KR101078399B1 - Shear friction damper with variable resistance - Google Patents

Abstract

The present invention relates to a load-bearing variable friction damper, and more particularly, to a load-bearing variable friction damper formed to effectively respond to external forces of various sizes.
The load-bearing variable friction damper according to the present invention includes a first support supported on a building structure or a damping rod, a second support slidably connected to an upper portion of the first support, and a first pad mounted on the front and rear surfaces of the first support. An additional plate part comprising a plate, a second additional plate connected to the first additional plate and mounted to the front and rear surfaces of the second support, a first friction plate provided between the first support and the first additional plate, and the second A second friction plate provided between the support and the second backing plate, a first fastening part for fastening the first backing plate and the first friction plate to the first support to have a predetermined frictional strength, and a second padding on the second support And a fastening unit including a second fastening part for fastening the plate and the second friction plate to have a frictional force different from that of the first fastening part.

Description

Variable friction damper {Shear friction damper with variable resistance}

The present invention relates to a load-bearing variable friction damper, and more particularly, to a load-bearing variable friction damper formed to effectively respond to external forces of various sizes.

The building structure is subject to torsion or similar horizontal movement when the member is subjected to external forces in the horizontal direction. Torsion, especially in building structures or towers, can cause serious impacts or even collapse of the structure.

Dampers play an important role in protecting building structures, such as houses or similar building structures, which are present in numerous variants.

Dampers generally dampen movement by frictional forces between two moving parts attached between structural members of a building or by fluids flowing and pressurizing between two chambers through a restricted tube.

Some dampers actively change the damping effect corresponding to external conditions, and other dampers include passive dampers with constant damping characteristics.

However, the dampers of the longitudinal ram, particularly the friction dampers, are designed to absorb vibration energy while driving with a constant frictional force, and thus have a disadvantage in that they cannot effectively cope with external loads of various sizes.

That is, the friction damper having a large frictional strength does not function as a damper because the damper itself does not operate against small external loads such as small earthquakes or wind vibrations.

On the contrary, in the case of a friction damper having a small frictional strength, when a large external load is applied, such as when a large earthquake occurs, it is difficult to expect a damping effect of vibration energy beyond the driving range of the friction damper.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a load-bearing variable friction damper having a plurality of frictional action sections having different frictional forces so as to effectively cope with external loads of various sizes.

According to the present invention for achieving the above object, the variable friction friction damper includes a first support supported on a building structure or a damping rod, a second support slidably connected to an upper portion of the first support, and the first support. A first pad plate mounted on the front and rear surfaces, a second pad plate connected to the first pad plate and mounted on the front and rear surfaces of the second support, and the first and second pad plates independently of the front and rear directions. An adder plate part including a connecting part which is movably connected to each other so as to be integrally movable with respect to the moving direction in which the second support member is slid; a first friction plate installed between the first support member and the first adder plate; A second friction plate provided between the second support body and the second backing plate, a first fastening part for fastening the first backing plate and the first friction plate to the first support body to have a predetermined frictional strength; 2 And a fastening unit including a second fastening part for fastening the second backing plate and the second friction plate to a support having a frictional force different from that of the first fastening part.

The first support may include a first end plate supported by the building structure or the damping rod, and a first sliding hole extending from the center of the first end plate in a direction orthogonal to the first end plate and penetrating the front and rear surfaces. A second end plate supported by a building structure or a damping rod, and a second end plate supported from the center of the second end plate toward the end of the first sliding plate. It is preferable to include the 2nd sliding plate which orthogonally extends and the 2nd sliding hole which penetrates the front and back surface is formed.

The first, second bolting plate, and the first and second friction plates are formed with first and second bolting holes, and first and second through holes, respectively, at positions corresponding to each other so as to be mutually coupled by the fastening unit. The first and second fastening portions may include tension bolts extending through the first bolting hole and the first through hole and the first sliding hole or the second bolting hole and the second through hole and the second sliding hole, respectively. And a nut fastened to an end of the tension bolt and a washer member mounted to the tension bolt to prevent the frictional force caused by the first and second fastening parts from being lowered when the first and second friction plates are worn. It includes.

