contact with the lower wire fixing plate 221 and the non-linear wire rope spring (1), the upper portion of the lower wire coupling plate in close contact with the polyurethane spring (3) 222; A lower wire fixing bolt 223 for fastening the lower wire fixing plate 221 and the lower wire coupling plate 222; It is composed of a lower base fastening bolt 224 for fastening the lower wire holder 22 and the lower base (5).

As shown in the cross section of FIG. 2, the polyurethane spring 3 has a space between the nonlinear wire rope spring 1 and the left and right to absorb the shock generated when the left and right oscillations and the nonlinear wire rope spring 1 due to the vibration. ), It is desirable to reduce wear due to friction between the polyurethane spring (3).

The interaction between the non-linear wire rope spring 1 and the polyurethane spring 3 when vibration occurs in various directions will be further described in detail with reference to FIGS. 12 to 17.

Spring device of the present invention serves as a stabilizer to assist between the non-linear wire rope and the wire rope having the elastic force and tensile force of the non-linear wire rope spring (1) in the event of a strong earthquake, to reduce shaking in the vertical and horizontal vibration and impact and to stabilize the posture And nonlinear polyurethane springs with the maneuverability and elasticity of nonlinear wire rope springs, viscoelastic material and not linear, whose behavior is nonlinear by strain and strain rate, absorbs instantaneous load and left and right pressure vibration When installing only nonlinear wire rope springs by installing nonlinear polyurethane springs that are not significantly affected by external environmental factors, the wire elastic force and bearing capacity weaken over time due to the product load, resulting in deflection of nonlinear wire rope springs. By installing the bearing capacity function for the polyurethane spring it can exhibit more effectively.

Figure 4 is an example perspective view applied to the switchboard according to the composite spring device combined with a strong earthquake absorbing nonlinear wire rope and a non-linear polyurethane spring, the spring device of the present invention is installed in the lower part of the switchboard (A) or by the earthquake The vibration generated is a device that prevents damage to the switchboard or the electrical equipment by reducing the amplitude of the spring by elasticity, and the spring apparatus of the present invention may be used in an appropriate amount according to the load of the switchboard A or the equipment.

As shown in FIG. 5, the non-linear wire rope spring 1 has a shape wound in the form of a coil in the longitudinal direction from the front and the rear in order to offset the same size when the vibration caused by the earthquake occurs on the left side or the right side. When viewed from the center, the right side is vertical and the left side is inclined at an angle.

The non-linear wire rope spring (1) is wound in the shape as shown in the figure can cancel the vibration regardless of whether the vibration caused by the earthquake occurs on the left side or the right side.

As shown in Figure 6, the wire holder 2 is fixed to the non-linear wire rope spring (1) up and down at regular intervals so that the non-linear wire rope spring (1) can be wound in a spiral coil shape of a predetermined interval It serves to evenly transmit the vibration generated by the earthquake to the non-linear wire rope spring (1).

The wire holder 2 has an upper wire holder 21 through which the upper coil portion of the nonlinear wire rope spring 1 passes and a lower wire fixture 22 through which the lower coil portion of the nonlinear wire rope spring 1 passes. It consists of.

The upper wire holder 21 has an upper wire fixing plate 211 which is connected to the upper base and the upper base 4 and the lower portion is in contact with the non-linear wire rope spring 1; The upper wire coupling plate 211 is fastened to the upper portion, the upper portion is in contact with the upper wire fixing plate 211 and the non-linear wire rope spring (1), the lower portion is in contact with the polyurethane spring (3) Plate 212; An upper wire holder fastening bolt 213 for fastening the upper wire fixing plate 211 and the upper wire coupling plate 212; It consists of an upper base fastening bolt 214 for fastening the upper wire holder 21 and the upper base 4 and the polyurethane spring (3).

The lower wire holder 22 has a lower wire fixing plate 221 which is fastened to a lower base and a lower base to be in contact with the non-linear wire rope spring 1; The lower wire fixing plate 221 is fastened to the lower portion, the lower portion is in contact with the lower wire fixing plate 221 and the non-linear wire rope spring (1), the upper portion of the lower wire coupling plate in close contact with the polyurethane spring (3) 222; A lower wire fixing bolt 223 for fastening the lower wire fixing plate 221 and the lower wire coupling plate 222; It is composed of a lower base fastening bolt 224 for fastening the lower wire holder 22 and the lower base (5).

As shown in FIG. 7, the upper wire fixing plate 211 is engaged with the upper base 4 and the lower portion is in contact with the nonlinear wire rope spring 1.

