KR100891169B1 - Aseismatic bridge support device using magnet - Google Patents

Abstract

A seismic isolation bearing system using the magnetic is provided to prevent the elastic rubber layer from breaking away with expansion and contraction due to the shear deformation and elastic deformation. A seismic isolation bearing system using the magnetic comprises a plurality of support bars(11) which is supported by the top of the pier and a lower plate(10) equipped with a plurality of lower plate mounting grooves(12), an elastic rubber layer(20) equipped with an insertion hole and a plurality of mounting grooves(22), an upper plate(30) including an upper plate insertion groove(31), and a plurality of magnetic units(40) inserted into the upper plate insertion groove.

Description

Aseismatic Bridge Support Device Using Magnet}

The present invention relates to a seismic bridge device for connecting the upper plate and the bridge of the bridge to allow the vertical expansion and contraction and the left and right rotation according to the shear deformation and horizontal deformation of the bridge. Even if the complex force of horizontal deformation is applied, the magnetic force of the installed magnetic (magnet) pulls the upper and lower plates and the elastic rubber layer to solve the problem that the elastic rubber layer is separated, and when the elastic rubber layer is aging and needs replacement, A bottom plate and an elastic rubber layer are magnetically attached to a seismic bridge device having an improved structure that can be replaced easily and quickly.

In general, bridges connecting both sides across rivers, rivers, and seas have a structure in which a top plate rests on a plurality of bridges, and in the case of a suspension bridge installed without a bridge, pillars (piers) supporting a top plate at the center or both ends are provided. The structure is installed.

That is, the top plate is mounted on a plurality of bridges, so that people, vehicles, trains and heavy loads on the top plate can pass.

At this time, the larger the bridge, the longer the top plate, and the amount of stretching / shrinkage is increased due to the change of seasons or the crossover of heat at different crossovers, and the bridge system for absorbing the displacement of the stretching / contraction and the vibration or impact between the top plate and the piers. It is common to install between piers and decks.

Such a conventional chair device comprises a lower plate fixed to the pier and the upper plate fixed to the bottom of the upper plate and an elastic pad provided in close contact between the lower plate and the upper plate to absorb the stretching / contraction and vibration.

Since the elastic pads in such a device are vertically stretched, left and right rotated and flowd due to shear deformation and elastic deformation, elastic pads slide or break away, and are severely torn due to damage and deformation due to abrasion. It is a consumable product only after checking and replacing the elastic pad of the chair.

Such an elastic pad is preferably fixed to the upper and lower plates so as to absorb the shear deformation and elastic deformation, but as described above, if the elastic pad that needs periodic replacement is fixed to the upper and lower plates, It was a hassle to loosen a number of fastening bolts or to remove all of the chairs.

In addition, when the elastic pad is positioned between the upper and lower plates without a separate fixture in order to facilitate replacement, there is a problem that the elastic pad is slipped or separated by shear deformation and elastic deformation so that the upper plate cannot be safely supported.

Accordingly, the present inventors have come to develop an improved structure of the device, which is easy to replace, while accurately positioning the elastic pads between the upper and lower plates by seismic reinforcement.

Therefore, the present invention was invented in view of the above-described conventional problems, and a first object of the present invention is to precisely position the elastic rubber layer provided between the upper and lower plates of the stabilization device, and to relax the elastic expansion by shear deformation and elastic deformation. And to provide an earthquake resistance device of the improved structure that prevents the elastic rubber layer is out of position by rotation.

The second object of the present invention is to provide an earthquake resistant device having an improved structure that can be replaced easily only the inner elastic rubber layer without removing the upper and lower plates of the device when the position-fixed elastic rubber layer is aged and need to be replaced. There is.

The above objects and other objects, advantages and features of the present invention will become more apparent from the detailed description for carrying out the invention with reference to the accompanying drawings showing the preferred embodiments.