The connecting portion includes a first coupling portion formed on the first pad and includes a coupling protrusion protruding along a front and rear direction extending through the front and rear surfaces of the first and second supports, and the second pad. It is preferable to have a second coupling portion which is formed in the through hole in the front and rear directions so that the coupling projection can be fitted, the coupling hole corresponding to the shape of the coupling projection is provided.

The load-bearing variable friction damper according to another embodiment of the present invention is the end plate fixed to the building structure, the main sliding plate extending to the lower portion of the end plate, the main sliding plate and the left and right under the main sliding plate A sliding panel unit including auxiliary sliding plates connected to each other so as to slide in a direction, a locking part connecting the main sliding plate and the auxiliary sliding plate to have a predetermined clearance in left and right directions, and on front and rear surfaces of the sliding panel unit. A plurality of installed overhanging plates, first and second auxiliary end plates installed at both left and right ends of the overhanging plate and supported by a damping rod, and between the overhanging plate, the main sliding plate, and the auxiliary sliding plate. Two friction plates, and the sliding panel unit and the friction plate and the back plate are fastened to each other. The riding plate and the auxiliary sliding plate is provided with a fastening unit for fastening so that the frictional strength is different when fastening with the friction plate.

The sliding panel unit includes a first auxiliary sliding plate connected to a lower side of the main sliding plate in a left and right direction, and a second auxiliary sliding plate connected to a lower side of the first auxiliary sliding plate in a left and right direction. The main sliding plate and the first and second auxiliary sliding plates are formed with first to third long holes penetrating the front and rear surfaces, respectively, wherein the first long hole is the longest and the third long hole is the relatively long. Is formed to be short, and the engaging portion is provided with a locking projection is inserted into the engaging groove formed in the lower end of the main sliding plate and the first auxiliary sliding plate protruding a predetermined length upward from the upper end of the first and second auxiliary sliding plate. It is desirable to.

The load-bearing variable friction damper according to the present invention has an advantage that it can effectively cope with external loads of various sizes.

1 is a front view showing an embodiment of the installation state of the load-bearing variable friction damper according to the present invention,
2 to 5 is a front view showing other embodiments of the installation state of the load-bearing variable friction damper,
Figure 6 is a perspective view showing a first embodiment of a load bearing variable friction damper,
7 is an exploded perspective view of FIG. 6, FIG.
8 is a front view showing a driving state of the load bearing variable friction damper;
9A and 9B are fragmentary perspective views showing a moving state of the first support when driving the load-bearing variable friction damper of the first embodiment;
10 is a front view showing the installation state of the second embodiment of the load-bearing variable friction damper;
11 is a perspective view of the load-bearing variable friction damper of FIG.
12 is an exploded perspective view of the load-bearing variable friction damper of FIG. 10;
13A to 13C are partial views illustrating a driving process of the load-bearing variable friction damper of FIG. 10.

Hereinafter, with reference to the accompanying drawings will be described in more detail the load-bearing variable friction damper (hereinafter referred to as "friction damper") as follows.

1 shows an embodiment in which the friction damper 100 is installed in the building structure 10.

As shown, the building structure 10 is provided with a steel frame, the friction damper 100 of the present invention is mounted on the lower center of the steel frame 20. The friction damper 100 is supported by the damping rods 30 respectively supported at the upper ends of the frame.

When vibration is applied to the building structure 10 by an external force such as an earthquake or a strong wind, the friction damper 100 coupled to the bottom and the top of the frame and the damping rod 30 attenuates the vibration while sliding in the horizontal direction, The vibration energy applied to the building structure 10 is diverged by the frictional heat from the friction plate 140, thereby minimizing damage to the building structure 10.