The upper wire fixing plate 211 has an odd number of semicircular wire rope spring passing holes 2111 through which the non-linear wire rope spring 1 passes, and the upper wire for fastening with the upper wire coupling plate 212. The lower wire coupling plate fastening bolt hole 2112 into which the fastening bolt fastening bolt 213 is inserted, and the upper base fastening bolt hole 2123 through which the upper base fastening bolt 214 for fastening with the upper base 4 passes. Is formed.

The lower wire coupling plate fastening bolt hole 2112 formed in the upper wire fixing plate 211 is formed with a bolt head insertion portion 21121 which prevents the bolt head of the upper wire fixing plate fastening bolt 213 from protruding.

As shown in FIG. 8, the upper wire coupling plate 212 is fastened to the upper wire coupling plate 211, and the upper portion contacts the upper wire fixing plate 211 and the nonlinear wire rope spring 1. The lower part is in contact with the polyurethane spring 3.

The upper wire coupling plate 212 has an odd number of semi-circular wire rope spring through holes 2121 through which the non-linear wire rope spring 1 passes, and the upper wire fixing plate for fastening with the upper wire fixing plate 211. An upper wire fixing plate fastening bolt hole 2122 to which the fastening bolt 213 is fastened, and an upper base fastening bolt hole 2123 through which the upper base fastening bolt 214 for fastening with the upper base 4 is formed. .

The upper base fastening bolt hole 2123 formed in the upper wire coupling plate 212 is formed with a female screw for screwing the upper base fastening bolt 214.

The upper wire fixing plate fastening bolt hole 2122 formed in the upper wire coupling plate 212 is formed with a female screw for screwing the upper wire fixing plate fastening bolt 213.

As shown in FIG. 9, the lower wire fixing plate 221 has a lower portion engaged with a lower base 5 and an upper portion contacted with the non-linear wire rope spring 1.

The lower wire fixing plate 221 has a plurality of semicircular wire rope spring passing holes 2211 for the odd number of non-linear wire ropes 1 to pass through, and a lower wire fixing plate for fastening with the lower wire coupling plate 222. A lower wire coupling plate fastening bolt hole 2212 into which the bolt 223 is inserted and a lower base fastening bolt hole 2213 through which the lower base fastening bolt 224 for fastening with the lower base 5 are formed. .

The lower wire fixing plate fastening bolt hole 2212 formed in the lower wire fixing plate 221 is formed with a bolt head inserting portion 22121 which prevents the bolt head of the lower wire fixing plate fastening bolt 223 from protruding.

As shown in FIG. 10, the lower wire coupling plate 222 is fastened to the lower wire fixing plate 221, and the lower portion contacts the lower wire fixing plate 221 and the non-linear wire rope spring 1. , The upper part is in close contact with the polyurethane spring (3).

The lower wire coupling plate 222 has an odd number of semicircular wire rope spring through holes 2221 through which the nonlinear wire rope spring 1 passes, and the lower wire for fastening with the lower wire fixing plate 221. The lower wire fixing plate fastening bolt hole 2222 to which the fixing bar fastening bolt 223 is fastened, and the lower base fastening bolt hole 2223 through which the lower base fastening bolt 224 for fastening with the lower base 5 are formed. do.

The lower wire fixing plate fastening bolt hole 2222 formed in the lower wire coupling plate 222 has a female screw for screwing the lower wire fixing plate fastening bolt 223.

The lower base fastening bolt hole 2223 formed in the lower wire coupling plate 222 is formed with a bolt head inserting portion 222231 which prevents the bolt head of the lower base fastening bolt 224 from protruding.

As shown in FIG. 11, the polyurethane spring 3 is installed in close contact with an elliptic column coil formed by the non-linear wire rope spring 1, and the top of the switchboard A or the electric device installed at the top. The load is received together with the nonlinear wire rope spring (1), and the instantaneous dynamic pressure due to the strong earthquake buffers the force applied to the nonlinear wire rope spring (1) to reduce the amplitude of the nonlinear wire rope spring (1). Play a role.

The polyurethane spring 3 should be made of a material having a tensile strength of 50N / mm 2 and a compressive strength of 80N / mm 2 or more.

The polyurethane spring 3 has an elliptic cylinder shape that is the same as that of the non-linear wire rope spring 1 formed therein, and a rectangular upper wire coupling plate insertion groove into which the upper wire coupling plate 212 is inserted. 31 is formed in the longitudinal direction, and the lower wire coupling plate insertion groove 32 into which the lower wire coupling plate 222 is inserted is formed in the longitudinal direction.