The device of the present invention according to the above object is provided with a plurality of support seats that are supported by being seated on the upper surface of the pier on the bottom surface, the lower plate having a plurality of lower plate mounting grooves on the upper surface, and the insertion groove abutting the lower plate mounting groove It is formed on the bottom surface, the elastic rubber layer is formed on the upper surface of the plurality of mounting grooves, the upper plate insertion groove which is in contact with the mounting groove of the upper surface of the elastic rubber layer is formed in the bottom plate and the lower plate is inserted in the lower mounting groove and the mounting groove It is achieved by the upper side is composed of a plurality of magnetic parts are protruded to a certain thickness to the upper surface and inserted into the insertion groove and the upper plate insertion groove.

In this case, a second magnetic part having a polarity opposite to the magnet polarity of the magnetic part is further provided in the insertion groove and the upper plate insertion groove, and the second magnetic part of the magnetic part is attracted to each other by magnetic force, so that the upper plate part and the elastic rubber layer and the lower plate are mutually provided. It may be implemented to be coupled.

In addition, in the practice of the present invention, the magnetic part has a body having a length vertically and vertically penetrates through-holes formed therein, and has a magnet inserted into the through-hole of the body and fixed to the center side, The upper and lower surfaces of the magnet may be coated to form a coating part surrounding the magnet.
The seismic bridge device using the magnetic of the present invention has a bottom plate 10 having a plurality of supports 11 seated on the upper surface of the pier on the bottom surface, an elastic rubber layer 20 formed on the bottom plate 10, The upper plate 30 formed on the elastic rubber layer 20 and a plurality of magnetic parts 40 provided with a magnet 42, the lower plate 10 by the magnetic force of the magnetic portion 40 In the chair device in which the elastic rubber layer 20 and the upper plate 30 is fixed to each other,
The upper surface of the lower plate 10 is provided with a plurality of lower plate mounting groove 12, the depth (H1 ') of the lower plate mounting groove 12 is the magnetic part 40 is interpolated and then the upper end is protruding Formed to the depth possible;
In the lower steel plate 20A forming the bottom surface of the elastic rubber layer 20, an insertion groove 21 in which an upper side of the magnetic part 40 is inserted is formed in an area in contact with the lower plate mounting groove 12. Depth (H2) of (21) is formed to be equal to the height of the projection (H2 ') of the magnetic portion 40 seated in the lower plate mounting groove 12;
The upper steel plate 20B forming the upper surface of the elastic rubber layer 20 is formed with a plurality of mounting grooves 22 in which the magnetic portion 40 is interposed therein, and the depth H1 of the mounting groove 22 is The magnetic part 40 is formed to a depth such that the upper end thereof can protrude after the interpolated seating;
An upper plate insertion groove 31 in which an upper side of the magnetic part 40 is inserted is formed in a region of the upper plate 30 which is in contact with the mounting groove 22 of the upper surface of the elastic rubber layer 20;
The magnetic part 40 has a lower side inserted into the lower plate mounting groove 12 and the mounting groove 22 and the upper side protrudes a predetermined thickness to the upper surface to be inserted into the insertion groove 21 and the upper plate insertion groove 31. The magnetic part 40 fixes the lower plate 10, the elastic rubber layer 20, and the upper plate 30 by magnetic force and serves as a stopper to prevent the elastic rubber layer 20 from slipping off. It relates to an earthquake proofing device using a magnetic.

By the use of the seismic stabilization device using the magnetic of the present invention obtained through the above object and the problem solving means for achieving the object, by precisely positioning the elastic rubber layer installed between the upper and lower plates of the chair device by shear deformation and elastic deformation Elastic rubber layer has the advantage of preventing the elastic rubber layer is out of position.

In addition, when the position-fixed elastic rubber layer needs to be replaced due to aging, there is an advantage that only the inner elastic rubber layer can be easily replaced without removing the upper and lower plates of the chair device.

Hereinafter will be described in more detail with reference to the accompanying drawings showing an embodiment of the present invention.