Figure 2 shows another embodiment of the installation of the friction damper 100, as shown, the upper and lower portions of the friction damper 100 by the four damping rods 30 respectively supported at the four corners of the frame Each may be formed in a supported form.

3 and 4, the friction damper 100 and the damping rod 30 may be directly supported on the building structure 10 without the steel frame 20, as illustrated in FIG. 5. As described above, the auxiliary pillar 50 in the vertical direction may be installed in the building structure 10, and the friction damper 100 may be installed in the middle of the auxiliary pillar 50.

Thus, the friction damper 100 of the present invention can be installed in various forms, and the basic principle is to minimize the external force applied to the building structure 10 by converting vibration energy into frictional heat with respect to vibrations applied in the horizontal direction. .

6 to 9 show a first embodiment of a friction damper 100 according to the invention.

Referring to Figures 6 to 9 on the basis of the installation state shown in Figure 1, the friction damper 100 of this embodiment is a rod fastening member to which the building structure 10 and the damping rod 30 are fastened, respectively ( The first and second supports 110 and 120 supported by 40, the back plate portion 140 coupled to front and rear surfaces of the first and second supports 110 and 120, and the back plate portion 140 and the first and second supports The first and second friction plates 131 and 133 inserted between the first and second support plates 110 and 120, and the first and second support plates 110 and 120, and the first and second friction plates 131 and 133, and the cover plate 140 have a predetermined frictional strength. It includes a fastening unit 150 to fasten to have.

The first support 110 includes a first end plate 111 fixed to the building structure 10 and a first sliding plate 113 extending upward from the upper surface of the first end plate 111, A plurality of fastening holes 112 are formed in the first end plate 111 to penetrate the upper and lower surfaces so as to be fixed to the building structure 10 through the fastening bolts.

The second supporter 120 is installed on the upper part of the first supporter 110, and extends downward from the center of the bottom surface of the second end plate 121 and the second end plate 121 connected to the rod fastening member 40. The second sliding plate 123 is included. Fastening holes 122 penetrating the upper and lower surfaces are also formed in the second end plate 121 so that the fastening bolts penetrate the fastening hole 122 so that the second end plate 121 is connected to the rod fastening member 40. To combine.

The first and second sliding holes 114 and 124 are formed in the first and second sliding plates 113 and 123 to penetrate the front and rear surfaces, respectively. The first and second sliding holes 114 and 124 are tension bolts 153 which will be described later. Since the width is to penetrate through, the width is formed to correspond to the outer diameter of the tension bolt 153, it is a long hole extending a predetermined length in the left and right directions. In particular, the first sliding hole 114 has a relatively longer length than the second sliding hole 124.

The additional plate 140 is mounted on the front and rear surfaces of the first and second sliding plates 113 and 123 and connects the first and second additional plates 141 and 143 to the first and second additional plates 141 and 143. Has 145.

As described above, the first pad plate 141 is installed on the front and rear surfaces of the first sliding plate 113, respectively, and includes a first ball having a diameter corresponding to the outer diameter of the tension bolt so that the tension bolt 153 can pass therethrough. The putting hole 142 is formed to penetrate in the front and rear direction.

The second pad plate 143 is installed at the front and rear surfaces of the second sliding plate 123, respectively, and has a second bolting hole 144 through which the tension bolt 153 penetrates in the front and rear directions. .

 The connection part 145 is for connecting the first and second pads 141 and 143 to each other, and includes a first coupling part 146 provided on an upper part of the first pad plate 141 and a first coupling part 146. And a second coupling part 148 provided on the second mounting plate 143 so as to be connected to the second mounting plate 143.

When the surface facing the first and second sliding plates 113 and 123 in the first and second backing plates 141 and 143 is inner, and the opposite side is referred to as the outer circumferential surface, the first coupling part 146 has a predetermined depth inward from the outer circumferential surface. A first inlet groove 146a is formed therein, and a coupling protrusion 147 protruding outward is formed in the first inlet groove 146a.