Polyurethane for fastening with the upper base fastening bolt 214 to the upper wire coupling plate insertion groove 31 is the upper base 4, the upper wire holder 21 and the polyurethane spring 3 is coupled at the same time The spring bolt fixing hole 311 is formed.

The polyurethane spring bolt fixing hole 311 is formed with a screw is a structure that can be screwed with the upper base fastening bolt 214.

12 is an explanatory view of the spring device state when the pulling force is applied, the tension force is increased by the non-linear wire rope spring 1 is firmly intertwined with each other when the pulling force is applied, the polyurethane spring (3) is gathered Not only reduces the fatigue of the non-linear wire rope spring 1, but also absorbs the shock upon restoration.

Fig. 13 is an explanatory view of the state of the spring device at the time of the pressing force, in which the non-linear wire rope spring 1 spreads when the pressing force is applied, as well as dispersing the impact, and the polyurethane spring 3 absorbs the impact and the nonlinear Absorb the resonance phenomenon and rolling phenomenon of the wire rope spring (1).

Fig. 14 is a diagram illustrating the state of the spring device when the left and right vibrations are generated. In addition, the non-linear wire rope spring 1 spreads when the left and right vibrations are generated, and the polyurethane spring 3 absorbs the shocks. Absorption and rolling of the nonlinear wire rope spring 1 are absorbed.

Fig. 15 is a diagram illustrating the state of the spring device when vibration occurs back and forth, wherein the non-linear wire rope springs 1 are firmly woven together and at the same time disperse the impact, and the polyurethane spring 3 absorbs the shock and the non-linear It absorbs the resonance phenomenon and the rolling phenomenon of the wire rope spring (1), the upper base fastening bolt 214 is fixed to the polyurethane spring bolt fixing hole (311) when the polyurethane spring (3) when the front and rear oscillation Falling prevention and vibration suppression effect.

FIG. 16 is an explanatory view of a spring device when instantaneous dynamic pressure is applied due to a strong earthquake, and the polyurethane spring 3 not only buffers the force applied to the nonlinear wire rope spring 1 but also complex spring displacement. And spreads a plurality of wires of the non-linear wire rope spring 1 to spread the pressure applied to the polyurethane spring 3.

17 is an explanatory view of a spring device state when all-weather vibration occurs, and the non-linear wire rope spring 1 and the polyurethane spring 3 are closely attached to the non-linear wire rope spring 1 at the moment of downward downward and leftward pressure. Not only does the polyurethane spring 3 dampen the holding force, but also the complex spring displacement occurs, and the instantaneous downward and rightward pressure attempts also cause the nonlinear wire rope spring 1 and the polyurethane spring 3 to be in close contact with the nonlinear wire. The polyurethane spring 3 not only buffers the force applied to the rope spring 1 but also causes a complex spring displacement, and when the vibration occurs from side to side, the non-linear wire rope spring 1 spreads not only to disperse the impact. The polyurethane spring (3) absorbs the rolling and resonance of the non-linear wire rope spring (1), a large number of wire By spreading and dispersing the pressure applied to the polyurethane spring (1).

18 is a displacement diagram of a composite spring. When the composite spring is displaced, the nonlinear wire rope spring shows a nonlinear curve as the vibration intensity increases when the vibration is applied to the nonlinear wire rope spring and the nonlinear polyurethane spring. Displacement rises to the maximum in the part combined with urethane spring, but stabilizes with parallel curve even if vibration intensity is increased by vibration absorption by nonlinear polyurethane spring. The spring is restored gradually diagonally by nonlinear polyurethane springs, and then secondly by nonlinear wire rope springs to restore nonlinear curves, as shown in the graph below. arrow The interval represents the composite spring displacement interval.

According to the composite spring combining the steel seismic absorption type nonlinear wire rope and nonlinear polyurethane spring of the present invention, the stabilizer assists between the nonlinear wire rope and the wire rope having elasticity and tensile force of the nonlinear wire rope spring 1 in the event of a strong earthquake. Its function is to reduce shaking during up and down, left and right vibration and impact, to stabilize the posture, and to control the elasticity and elasticity of the nonlinear wire rope spring (1). It is a viscoelastic material and not linear, and its behavior is nonlinear due to strain and deformation speed. Non-linear polyurethane springs (3) in combination with non-linear wire rope springs (1) by combining non-linear polyurethane springs (3) which absorb instantaneous loads and lateral pressure vibrations and are not significantly affected by external environmental factors. Only as time passes by the installed product load Subsequently, the elastic force and the supporting force are weakened, so that the deflection phenomenon of the nonlinear wire rope spring 1 occurs, but by installing the nonlinear polyurethane spring 2, there is an effect that the bearing force function can be more effectively exhibited.

