KR100919683B1 - Multi-Point Type Friction Damper and Earthquake-proof Stiffening Device - Google Patents

Abstract

The present invention relates to a multi-point friction damper and a seismic reinforcing device using the same. The multi-point friction damper, which is the core of the present invention, is cut to penetrate a plate at a constant radius about a bolt hole 11 provided at one end thereof. A first acupressure steel sheet 110 provided with an arc cut portion 22; A pair of bolt holes 11 are coupled to the front and rear surfaces of one end of the first pressure steel plate 110 so as to face each other and provided with a bolt hole 11 at a position corresponding to the bolt hole 11 of the first pressure steel plate 110. Second acupressure steel sheet 120; And a pair of first friction pads 130 inserted into and squeezed between the front and rear surfaces of the first acupressure steel plate 110 and the second acupressure steel plate 120, respectively, wherein the first friction The pad 130 is provided with a bolt hole 11 and an arc cut portion 22 so as to correspond to the first acupressure steel sheet 110, and a central bolt 150 is disposed on the front surface of the first acupressure steel sheet 110. After passing through the bolt hole 11 of the second acupressure steel plate 120 located through the first friction pad 130 and the bolt hole 11 provided in the first acupressure steel plate 110 and the first After passing through the bolt hole 11 of the second acupressure steel plate 120 located on the back of the acupressure steel plate 110 is characterized in that it is fastened to the nut.

1st Acupressure Steel Plate, 2 Acupressure Steel Plate, 1st Friction Pad, 2nd Friction Pad, Bolt Hole, Circular Cut Section, Press Washer, Center Bolt, Auxiliary Bolt

Description

Multi-point friction damper and seismic reinforcement device using same {Multi-Point Type Friction Damper and Earthquake-proof Stiffening Device}

The present invention is a first acupressure steel sheet (110) having an arc cut portion (22) cut to penetrate a plate at a constant radius about a bolt hole (11) provided at one end; A pair of bolt holes 11 are coupled to the front and rear surfaces of one end of the first pressure steel plate 110 so as to face each other and provided with a bolt hole 11 at a position corresponding to the bolt hole 11 of the first pressure steel plate 110. Second acupressure steel sheet 120; And a pair of first friction pads 130 inserted into and squeezed between the front and rear surfaces of the first acupressure steel plate 110 and the second acupressure steel plate 120, respectively, wherein the first friction The pad 130 is provided with a bolt hole 11 and an arc cut portion 22 so as to correspond to the first acupressure steel sheet 110, and a central bolt 150 is disposed on the front surface of the first acupressure steel sheet 110. After passing through the bolt hole 11 of the second acupressure steel plate 120 located through the first friction pad 130 and the bolt hole 11 provided in the first acupressure steel plate 110 and the first It relates to a multi-point friction damper and a seismic reinforcing device using the same, characterized in that is fastened to the nut after passing through the bolt hole 11 of the second acupressure steel plate 120 located on the back of the acupressure steel plate (110).

Seismic reinforcement method using hydraulic damper and seismic reinforcement method using steel damper are used as seismic reinforcement method of steel structure or concrete structure which is used at home and abroad.

     Among the existing technologies, the seismic reinforcement method using hydraulic dampers is a technology mainly used in Japan, where earthquakes occur frequently throughout the country. The design is relatively improved so that the external environment is not rough, and the seismic reinforcement performance is excellent, but domestic environmental Considering factors, firstly, the construction cost is excessively necessary, and secondly, there is a possibility that the reinforcement will be excessively unnecessary in view of the domestic earthquake frequency or progress.

     Seismic reinforcement method using steel damper is a technology that has been developed at home and abroad recently and it can be said that the construction cost is relatively inexpensive, but it is mainly developed for steel structure reinforcement, and it is also a structural problem of existing steel damper. In the case of structures, the use of windows and entrances, etc. are inconveniently restricted, and the appearance of the product is rough, which not only impairs the aesthetics of the structure, but also causes emotional anxiety, and is applicable to the seismic reinforcement of RC structures with less deformation than steel structures. There is a difficult problem.

Therefore, excessive reinforcement and excessive construction cost, which are the problems of reinforcement method using the existing hydraulic damper, and aesthetic deterioration and emotional anxiety caused by the rough appearance, which is a problem of the existing steel damper, the usability of windows and entrances, the limit of the application range, etc. There is an urgent need for a new seismic reinforcing device and construction method that can solve the problem and achieve an optimal seismic effect at a reasonable cost.