The second coupling part 148 is provided at a lower portion of the second sliding plate 123, and a second drawing groove 148a drawn outward from an inner circumferential surface is formed, and the second drawing groove 148a is formed in the second drawing groove 148a. A coupling hole 149 corresponding to the coupling protrusion 147 is formed to penetrate the inner circumferential surface and the outer circumferential surface.

Accordingly, the first and second coupling parts 146 and 148 are positioned so that the outer circumferential surface of the first coupling part 146 and the inner circumferential surface of the second coupling part 148 face each other, and the coupling protrusion 147 is coupled to the coupling hole ( 149, the first and second backing plates 141 and 143 may be connected to each other through the first and second coupling parts 146 and 148.

Since the coupling protrusion 147 is fitted into the coupling hole 149, the first and second backing plates 141 and 143 are integrally driven in the left and right directions, and the front and rear sides of the coupling protrusion 147 are directed to the first and second sliding plates 113 and 123. Direction can be driven independently.

The first and second friction plates 131 and 133 are installed between the first back plate 141 and the first sliding plate 113 and between the second back plate 143 and the second sliding plate 123, respectively. First and second through holes 132 and 134 are formed in the first and second friction plates 131 and 133 to fasten the tension bolt 153, respectively.

The first and second friction plates 131 and 133 have a hardness that is relatively higher than that of the first and second sliding plates 113 and 123 so that when the slip occurs with the first and second sliding plates 113 and 123, the frictional heat may be worn. It is preferable to be formed of a low material, and although not shown, irregularities may be formed on the contact surfaces of the first and second friction plates 131 and 133 and the first and second sliding plates 113 and 123 to increase the friction area.

The fastening unit 150 may include a first fastening part 151 for fastening the first sliding plate 113, a first friction plate 131, and a first backing plate 141, and a second sliding plate 123 and a second sliding plate 123. And a second fastening part 152 for fastening the second friction plate 133 and the second backing plate 143.

Each of the first and second fastening parts 151 and 152 includes a tension bolt 153, a nut 154, and a washer member 155, and the first friction plate 131 and the front and rear surfaces of the first sliding plate 113 are formed. When the first mounting plate 141 is installed, the tension bolt 153 of the first fastening portion 151 sequentially the first bolting hole 142, the first through hole 132, and the first sliding hole 114. Is installed to penetrate through, the washer member 155 is fitted to the end of the tension bolt 153 protruding to the outside of the first mounting plate 141 is fastened by screwing the nut 154.

The second sliding plate 123, the second backing plate 143, and the second friction plate 133 are also fastened in the same manner.

The washer member 155 is a tension bolt when the first and second sliding plates 113 and 123 and the first and second friction plates 131 and 133 wear out while friction heat is generated by slipping. It is preferable to apply a dish spring washer to prevent the frictional force from being lowered while the tightening tension of 153 is reduced.

When the first fastening part 151 and the second fastening part 152 are fastened, the tension bolt 153 is tightened using a torque wrench. The friction between the first friction plate 131 and the first sliding plate 113 is reduced. The tension bolt 153 and the nut 154 are tightened such that the internal force is relatively greater than the frictional force between the second friction plate 133 and the second sliding plate 123.

Referring to the driving process of the friction damper 100 of the present embodiment formed as described above formed as described above are as follows.

First, when the magnitude of the vibration is small, such as a small earthquake or an external force caused by wind, as shown in FIGS. 8 and 9A, the tension bolt 153 and the nut 154 of the second fastening part 152 are relatively relatively. Since the second support 120 is driven while the slip is generated in the left and right directions because it is tightened with a small fastening tension, the energy of the frictional heat is increased while the second sliding plate 123 and the second friction plate 133 are mutually rubbed. Exhausted in form.

When a large earthquake occurs, the magnitude of the external force applied from the outside exceeds the frictional force between the second friction plate 133 and the second sliding plate 123.