The present invention is provided with a plurality of supports 11 which is supported by being seated on the upper surface of the pier on the bottom as shown in Figure 1, the lower plate 10 having a plurality of lower plate mounting grooves 12 on the upper surface and the lower plate mounting Insertion grooves 21 abutting the grooves 12 are formed on the bottom, the elastic rubber layer 20 is formed with a plurality of mounting grooves 22 on the upper surface, and the mounting groove 22 of the upper surface of the elastic rubber layer 20 A lower side is inserted into the upper plate 30 and the lower plate mounting groove 12 and the mounting groove 22 having the upper plate insertion groove 31 abutting on the bottom surface, and the upper side protrudes a predetermined thickness to the upper surface of the insertion groove 21. And consists of a plurality of magnetic portion 40 is inserted into the upper plate insertion groove (31).

When explaining the configuration in more detail, as shown in Figure 2, the plurality of supports 11 provided on the bottom surface of the lower plate 10, is seated on the upper surface of the pier, is buried through concrete, etc. for fixing the curing, this Through the lower plate 10 is fixed integrally to the upper surface of the piers.

In addition, the upper surface of the lower plate 10 is formed with a lower plate mounting groove 12 through which a plurality of magnetic portions 40 can be interposed. The lower plate mounting groove 12 is an interpolated magnetic portion 40. The top of the is carried out to a depth that can project a certain width.

This is to be fixed by the magnetic force after the magnetic portion 40 protruding into the insertion groove 21 of the elastic rubber layer 20 is seated on the upper surface of the lower plate 10, it will be described in more detail, As shown in FIG. 3 and FIG. 4, the depth H 2 of the insertion groove formed in the lower steel plate 20A of the elastic rubber layer 20 is inserted into the lower plate mounting groove 12 of the lower plate 10 to protrude from the magnetic. It is formed equal to the height H2 '.

In addition, the depth H1 of the mounting groove formed in the upper steel plate 20B is formed to be equal to the insertion depth H1 'of the magnetic.

Therefore, as shown in FIG. 6, the lower plate mounting groove 12, the mounting groove 22, the insertion groove 21, and the upper plate insertion groove when the lower plate 10, the upper plate 30, and the elastic rubber layer 20 are coupled to each other. The magnetic part 40 interpolated in 31 is fixed up and down in close contact with each other.

The magnetic portion 40, the lower plate 10, the elastic rubber layer 20 and the upper plate 30 is firmly fixed by the magnetic force and at the same time the magnetic portion 40 acts as a stopper, the elastic rubber layer 20 is slippery It is prevented from falling out.

On the other hand, the elastic rubber layer 20 of the present invention is provided with a lower steel plate 20A and an upper steel plate 20B for forming the insertion groove 21 and the mounting groove 22 on the upper and lower sides, the lower steel sheet 20A ) And the rubber plate 20C and the iron plate 20D are alternately stacked between the upper steel plate 20B and each other. Here, the lower steel plate 20A and the upper steel plate 20B are made of metal to be attached by the magnet 42 of the magnetic part 40.

As such, the elastic rubber layer in which the iron plate 20B and the rubber plate 20C are alternately stacked with each other has an advantage in that the elastic restoring force is greatly improved by the deformation in the horizontal direction, which is widely used in general teaching device technology. The description will be omitted.

On the other hand, the magnetic portion 40 will be described in more detail, as shown in Figure 5 has a body 41 having a length vertically and penetrating the upper and lower through-hole 41A is formed, the body 41 The magnet 42 is inserted into the through hole 41A and is fixed to the center side, and the coating part 43 is coated on the upper and lower sides of the magnet 42 to surround the magnet 42. Can be.

In the magnetic part 40 configured as described above, even if the magnet 42 provided inside the body 41 has a shear force caused by the horizontal deformation of the lower plate 10, the elastic rubber layer 20, and the upper plate 30, The body 41 protects the magnet 42 and prevents it from being broken, and the magnet 42 inserted in the upper and lower sides is prevented from being separated.

At this time, the coating portion 43 is coated with a thick, but to prevent the magnetic force is weakened, it is preferable that the fixing force to the same thickness to prevent the detachment of the magnet 42 is preferably carried out in the same thickness, approximately 0.5 ~ 1mm thickness (T It is preferred to be coated with epoxy of).

When the coating layer is coated with a thickness of 0.5 mm or less, the inner magnet 42 may be detached due to a decrease in rigidity of the epoxy, and when coated with a thickness of 1 mm or more, the magnetic force may be weakened.