The object of the present invention created to solve the above problems is as follows.

First, an object of the present invention is to prevent the deformation of the members constituting the structure by efficiently absorbing seismic energy through the frictional heat of the friction damper.

Second, it is another object of the present invention to provide a means for amplifying the movement (strain) of the frame constituting the building frame or building frame due to the earthquake and transmitting it to the friction damper effectively.

Third, it is another object of the present invention to provide a friction damper with a fine appearance to solve the emotional anxiety and aesthetics.

Fourth, another object of the present invention is to provide a friction damper having a structure that can be easily attached to the inside and outside (window frame, etc.) of the existing structure.

Technical composition of the present invention created to achieve the above object is as follows.

The present invention is a first acupressure steel sheet (110) having an arc cut portion (22) cut to penetrate a plate at a constant radius about a bolt hole (11) provided at one end; A pair of bolt holes 11 are coupled to the front and rear surfaces of one end of the first pressure steel plate 110 so as to face each other and provided with a bolt hole 11 at a position corresponding to the bolt hole 11 of the first pressure steel plate 110. Second paper rolling plate 120; And a pair of first friction pads 130 inserted into and squeezed between the front and rear surfaces of the first acupressure steel plate 110 and the second acupressure steel plate 120, respectively, wherein the first friction The pad 130 is provided with a bolt hole 11 and an arc cut portion 22 to correspond to the first acupressure steel plate 110, and a central bolt 150 is located in front of the first acupressure steel plate 110. The bolt hole 11 provided in the two first friction pads 130 and the first acupressure steel sheet 110 disposed therebetween, penetrating through the bolt hole 11 of the second acupressure steel sheet 120 located therebetween. After passing through the bolt hole 11 of the second acupressure steel plate 120 located in the rear of the first acupressure steel plate 110 is characterized in that it is fastened to the nut.

Technical effects according to the configuration of the present invention are as follows.

First, the seismic energy can be efficiently absorbed through the frictional heat of the friction damper to prevent deformation of the members constituting the structure. When the friction damper is installed on the steel frame of the building, the displacement of the steel frame caused by the earthquake causes friction Friction between the first friction pad 130 and the second friction pad 140 in a process in which displacement is generated between the first pressure steel plate 110 and the second pressure steel plate 120 constituting the friction damper. The frictional heat caused by the resistance effectively absorbs seismic energy. This principle is the same when installing a modular rectangular frame as shown in FIG. 4 or 6 in a building.

Second, by providing a friction damper with a beautiful appearance, it can induce aesthetics and resolve emotional anxiety.

Third, by providing a friction damper having a structure that can be easily attached to the inside and outside (window frame, etc.) of the existing structure can be carried out more easily and at a lower cost seismic reinforcement construction of the existing structure.

Hereinafter, specific embodiments of the present invention will be described in more detail with reference to the accompanying drawings. (The bolt holes 11, the arc cut portions 22, and the auxiliary bolt holes 33 all have the same reference numerals for the sake of simplicity. Applied.)

Figure 1 is a perspective view of the major components constituting the present invention, Figure 2 is a perspective view showing a coupling relationship of the "b" shaped multi-point friction damper, Figure 3 is a "a" shaped friction is completed assembly Front and side views of the damper.

As shown in FIG. 1, the first acupressure steel sheet 110 is a flat steel having a predetermined width and length, and has a bolt hole 11 provided at one end thereof, and is centered on the bolt hole 11. A pair of (2) circular arc incisions (22) cut to penetrate the plate at a constant radius are provided so as to face each other.

As shown in FIG. 1, the second acupressure steel plate 120 is a flat steel having a predetermined width and length, and the two acupressure steel plates 120 form a pair and face each other in front and rear of one end of the first acupressure steel plate 110. It is coupled, the bolt hole 11 is provided at a position corresponding to the bolt hole 11 of the first pressure steel plate (110).

In addition, the auxiliary bolt hole 33 is provided to face each other centering on the bolt hole 11 of the second acupressure steel plate 120 at a position corresponding to the arc cut portion 22 of the first acupressure steel plate 110.