Therefore, in this case, the second sliding plate 123 is primarily moved until the end of the second sliding hole 124 is in contact with the tension bolt 153. Since the magnitude of the external force is greater than the frictional force between the first sliding plate 113 and the first friction plate 131, slip occurs between the first sliding plate 113 and the first friction plate 131. Since the 110 is fixed, slip occurs in the left and right directions of the first friction plate 131 with respect to the first sliding plate 113.

The first friction plate 131 behaves integrally with the first backing plate 141 by the first fastening part 151, and the first backing plate 141 is second with respect to the left and right direction by the connecting part 145. Since it behaves integrally with the adder plate 143, the resultant behavior is as shown in Figs. 8 and 9b.

Since the first and second fastening parts 151 and 152 are fastened with different fastening forces, the second friction plate 133 may be moved by only the second support 120 according to the magnitude of the external force applied to the building structure 10. Since the friction may occur only between the and the second sliding plate 123, or the first and second friction plates 131 and 133 may generate a slip so as to generate friction, thereby effectively reducing vibration by effectively acting on external forces of various sizes. Can be harvested.

Although not shown, a Teflon sheet having a low coefficient of friction is attached between the first and second sliding plates 113 and 123 and between the first and second backing plates 141 and 143 and the first and second end plates 111 and 121. This prevents abrasion from occurring in the contact area.

10 to 13 show a second embodiment of the friction damper 200 according to the present invention.

As shown in FIG. 10, the friction damper 200 according to the present embodiment has a top end fixed to the building structure 10, and is installed such that the damping rods 30 are connected to both left and right sides, and the top side is turned downward. It is also possible to install.

And when the steel frame 20 is provided for the damper installation may be installed so that the upper end is coupled to the steel frame (20).

11 and 12, the friction damper 200 according to the present embodiment includes an end plate 210 fixed to the building structure 10, and a sliding panel unit 220 installed below the end plate 210. And, the back plate 260 mounted on the front and rear surfaces of the sliding panel unit 220, the friction plate 280 is provided between the back plate 260 and the sliding panel unit 220, and the back plate 260 The auxiliary end plates 210 installed at both left and right ends thereof include a fastening unit 290 fastening the sliding panel unit 220 to the friction plate 280 and the backing plate 260.

The end plate 210 is formed to penetrate the upper and lower surfaces of the plurality of fastening holes 211 for installing the fastening bolts to be fixed to the building structure 10 as described above.

The sliding panel unit 220 is provided below the end plate 210, and includes a main sliding plate 230 and first and second sliding plates.

The main sliding plate 230 is formed to extend a predetermined length downward from the center of the lower surface of the end plate 210 and extends in the longitudinal direction, that is, the left and right direction of the end plate 210. And it is welded so that it may drive integrally with the end plate 210.

In addition, two main sliding plates 230 are formed so that the first long holes 231 penetrating the front and rear surfaces are spaced apart in the longitudinal direction, and the first long holes 231 are tension bolts of the fastening unit 290 which will be described later. It has a width corresponding to the outer diameter of 294 and extends in the horizontal direction. And at the bottom is formed two first locking grooves 232 which are drawn upwards.

The first auxiliary sliding plate 240 is slidably installed in the left and right directions under the main sliding plate 230. Like the main sliding plate 230, two second long holes 241 penetrating the front and rear surfaces are left and right. It is formed to be spaced apart from each other, and two second locking grooves 242 are formed at the bottom. In addition, two first locking protrusions 243 protruding upward to be inserted into the first locking grooves 232 are formed at an upper end thereof, and the first locking grooves may be larger than the left and right widths of the first locking protrusions 243. Since the length of the left and right directions 232 is long, the first locking protrusion 243 has a play that can flow in the first locking groove 232.

The second auxiliary sliding plate 250 is installed to be slidable in the left and right directions under the first auxiliary sliding plate 240, and two third long holes 251 penetrating the front and rear surfaces are spaced apart from each other in the left and right directions. It is. The second locking protrusion 252 is inserted into the second locking groove 242 at the upper end.