Meanwhile, as another embodiment of the present invention, as shown in FIG. 7, the second magnetic part 40 ′ is further provided in the insertion groove 21 and the upper plate insertion groove 31, but is mounted with the lower plate mounting groove 12. The magnetic pole portion 40 and the second magnetic portion 40 'are attracted to each other by magnetic force so that the lower portion 10 and the elastic rubber layer 20 and the upper plate 30 are mounted to the pole 22 and the other pole. ) May be coupled to each other.

This is a modified embodiment in which the different poles are attracted strongly, but the same poles are more firmly fixed to the elastic rubber layer 20 by using the characteristics of magnets pushing against each other.

The present invention is carried out in this way, as shown in Figure 8 seated on the pier 1, the seating portion is formed in the upper end is fixed by positioning the support 11 of the lower plate 10, the reinforcement to the seating portion of the pier 1 Reinforcement so that the support (11) is embedded in the concrete (2) to be firmly fixed.

Meanwhile, the upper plate 30 is fixed to the fixing plate 3A fixed to the bottom surface of the bridge upper plate 3 positioned above the lower plate 10. In this case, the fixing plate 3A and the upper plate 30 may be fixed through fastening means such as anchor bolts, but may be variously modified to be easily implemented by those skilled in the art.

After fixing the lower plate 10 and the upper plate 30 to the pier 1 and the upper plate 3 as described above, the magnetic portion 40 is interpolated into the lower plate mounting groove 12 of the lower plate 10, the outside After inserting the magnetic part 40 into the upper mounting groove 22 of the elastic rubber layer 20, the elastic rubber layer 20 is pushed between the lower plate 10 and the upper plate 30. At this time, the elastic rubber layer 20 is fixed by inserting the insertion groove 21 of the elastic rubber layer 20 due to the protruding magnetic portion 40 is fixed.

At this time, the upper plate (3) of the bridge is to work in a raised state using a device such as a hydraulic jack, the elastic rubber layer 20 is seated in a predetermined position, after removing the hydraulic jack, the lower plate 10 and the upper The plate 30 and the elastic rubber layer 20 are kept in close contact with each other.

The hydraulic jack is a well-known / common apparatus widely used for the maintenance of the bridge, and a detailed description thereof will be omitted.

As an embodiment of the present invention, the magnetic part 40 is shown to be implemented in a circular shape, but this may be modified to be rectangular or polygonal as shown in FIG. 9 for easy implementation by those skilled in the art.

In addition, although the quantity of the magnetic part 40 is shown in FIG. 1 and FIG. 9 by 6, it is not limited to this, For example, the quantity of the magnetic part 40 is 1, 2, 4, 6 Of course, it can be performed in dogs, eight, ten, twelve, twenty-four, and the like, which is within the scope of the present invention.

As described above, the present invention serves as a stopper and simultaneously firmly fixes the position between the lower plate 10, the elastic rubber layer 20, and the upper plate 30 by magnetic force, and at the same time, the magnetic part 40 is subjected to shear deformation. It is to include a structure that can protect it to prevent it from being easily damaged by the lower plate 10 and the elastic rubber layer 20 and the upper plate 30 by the interpolated magnet 42 even when a horizontal earthquake occurs. This technical feature is that the elastic rubber layer 20 is not pulled apart from each other.