A: switchboard
1 non-linear wire rope spring 2 wire holder
21: upper wire holder 211: upper wire holder
2111: wire rope spring through hole
2112: Lower wire coupling plate fastening bolt hole
21121: Bolt head insertion portion 2113: Upper base tightening bolt hole
212: upper wire coupling plate 2121: wire rope spring through hole
2122: upper wire fixing plate fastening bolt hole
2123: upper base fastening bolt hole 213: upper wire fixing bolt fastening bolt
214: upper base fastening bolt 22: lower wire holder
221: lower wire fixing plate 2211: wire rope spring through hole
2212: Lower wire coupling plate fastening bolt hole
22121: Bolt head insertion portion 2213: Lower base fastening bolt hole
222: lower wire coupling plate 2221: wire rope spring through hole
2222: Lower wire fixing plate fastening bolt hole
2223: lower base tightening bolt hole 22231: bolt head insert
223: lower wire fixing bolt fastening bolt 224: lower base fastening bolt
3: polyurethane spring 31: upper wire coupling plate insertion groove
311: polyurethane spring bolt fixing hole
32: lower wire coupling plate insertion groove
4: Upper base 41: Tightening bolt hole
5: Lower base 51: Tightening bolt hole

Claims (6)

In the spring device which is installed in the lower part of the switchboard (A) or the electric equipment to reduce the vibration generated by the earthquake to the elasticity of the spring to prevent damage to the switchboard or the electrical equipment,
The spring device is made of a thin metal wire wound in multiple layers, wound in the form of a spiral cylindrical coil non-linear wire rope spring (1) to eliminate the vibration of the switchboard (A) or electrical equipment generated by the earthquake and ;
The nonlinear wire rope spring 1 is fixed up and down at a predetermined interval so that the nonlinear wire rope spring 1 can be wound in a spiral coil shape at a predetermined interval to evenly vibrate the vibration generated by the earthquake. And an upper wire holder 21 through which the upper coil part of the nonlinear wire rope spring 1 passes and a lower wire fixture 22 through which the lower coil part of the nonlinear wire rope spring 1 passes. A wire holder 2;
It is installed inside the elliptic column coil formed by the nonlinear wire rope spring (1), receives the load of the switchboard (A) or electrical equipment installed on the upper side as the nonlinear wire rope spring (1), A polyurethane spring (3) which reduces the amplitude of the nonlinear wire rope spring (1) by buffering the force exerted by the dynamic pressure due to the nonlinear wire rope spring (1);
An upper base (4) fixedly coupled to an upper portion of the upper wire holder (21), to which a switchgear or an electric device having a base frame formed thereon is coupled;
It is fixedly coupled to the lower portion of the lower wire holder 22, consists of a lower base (5) is installed on the base plate formed on the base of the device at the bottom,
The polyurethane spring (3) absorbs the shock generated during the left and right vibration and space between the non-linear wire rope spring (1) and the left and right to reduce the wear caused by friction with the non-linear wire rope spring (1) due to vibration Combined spring device combining strong earthquake absorption type nonlinear wire rope and nonlinear polyurethane spring
The method of claim 1,
The non-linear wire rope spring (1) is the right side relative to the center when viewed from the front and rear in the longitudinal direction of the coil wound shape in order to offset the same size when the vibration caused by the earthquake occurs on the left side or on the right side Combination spring device combining a strong earthquake absorption type nonlinear wire rope and nonlinear polyurethane spring, characterized in that the structure is vertical and the left side is inclined at a predetermined angle
The method of claim 1,
The polyurethane spring (3) is a composite spring device combining a strong earthquake absorption type nonlinear wire rope and nonlinear polyurethane spring, characterized in that the material of tensile strength 50N / mm ² , compressive strength 80N / mm ² or more
delete The method of claim 1,
The upper wire holder 21 has an upper wire fixing plate 211 which is connected to the upper base and the upper base 4 and the lower portion is in contact with the non-linear wire rope spring 1;
The upper wire coupling plate 211 is fastened to the upper portion, the upper portion is in contact with the upper wire fixing plate 211 and the non-linear wire rope spring (1), the lower portion is in contact with the polyurethane spring (3) Plate 212;
An upper wire holder fastening bolt 213 for fastening the upper wire fixing plate 211 and the upper wire coupling plate 212;
It consists of an upper base fastening bolt 214 for fastening the upper wire holder 21 and the upper base 4 and the polyurethane spring (3),
The lower wire holder 22 has a lower wire fixing plate 221 which is fastened to a lower base and a lower base to be in contact with the non-linear wire rope spring 1;