The left and right widths of the second locking protrusions 252 are the same as the first locking protrusions 243, and the left and right lengths of the second locking grooves 242 are also the same as the first locking grooves 232. 252 also has a play that can flow in the left and right direction in the second locking groove 242.

The first to third long holes 231, 241 and 251 are formed with the longest first hole 231 and the shortest third third hole 251.

The adder plate 260 includes first to third adder plates 261, 262 and 263 coupled to front and rear surfaces of the main sliding plate 230 and the first and second auxiliary sliding plates 240 and 250, respectively.

The first to third bolting plates 261, 262, and 263 are provided with first to third bolting holes 264, 265, and 266 to penetrate front and rear surfaces at points corresponding to the first to third long holes 231, 241, and 251, respectively. The three bolting holes 264, 265, and 266 have a diameter corresponding to the outer diameter of the tension bolt 294 described later. In addition, the left and right lengths of the adder plate 260 are relatively longer than the sliding panel unit 220, and two fastening protrusions 267 are formed at both ends of the left and right sides.

The first and second auxiliary end plates 271 and 272 are respectively installed at left and right ends of the pads 260, respectively, and a plurality of auxiliary fastening holes for installing fastening bolts to be supported by the damping rods 30, respectively. 273) are formed.

The first and second insertion holes 274 and 275 are formed to insert the fastening protrusions 267 provided in the first to third backing plates 261, 262 and 263. The first insertion holes 274 are sliding panels. It is formed to be spaced apart in the vertical direction so that the fastening protrusions 267 of the first to third pads 261, 262, 263 installed in front of the unit 220 can be inserted, the second insertion holes 275 are sliding panel units The fastening protrusions 267 of the first to third backing plates 261, 262, and 263 installed at the rear of the 220 may be inserted therein. In particular, the second insertion hole 275 has a long hole shape extending a predetermined length in the front and rear direction, which is the main sliding plate 230 and the first and second auxiliary sliding plates 240 and 250 by the fastening unit 290 to be described later Since the fastening force to be fastened is different, the first to third backing plates 261, 262 and 263 may be independently operated in the front and rear directions.

The first to third backing plates 261, 262 and 263 are fastened to and supported by the first and second auxiliary end plates 271 and 272 as described above, and thus, are not separated from each other and independently move forward and backward.

The first to third friction plates 281, 282, and 283 are respectively between the main sliding plate 230 and the first backing plate 261, between the first auxiliary sliding plate 240 and the second backing plate 262, and the second auxiliary sliding plate. Fourth to sixth bolting holes 284, 285 and 286 are installed between the 250 and the third adding plate 263 and corresponding to the first to third bolting holes 264, 265, and 266 for mounting the tension bolt 294. have. The fourth to sixth bolting holes 284, 285, and 286 are also formed to have diameters corresponding to the outer diameters of the tension bolts 294.

The fastening unit 290 is for coupling the backing plate 260 and the sliding panel unit 220 and the friction plate 280 to each other.

The fastening unit 290 includes a first fastening portion 291 for fastening the main sliding plate 230, the first backing plate 261 and the first friction plate 281, and the first auxiliary sliding plate 240 and the first sliding plate 240. 2 Fastening the second fastening part 292, the second auxiliary sliding plate 250, the third backing plate 263 and the third friction plate 283 to fasten the backing plate 262 and the second friction plate 282. A third fastening portion 293 is provided to include a tension bolt 294, a nut 295, and a washer member 296, respectively.

The tension bolt 294 sequentially passes through the first to third bolting holes 264, 265, and 266, the fourth to sixth bolting holes 284, 285, 286, and the first to third long holes 231, 241, and 251, respectively, and then protrudes at the protruding end. The nut 295 is screwed and tightened, and the washer member 296 is fitted into the head of the tension bolt 294 and the nut 295, respectively.