Although the present invention has been described in connection with the above-mentioned preferred embodiments, it will be readily apparent to those skilled in the art that various other changes and modifications can be made without departing from the spirit and scope of the invention. It is obvious that all modifications belong to the appended claims.
The seismic bridge device using the magnetic of the present invention has a bottom plate 10 having a plurality of supports 11 seated on the upper surface of the pier on the bottom surface, an elastic rubber layer 20 formed on the bottom plate 10, The upper plate 30 formed on the elastic rubber layer 20 and a plurality of magnetic parts 40 provided with a magnet 42, the lower plate 10 by the magnetic force of the magnetic portion 40 In the chair device in which the elastic rubber layer 20 and the upper plate 30 is fixed to each other,
The upper surface of the lower plate 10 is provided with a plurality of lower plate mounting groove 12, the depth (H1 ') of the lower plate mounting groove 12 is the magnetic part 40 is interpolated and then the upper end is protruding Formed to the depth possible;
In the lower steel plate 20A forming the bottom surface of the elastic rubber layer 20, an insertion groove 21 in which an upper side of the magnetic part 40 is inserted is formed in an area in contact with the lower plate mounting groove 12. Depth (H2) of (21) is formed to be equal to the height of the projection (H2 ') of the magnetic portion 40 seated in the lower plate mounting groove 12;
The upper steel plate 20B forming the upper surface of the elastic rubber layer 20 is formed with a plurality of mounting grooves 22 in which the magnetic portion 40 is interposed therein, and the depth H1 of the mounting groove 22 is The magnetic part 40 is formed to a depth such that the upper end thereof can protrude after the interpolated seating;
An upper plate insertion groove 31 in which an upper side of the magnetic part 40 is inserted is formed in a region of the upper plate 30 which is in contact with the mounting groove 22 of the upper surface of the elastic rubber layer 20;
The magnetic part 40 has a lower side inserted into the lower plate mounting groove 12 and the mounting groove 22 and the upper side protrudes a predetermined thickness to the upper surface to be inserted into the insertion groove 21 and the upper plate insertion groove 31. The magnetic part 40 fixes the lower plate 10, the elastic rubber layer 20, and the upper plate 30 by magnetic force and serves as a stopper to prevent the elastic rubber layer 20 from slipping off. It relates to an earthquake proofing device using a magnetic.

1 is a perspective view showing an example of an earthquake proofing device using the magnetic of the present invention.

Figure 2 is an isolated perspective view showing an example of the seismic bridge device using the magnetic of the present invention.

Figure 3 is a side cross-sectional view showing an example of an elastic rubber layer of the earthquake resistance device using the magnetic of the present invention.

Figure 4 is a side cross-sectional view showing an example of the lower plate of the earthquake resistance device using a magnetic of the present invention.

Figure 5 is a side cross-sectional view showing an example of the magnetic portion of the earthquake proofing device using the magnetic of the present invention.

Figure 6 is a side cross-sectional view showing an example of coupling of the seismic bridge device using the magnetic of the present invention.

Figure 7 is a side cross-sectional view showing another embodiment of an earthquake resistant device using a magnetic of the present invention.

8 is a use state diagram showing an example of the use of the seismic bridge device using the magnetic of the present invention.

Figure 9 is an isolated perspective view showing another embodiment of the magnetic portion of the seismic bridge device using the magnetic of the present invention.

[Explanation of symbols on the main parts of the drawings]

10: lower plate 11: support

12: lower plate mounting groove 20: elastic rubber layer

20A: lower steel plate 20B: upper steel plate

20C: rubber sheet 20D: iron plate

21: insertion groove 22: mounting groove

30: top plate 31: top plate insertion groove

40: magnetic part 40 ': second magnetic part

41: Body 41A: Through Hole

42: magnet 43: coating

H1: Depth of mounting groove H1 ': Insertion depth of magnetic

H2: depth of insertion groove H2 ': height of magnetic protrusion

T: thickness

Claims (6)