The outer shape of the first acupressure steel plate 110 and the second acupressure steel plate 120 is not necessarily limited to the shape shown in FIGS. 1 to 3 or the shape shown in FIG. 5, and the width, length, or shape may be appropriately changed. have.

As shown in FIG. 2, the first friction pad 130 is disposed between any one of the front surface of the first acupressure plate 110 and the second acupressure plate 120, and the rear surface of the first acupressure plate 110 and the second. Each of the acupressure steel sheets 120 is inserted into each other and compressed.

As shown in FIG. 1, the first friction pad 130 is provided with a bolt hole 11 and an arc cut portion 22 to correspond to the first pressure steel plate 110.

As shown in FIG. 2, the central bolt 150 penetrates through the bolt holes 11 of the second acupressure steel plate 120 located in front of the first acupressure steel plate 110, thereby providing two first friction pads 130. And a second acupressure steel plate located behind the first acupressure steel plate 110 after passing through the bolt holes 11 provided in each of the first acupressure steel plates 110 positioned between the two first friction pads 130 ( It is fastened to the nut after penetrating the bolt hole 11 of the 120, shown in Figure 2 between the head of the central bolt 150 and the second acupressure steel plate 120 located in front of the first acupressure steel plate 110. As described above, the pressing washer 170 and the second friction pad 140 are inserted, and between the nut fastened to the central bolt 150 and the second acupressure steel plate 120 located behind the first acupressure steel plate 110. As shown in FIG. 2, the compression washer 170 and the second friction pad 140 are inserted.

The first acupressure steel plate 110 and the second acupressure steel plate 120 are combined to form a "b" shape, as shown in Figure 3, using two auxiliary bolts 160 separately from the central bolt 150 Thus, the first friction pad 130 is compressed at three points.

The auxiliary bolt 160 is fastened to a position facing each other with respect to the center bolt 150, and passes through the auxiliary bolt hole 33 of the second acupressure steel plate 120 located in front of the first acupressure steel plate 110. After passing through the circular arc incision 22 provided in each of the two first friction pad 130 and the first acupressure steel plate 110 positioned therebetween, the second acupressure is located behind the first acupressure steel plate 110. After passing through the auxiliary bolt hole 33 of the steel plate 120, it is fastened to the nut. (If necessary, a washer may be used together.)

Such a multi-point friction damper may be installed in the steel frame of the existing building itself to the earthquake-resistant action, as shown in Figure 4 to make a module installed in the interior of the rectangular vertex of the frame in advance and seismic module It can also be installed in existing buildings that need reinforcement.

Figure 4 shows an embodiment of the seismic reinforcement device using a multi-point friction damper of the "b" shape.

In the seismic reinforcing device shown in Figure 4 (a), the two ends of each of the two horizontal steel frame 180 and two vertical steel frame 190 is welded or bolted to form a rectangular frame, horizontal steel frame Inside the vertex where the frame 180 and the vertical steel frame 190 meet each other, the first acupressure steel sheet 110 and the second acupressure steel sheet 120 of the multi-point friction damper 100 having a "A" shape are welded or the like. It is fixed by the method.

In the seismic reinforcement device shown in Figure 4 (b), two horizontal steel frame 180 and two vertical steel frame 190, both ends are combined to form a rectangular frame, horizontal steel frame 180 ) And one of the four vertices where the vertical steel frame 190 meets is fixed by welding or bolted, and the other three vertices are pinned and can be rotated. A friction pad may be inserted to allow friction force to be applied during rotation.)

Inside the vertices where the horizontal steel frame 180 and the vertical steel frame 190 meet each other, the first acupressure steel sheet 110 and the second acupressure steel sheet 120 of the multi-point friction damper 100 of the "a" shape are respectively formed. The joint is fixed by welding or the like.

FIG. 5 illustrates a frictional damper of the "W" shape in which two multi-point friction dampers of the "A" shape are coupled. The two ends of the multi-point friction damper 100 of the "A" shape are coupled to each other. Forming a "ㅁ" shape, the coupling structure between the new first pressure plate 110 and a pair of second pressure plate 120 is also a conventional first pressure plate 110 and a pair of second acupressure It is made in the same manner as the bonding structure between the steel sheet (120).

5 shows a seismic reinforcing device using the multi-point friction damper 100 of the " W " shape shown in FIG.