The tension bolts 294 are fastened with fastening tensions respectively set using torque wrenches to have different frictional strengths at fastening portions fastened by the first to third fastening portions 291, 292 and 293.

The friction damper 200 according to the present embodiment includes the main sliding plate 230 and the first and second auxiliary sliding plates 240 and 250 to have different frictional strengths at the first to third fastening portions 291, 292 and 293. Since the friction plates 281, 282, 283 and the first to third backing plates 261, 262, 263 are fastened, they have a behavior section with respect to the external force of three parts.

The first to third fastening portions 291, 292 and 293 are fastened by the first fastening portion 291, and the third fastening portion 293 preferably has the largest magnitude.

The driving process of the friction damper 200 according to the present embodiment will be described with reference to FIGS. 13A to 13C as follows.

First, the frictional force formed between the main sliding plate 230 and the first friction plate 281 by the first to third fastening parts 291, 292, and 293 may be used as a first frictional force and a first auxiliary sliding plate ( When the frictional force formed between the 240 and the second friction plate 282 is the second frictional force, and the frictional force formed between the second auxiliary sliding plate 250 and the third frictional plate 283 is the third frictional resistance, When no external force is applied from the outside or the magnitude of the external force is smaller than the first frictional force, the main sliding plate 230 and the first and second auxiliary sliding plates 240 and 250 are friction plates 280 as shown in FIG. 13A. Slip does not occur with respect to the field, and is kept in the initial state.

When an external force of a magnitude larger than the first frictional force and smaller than the second frictional force is applied by a small earthquake or wind, the main sliding plate slips in the left and right directions as shown in FIG. 13B, and at this time, the main sliding As friction heat is generated between the plate 230 and the first friction plate 281, the external force is exhausted by the friction heat.

The traveling distance of the main sliding plate 230 to the left and right is limited to a point at which the first locking groove 232 is caught by the first locking protrusion 243, and since the external force is smaller than the second frictional force, the first auxiliary distance is increased. The sliding plate 240 does not behave but only the main sliding plate 230 is made.

When an external force greater than the second frictional force and smaller than the third frictional force is applied, slip occurs between the first auxiliary sliding plate 240 and the second friction plate 282 because the external force is greater than the second frictional force.

Accordingly, the first locking protrusion 243 of the first auxiliary sliding plate 240 is towed in the state of being caught in the first locking groove 232, and moves in the left and right direction together with the main sliding plate 230, and proceeds in the left and right direction. The width can be increased and the amount of frictional heat generated is increased.

The first auxiliary sliding plate 240 may move until the first locking protrusion 243 is caught by the second locking groove 242.

When an external force greater than the third frictional force is applied, the second auxiliary sliding plate 250 is pulled by the second locking protrusion 252 caught by the second locking groove 242, as shown in FIG. 13C, and the third friction plate ( 283) slip occurs.

As such, the end plate 210 can effectively adjust vibration for various external force sizes because the left and right movement distances can be adjusted by the movement amounts of the main sliding plate 230 and the first and second auxiliary sliding plates 240 and 250. It can work.

The washer member 296 is reduced in thickness as the first to third friction plates 281, 282, and 283 are worn to prevent the tightening tension caused by the tension bolt 294 from being lowered, thereby preventing the function of the friction damper 200 from being deteriorated. As in the first embodiment, it is preferable that a dish spring washer is applied.

As described above, since the friction damper 200 of the present embodiment can be driven in three stages according to the magnitude of the external force applied, the friction damper 200 can be effectively driven against an external force of a small size or a large external force.