A lower plate 10 having a plurality of supports 11 seated on and supported by an upper surface of the piers, an elastic rubber layer 20 formed on the lower plate 10, and an upper portion of the elastic rubber layer 20. Is composed of a plurality of magnetic portion 40 is provided with a top plate 30, a magnet 42, the lower plate 10 and the elastic rubber layer 20 and the top plate by the magnetic force of the magnetic portion 40 In a teaching device in which 30 is fixed to each other, The upper surface of the lower plate 10 is provided with a plurality of lower plate mounting groove 12, the depth (H1 ') of the lower plate mounting groove 12 is the magnetic part 40 is interpolated and then the upper end is protruding Formed to the depth possible; In the lower steel plate 20A forming the bottom surface of the elastic rubber layer 20, an insertion groove 21 in which an upper side of the magnetic part 40 is inserted is formed in an area in contact with the lower plate mounting groove 12. Depth (H2) of (21) is formed to be equal to the height of the projection (H2 ') of the magnetic portion 40 seated in the lower plate mounting groove 12; The upper steel plate 20B forming the upper surface of the elastic rubber layer 20 is formed with a plurality of mounting grooves 22 in which the magnetic portion 40 is interposed therein, and the depth H1 of the mounting groove 22 is The magnetic part 40 is formed to a depth such that the upper end thereof can protrude after the interpolated seating; An upper plate insertion groove 31 in which an upper side of the magnetic part 40 is inserted is formed in a region of the upper plate 30 which is in contact with the mounting groove 22 of the upper surface of the elastic rubber layer 20; The magnetic part 40 has a lower side inserted into the lower plate mounting groove 12 and the mounting groove 22 and the upper side protrudes a predetermined thickness to the upper surface to be inserted into the insertion groove 21 and the upper plate insertion groove 31. The magnetic part 40 fixes the lower plate 10, the elastic rubber layer 20, and the upper plate 30 by magnetic force and serves as a stopper to prevent the elastic rubber layer 20 from slipping off. A seismic bridge device using a magnetic, characterized in that. A lower plate 10 having a plurality of supports 11 seated on and supported by an upper surface of the piers, an elastic rubber layer 20 formed on the lower plate 10, and an upper portion of the elastic rubber layer 20. Is composed of a plurality of magnetic portion 40 is provided with a top plate 30, a magnet 42, the lower plate 10 and the elastic rubber layer 20 and the top plate by the magnetic force of the magnetic portion 40 In a teaching device in which 30 is fixed to each other, The upper surface of the lower plate 10 is provided with a plurality of lower plate mounting groove 12, the depth (H1 ') of the lower plate mounting groove 12 is the magnetic part 40 is interpolated and then the upper end is protruding Formed to the depth possible; The lower steel plate 20A forming the bottom of the elastic rubber layer 20 is formed with an insertion groove 21 in which an upper side of the magnetic part 40 is inserted in an area in contact with the lower plate mounting groove 12; The upper steel plate 20B forming the upper surface of the elastic rubber layer 20 is formed with a plurality of mounting grooves 22 in which the magnetic portion 40 is interposed therein, and the depth H1 of the mounting groove 22 is The magnetic part 40 is formed to a depth such that the upper end thereof can protrude after the interpolated seating; An upper plate insertion groove 31 in which an upper side of the magnetic part 40 is inserted is formed in a region of the upper plate 30 which is in contact with the mounting groove 22 of the upper surface of the elastic rubber layer 20; The insertion groove 21 and the upper plate insertion groove 31 are further provided with a second magnetic portion 40 'having a polarity opposite to that of the magnet 42 of the magnetic portion 40, and the magnetic portion 40 ) And the second magnetic portion 40 'are attracted to each other by magnetic force; The magnetic part 40 has a lower side inserted into the lower plate mounting groove 12 and the mounting groove 22 and the upper side protrudes a predetermined thickness to the upper surface to be inserted into the insertion groove 21 and the upper plate insertion groove 31. The magnetic part 40 fixes the lower plate 10, the elastic rubber layer 20, and the upper plate 30 by magnetic force and serves as a stopper to prevent the elastic rubber layer 20 from slipping off. A seismic bridge device using a magnetic, characterized in that. The method according to claim 1 or 2, The magnetic part 40 may include: a body 41 having a length vertically and having a through hole 41A vertically penetrating therein; A magnet 42 inserted into the through hole 41A of the body 41 and fixed to the center side thereof; It is composed of a coating part 43 coated on the upper and lower surfaces of the magnet 42 to surround the magnet 42, and the magnet 42 of the magnetic part 40 is moved to the outside due to the coating part 43. A seismic bridge device using a magnetic, characterized in that the exposure to prevent damage. The method of claim 3, The coating portion 43 is 0.5 ~ 1mm thick epoxy, The magnetic part 40, the earthquake resistance device using a magnetic, characterized in that the outer shape is carried out in any one shape selected from a circle or a square. delete delete

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