6 (a), the seismic reinforcing device shown in FIG. 6 (a) has two horizontal steel frames 180 and two vertical steel frames 190, both ends of which are welded or bolted to form a rectangular frame and horizontal steel frame. Inside the vertex where the frame 180 and the vertical steel frame 190 meet each other, the first acupressure steel plate 110 and the second acupressure steel plate 120 of the multi-point friction damper 100 having a "ㅁ" shape are welded or the like. It is fixed by the method.

6 (b), the seismic reinforcing device is two horizontal steel frame 180 and two vertical steel frame 190, both ends are combined to form a rectangular frame, horizontal steel frame 180 ) And one of the four vertices where the vertical steel frame 190 meets is fixed by welding or bolted, and the other three vertices are pinned and can be rotated. A friction pad may be inserted to allow friction force to be applied during rotation.)

Inside the vertices where the horizontal steel frame 180 and the vertical steel frame 190 meet each other, the first acupressure steel sheet 110 and the second acupressure steel sheet 120 of the multi-point friction damper 100 having a "ㅁ" shape are respectively formed. The joint is fixed by welding or the like.

When the multi-point friction damper 100 is directly installed on the steel frame of a building, the displacement of the steel frame generated by the earthquake is transmitted to the friction damper, and the first pressure steel plate 110 and the second pressure steel sheet constituting the friction damper. In the process of displacement between 120, frictional heat due to frictional resistance between the first friction pad 130 and the second friction pad 140 effectively absorbs seismic energy.

In addition, the same effect can be obtained when the modular frame of the rectangular form as shown in FIG. 4 or 6 is installed in a window frame or an entrance of a building.

7 is an embodiment in which the arc cutout 22 is not provided, the auxiliary bolt hole 33 and the auxiliary bolt 160 associated with the arc cutout 22 are not used, and FIG. 8 is a circular cutout. It is shown that the number 22 of the auxiliary bolt hole 33 and the auxiliary bolt 160 also increases in response to the case where a plurality of 22 are provided while varying the distance from the bolt hole 11.

In the case of Figure 7, the first acupressure plate 110 and the first friction pad 130 is not provided with an arc cut portion 22, the second acupressure plate 120 is not provided with an auxiliary bolt hole 33, There is a difference that the assembly is made using only the central bolt 150 is not used when the auxiliary bolt 16 is used, the remaining part is assembled in the same manner and structure as in the case of Figures 2 to 6, Detailed illustration or additional description thereof will be omitted.

In the case of Figure 8, the first acupressure steel sheet 110 and the first friction pad 130 are provided with two pairs (four) so that the arcuate cut portion 22 is different from the distance between the bolt hole 11, The second acupressure steel plate 120 has a plurality of auxiliary bolt holes 33 at a position corresponding to the arc cutout 22 provided in each of the first acupressure steel plate 110 and the first friction pad 130. 11) is provided so as to face each other with respect to each other, there is a difference that the auxiliary bolt 160 is additionally used as much as the number of the increased auxiliary bolt holes 33, the remaining part is the same manner and structure as in the case of Figs. Bar assembly is made, specific illustration or additional description thereof will be omitted. In some cases, two or more pairs of arc cutouts 22 may be provided.

Although the technical spirit of the present invention has been described with reference to specific embodiments of the present invention as described above, the scope of protection of the present invention is not necessarily limited to these embodiments, and various designs may be made without changing the technical spirit of the present invention. Changes, additions or deletions of well-known technology, and simple numerical limitations also make it clear that they belong to the protection scope of the present invention.

1 is a perspective view of the major components of the present invention.

Figure 2 is a perspective view showing the coupling relationship of the "b" shaped multi-point friction damper.

Figure 3 is a front view and a side view of the friction damper of the "-" shape is completed assembly.

Figure 4 is an embodiment of the seismic reinforcement device using a multi-point friction damper of the "b" shape.

(a) a case where the vertical steel frame 190 and the horizontal steel frame 180 is welded or bolted, (b) any of four vertices to which the vertical steel frame 190 and the horizontal steel frame 180 is coupled Only one is welded or bolted and fixed, and the other three vertices are pinned and pivotable.

Fig. 5 shows a friction damper in the shape of a "wh" shape in which two multi-point friction dampers in the shape of "a" are combined.

Figure 6 is an embodiment of the seismic reinforcement device using a multi-point friction damper of the "ㅁ" shape.