Although not shown, the number of auxiliary sliding plates may be increased to further refine the driving stage for the magnitude of the external vibration.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

First embodiment
100: friction damper
110: first support
120: second support
140: back plate part
150: fastening unit
Second embodiment
200: friction damper
210: end plate
220: sliding panel unit
230: main sliding plate
240: first auxiliary sliding plate
250: second auxiliary sliding plate
260: plate
280: friction plate
290: fastening unit

Claims (6)

A first support supported by the building structure or the damping rod;
A second support slidably connected to an upper portion of the first support;
A front and rear surfaces of the first support plate mounted on the front and rear surfaces of the first support body, a second back plate connected to the first support plate and mounted on the front and rear surfaces of the second support body, and the first and second back plate. A stand-up plate part including a connecting part which is independently movable in a direction and interconnects so as to integrally move with respect to the moving direction in which the second support is slid;
A first friction plate installed between the first support and the first backing plate;
A second friction plate installed between the second support and the second backing plate;
A first fastening part configured to fasten the first backing plate and the first friction plate to the first support member to have a predetermined frictional resistance, and the second fastening plate and the second friction plate to the second support body; And a fastening unit including a second fastening part configured to fasten to have a different frictional strength. The method of claim 1,
The first support may include a first end plate supported by the building structure or the damping rod, and a first sliding hole extending from the center of the first end plate in a direction orthogonal to the first end plate and penetrating the front and rear surfaces. A first sliding plate,
The second support extends orthogonal to the second end plate from the center of the second end plate toward the end of the first sliding plate, the second end plate supported by the building structure or the damping rod, and penetrates the front and rear surfaces. The variable resistance friction friction damper comprising a second sliding plate is formed with a second sliding hole. The method of claim 2,
The first, second bolting plate, and the first and second friction plates are formed with first and second bolting holes, and first and second through holes, respectively, at positions corresponding to each other so as to be mutually coupled by the fastening unit. And
The first and second fastening portions may include tension bolts extending through the first bolting hole and the first through hole and the first sliding hole or the second bolting hole and the second through hole and the second sliding hole, respectively; A nut fastened to an end of the tension bolt, and a washer member mounted to the tension bolt to prevent a decrease in frictional resistance caused by the first and second fastening parts when the first and second friction plates are worn. A load bearing variable friction damper, characterized in that. The method of claim 1,
The connecting portion includes a first coupling portion formed on the first pad and includes a coupling protrusion protruding along a front and rear direction extending through the front and rear surfaces of the first and second supports, and the second pad. And a second coupling part formed in the second coupling part and penetrating along the front and rear directions so that the coupling protrusion can be fitted therein and having a coupling hole corresponding to the shape of the coupling protrusion. An end plate fixed to the building structure;
A main sliding plate extending below the end plate, auxiliary sliding plates connected to the main sliding plate in a left and right direction at a lower portion of the main sliding plate to be able to slip, and the main sliding plate and the auxiliary sliding plate A sliding panel unit including a locking part connected to have a predetermined clearance in a left and right direction;
Addition plates mounted on the front and rear surfaces of the sliding panel unit;
First and second auxiliary end plates installed on both left and right ends of the adder plate and supported by a damping rod;
A plurality of friction plates installed between the adding plate, the main sliding plate, and the auxiliary sliding plate;
And a fastening unit for fastening the sliding panel unit to the friction plate and the backing plate, and fastening the frictional force of the main sliding plate and the auxiliary sliding plate to be different when the friction plate is fastened with the friction plate. Damper. 6. The method of claim 5,
The sliding panel unit includes a first auxiliary sliding plate connected to a lower side of the main sliding plate in a left and right direction, and a second auxiliary sliding plate connected to a lower side of the first auxiliary sliding plate in a left and right direction. and,
The main sliding plate and the first and second auxiliary sliding plates are formed with first to third long holes penetrating the front and rear surfaces, respectively, wherein the first long hole has the longest length and the third long hole has the relatively shortest length. Formed,
The locking portion may include a locking protrusion protruding a predetermined length upward from upper ends of the first and second auxiliary sliding plates to be inserted into a locking groove formed at a lower end of the main sliding plate and the first auxiliary sliding plate. Load bearing variable friction damper.

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