The lower wire fixing plate 221 is fastened to the lower portion, the lower portion is in contact with the lower wire fixing plate 221 and the non-linear wire rope spring (1), the upper portion of the lower wire coupling plate in close contact with the polyurethane spring (3) 222;
A lower wire fixing bolt 223 for fastening the lower wire fixing plate 221 and the lower wire coupling plate 222;
It is composed of a lower base fastening bolt 224 for fastening the lower wire holder 22 and the lower base 5,
The upper wire fixing plate 211 has an odd number of semicircular wire rope spring passing holes 2111 through which the non-linear wire rope spring 1 passes, and the upper wire for fastening with the upper wire coupling plate 212. The lower wire coupling plate fastening bolt hole 2112 into which the fastening bolt fastening bolt 213 is inserted, and the upper base fastening bolt hole 2123 through which the upper base fastening bolt 214 for fastening with the upper base 4 passes. Formed,
The upper wire coupling plate 212 has an odd number of semi-circular wire rope spring through holes 2121 through which the non-linear wire rope spring 1 passes, and the upper wire fixing plate for fastening with the upper wire fixing plate 211. An upper wire fixing plate fastening bolt hole 2122 to which the fastening bolt 213 is fastened, and an upper base fastening bolt hole 2123 through which the upper base fastening bolt 214 for fastening with the upper base 4 are formed are formed. ,
The lower wire fixing plate 221 has a plurality of semicircular wire rope spring through-holes 2211 having an odd number of non-linear wire rope springs 1 passing therethrough, and a lower wire fixing plate for fastening with the lower wire coupling plate 222. The lower wire coupling plate fastening bolt hole 2212 for inserting the fastening bolt 223 and the lower base fastening bolt hole 2213 through which the lower base fastening bolt 224 for fastening with the lower base 5 are formed. ,
The lower wire coupling plate 222 has an odd number of semicircular wire rope spring through holes 2221 through which the nonlinear wire rope spring 1 passes, and the lower wire for fastening with the lower wire fixing plate 221. The lower wire fixing plate fastening bolt hole 2222 to which the fixing bar fastening bolt 223 is fastened, and the lower base fastening bolt hole 2223 through which the lower base fastening bolt 224 for fastening with the lower base 5 are formed. Become,
The polyurethane spring 3 has an elliptic cylinder shape that is the same as that of the non-linear wire rope spring 1 formed therein, and a rectangular upper wire coupling plate insertion groove into which the upper wire coupling plate 212 is inserted. 31 is formed in the longitudinal direction, the lower wire coupling plate insertion groove 32 into which the lower wire coupling plate 222 is inserted is formed in the longitudinal direction,
Polyurethane for fastening with the upper base fastening bolt 214 to the upper wire coupling plate insertion groove 31 is the upper base 4, the upper wire holder 21 and the polyurethane spring 3 is coupled at the same time Combined spring device combining a strong earthquake absorption type non-linear wire rope and non-linear polyurethane spring, characterized in that the spring bolt fixing hole 311 is formed
6. The method of claim 5,
The lower wire coupling plate fastening bolt hole 2112 formed in the upper wire fixing plate 211 is formed with a bolt head insertion portion 21121 which prevents the bolt head of the upper wire fixing plate fastening bolt 213 from protruding.
The upper base fastening bolt hole 2123 formed in the upper wire coupling plate 212 is formed with a female screw for screwing the upper base fastening bolt 214,
The upper wire fixing plate fastening bolt hole 2122 formed on the upper wire coupling plate 212 is formed with a female screw for screwing the upper wire fixing plate fastening bolt 213.
The lower wire fixing plate fastening bolt hole 2212 formed in the lower wire fixing plate 221 is formed with a bolt head inserting portion 22121 which prevents the bolt head of the lower wire fixing plate fastening bolt 223 from protruding,
The lower wire fixing plate fastening bolt hole 2222 formed in the lower wire coupling plate 222 is formed with a female screw for screwing the lower wire fixing bolt fastening bolt 223,
The lower base fastening bolt hole 2223 formed in the lower wire coupling plate 222 is formed with a bolt head inserting portion 222231 which prevents the bolt head of the lower base fastening bolt 224 from protruding from the lower base fastening bolt hole 224.
The polyurethane spring bolt fixing hole 311 is a combination of a strong earthquake-absorbing non-linear wire rope and a non-linear polyurethane spring, characterized in that the screw is formed is a structure that can be screwed with the upper base fastening bolt 214. One composite spring device

Images