(a) a case where the vertical steel frame 190 and the horizontal steel frame 180 is welded or bolted, (b) any of four vertices to which the vertical steel frame 190 and the horizontal steel frame 180 is coupled Only one is welded or bolted and fixed, and the other three vertices are pinned and pivotable.

7 shows an embodiment in which the arc cutout 22 is not provided, and the auxiliary bolt hole 33 and the auxiliary bolt 160 associated with the arc cutout 22 are not used.

8 shows a case in which a plurality of arc cutouts 22 are provided with different distances from the bolt holes 11, so that the amount of use of the auxiliary bolt holes 33 and the auxiliary bolts 160 increases.

<Description of the symbols for the main parts of the drawings>

100: multi-point friction damper

110: first acupressure steel sheet

120: second acupressure steel sheet

130: first friction pad

140: second friction pad

150: center bolt

160: auxiliary bolt

170: compression washer

180: horizontal steel frame

190: vertical steel frame

11: Bolt hole

22: arc incision

33: Auxiliary bolt hole

Claims (9)

A first acupressure steel plate 110 having a bolt hole 11 at one end thereof; A pair of first coupled to the front and rear of one end of the first pressure steel plate 110 to face each other and provided with a bolt hole 11 at a position corresponding to the bolt hole 11 of the first pressure steel plate 110 2 acupressure steel sheet 120; And, A pair of first friction pads 130 inserted into and compressed between the front and rear surfaces of the first acupressure steel plate 110 and the second acupressure steel plate 120; Consists of including The first friction pad 130 is provided with a bolt hole 11 at a position corresponding to the bolt hole 11 of the first acupressure steel plate 110, The central bolt 150 penetrates through the bolt holes 11 of the second acupressure steel plate 120 located in front of the first acupressure steel plate 110, thereby providing two first friction pads 130 and the first friction pad 130. After passing through the bolt hole 11 provided in the first pressure steel plate 110 positioned between the friction pad 130, the second pressure steel plate 120 located behind the first pressure steel plate 110. After passing through the bolt hole 11 and fastened to the nut, Each of the first acupressure steel sheet 110 and the first friction pad 130 has a pair of arc cut portions 22 cut through the plate at a constant radius about the bolt hole 11 to form a bolt hole 11. ) Are provided to face each other, Each of the second acupressure steel plates 120 has a pair of auxiliary bolt holes 33 at positions corresponding to the arc cut portions 22 provided on the first acupressure steel plates 110 and the first friction pads 130, respectively. ) Are provided to face each other with respect to the bolt hole 11, The first acupressure steel sheet 110 and the second acupressure steel sheet 120 are combined to form a "a" shape, The central bolt 150 is fastened to a position facing each other, and through the auxiliary bolt hole 33 of the second acupressure steel plate 120 located in front of the first acupressure steel plate 110 and the two The first acupressure steel sheet after passing through the central portion of the arc cut portion 22 provided in each of the first acupressure steel sheet 110 positioned between the first friction pad 130 and the first friction pad 130. A pair of auxiliary bolts 160 fastened to the nuts after passing through the auxiliary bolt holes 33 of the second acupressure steel plate 120 located at the rear of the 110; Multi-point friction damper characterized in that it further comprises. A first acupressure steel plate 110 having a bolt hole 11 at one end thereof; A pair of first coupled to the front and rear of one end of the first pressure steel plate 110 to face each other and provided with a bolt hole 11 at a position corresponding to the bolt hole 11 of the first pressure steel plate 110 2 acupressure steel sheet 120; And, A pair of first friction pads 130 inserted into and compressed between the front and rear surfaces of the first acupressure steel plate 110 and the second acupressure steel plate 120; Consists of including The first friction pad 130 is provided with a bolt hole 11 at a position corresponding to the bolt hole 11 of the first acupressure steel plate 110, The central bolt 150 penetrates through the bolt holes 11 of the second acupressure steel plate 120 located in front of the first acupressure steel plate 110, thereby providing two first friction pads 130 and the first friction pad 130. After passing through the bolt hole 11 provided in the first pressure steel plate 110 positioned between the friction pad 130, the second pressure steel plate 120 located behind the first pressure steel plate 110. After passing through the bolt hole 11 and fastened to the nut, Each of the first acupressure steel sheet 110 and the first friction pad 130 has a plurality of pairs of circular arc cutouts 22 cut through the plate while varying a distance from the center of the bolt hole 11. It is provided to face each other with respect to the hole 11, The second acupressure steel plate 120 has a plurality of auxiliary bolt holes 33 at positions corresponding to the arc cutouts 22 provided in the first acupressure steel plate 110 and the first friction pad 130, respectively. It is provided to face each other around the bolt hole 11, The first acupressure steel sheet 110 and the second acupressure steel sheet 120 are combined to form a "a" shape, The central bolt 150 is fastened to a position facing each other, and through the auxiliary bolt hole 33 of the second acupressure steel plate 120 located in front of the first acupressure steel plate 110 and the two The first acupressure steel sheet after passing through the central portion of the arc cut portion 22 provided in each of the first acupressure steel sheet 110 positioned between the first friction pad 130 and the first friction pad 130. A plurality of auxiliary bolts 160 fastened to the nuts after passing through the auxiliary bolt holes 33 of the second acupressure steel plate 120 located at the rear of the 110; Multi-point friction damper characterized in that it further comprises. The method of claim 1, wherein A compression washer 170 inserted between the head of the central bolt 150 and the second acupressure steel plate 120 and between the nut fastened to the central bolt 150 and the second acupressure steel plate 120; And, The pair of second friction pads 140 are manufactured in the same shape as the pressing washer 170 and are inserted between each of the pair of second acupressure steel plates 120 and each of the pressing washer 170 to be compressed. ; Multi-point friction damper characterized in that it further comprises. In claim 3, The two ends of the "a" shaped multi-point friction damper 100 are coupled to each other to form a "ㅁ" shape, The coupling structure between the newly formed first acupressure steel plate 110 and the pair of second acupressure steel plates 120 is also a coupling structure between the existing first acupressure steel plate 110 and the pair of second acupressure steel plates 120. Multi-point friction damper, characterized in that the same. As to a seismic reinforcing device using the multi-point friction damper 100 according to claim 3, Two horizontal steel frames 180; And, Two vertical steel frame 190; This includes, but each is welded or bolted to form a rectangular frame, Inside the vertex where the horizontal steel frame 180 and the vertical steel frame 190 meet each of the first acupressure steel plate 110 and the second acupressure steel sheet of the multi-point friction damper 100 of the "b" shape ( Seismic reinforcement device using a multi-point friction damper, characterized in that the coupling 120 is fixed. As to a seismic reinforcing device using the multi-point friction damper 100 according to claim 3, Two horizontal steel frames 180; And, Two vertical steel frame 190; Is included, each side end is coupled to form a rectangular frame, any one of the four vertices of the horizontal steel frame 180 and the vertical steel frame 190 is welded or bolted to be fixed The other three vertices are pinned and pivotable, Inside the vertex where the horizontal steel frame 180 and the vertical steel frame 190 meet each of the first acupressure steel plate 110 and the second acupressure steel sheet of the multi-point friction damper 100 of the "b" shape ( Seismic reinforcement device using a multi-point friction damper, characterized in that the coupling 120 is fixed. As to a seismic reinforcing device using the multi-point friction damper 100 according to claim 4, Two horizontal steel frames 180; And, Two vertical steel frame 190; This includes, but each is welded or bolted to form a rectangular frame, Inside the vertices where the horizontal steel frame 180 and the vertical steel frame 190 meet each other, the first acupressure steel plate 110 and the second acupressure steel plate 110 of the multi-point friction damper 100 having a "ㅁ" shape are formed. Seismic reinforcement device using a multi-point friction damper, characterized in that the coupling 120 is fixed. As to a seismic reinforcing device using the multi-point friction damper 100 according to claim 4, Two horizontal steel frames 180; And, Two vertical steel frame 190; Is included, each side end is coupled to form a rectangular frame, any one of the four vertices of the horizontal steel frame 180 and the vertical steel frame 190 is welded or bolted to be fixed The other three vertices are pinned and pivotable, Inside the vertices where the horizontal steel frame 180 and the vertical steel frame 190 meet each other, the first acupressure steel plate 110 and the second acupressure steel plate 110 of the multi-point friction damper 100 having a "ㅁ" shape are formed. Seismic reinforcement device using a multi-point friction damper, characterized in that the coupling 120 is fixed. delete

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