KR20180047926A - Light Insulation stone pannel structure for vibration absorption - Google Patents

Abstract

The present invention relates to a light insulation stone panel structure with improved vibration absorption characteristics and, more particularly, to a light insulation stone panel structure for vibration absorption including a very thin stone panel and fixed hardware having vibration absorption characteristics for stone panel fixing on a wall body for economic cost reduction, lightweightness for zero building load burden, convenient construction, high durability, easy repair and maintenance, and efficient use as a building exterior finishing material. In the light insulation stone panel structure for an exterior construction material according to the present invention, which is integrally coupled with an insulating material, an insulating layer with a predetermined thickness is integrated with the stone panel formed of a stone processed in a predetermined size and a predetermined thickness and construction is performed with the simple vibration-absorbing fixed hardware, and thus exterior wall finishing can be expedited and facilitated in various buildings and construction period and cost reduction can be achieved. In addition, the finishing material is inexpensive, economical, and very light in weight, and thus building load burden is not given, high durability can be achieved, repair and maintenance can be facilitated, and efficient use is possible during building exterior finishing work.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a lightweight insulation-

More particularly, the present invention relates to a lightweight stone panel panel structure having improved dustproof characteristics, and more particularly, to a stone panel panel having a very thin thickness and a stationary iron piece having a dustproof property for fixing the panel panel to a wall, Lightweight insulation stone panel structure for lightweight insulation that can be efficiently used as a finishing material for a building because it is lightweight and does not burden the load of the building, and is simple in construction, excellent in durability and easy to maintain.

Generally, a stone panel used as a cladding material for a building structure is made of granite or granite with a thickness of about 30 to 60 mm and formed into a plate shape. When such a stone panel is to be constructed, And between the stone panel and the connecting plate, and between the outer wall of the building and the supporting steel plate and the connecting plate through the anchor bolts, respectively, with the connecting plate interposed therebetween.

The reason why the general stone thickness is set to about 30 to 60 mm is to prevent the stone from cracking with respect to external force when the stone is loaded in the cargo compartment for transportation or for construction with a building exterior material, And the weight per stone panel is 50 ~ 60 kg. Thus, it is difficult to handle the stone, it is very difficult to construct the stone, and it takes a lot of time for the construction, and it is a cause of the safety accident during the construction work.

Since the stone is fixed to the connecting plate through the anchor bolts and the connecting plate is fixed to the outer wall of the building or the supporting steel through the anchor bolts, the outside temperature of the summer increases, Or the supporting steel, the stone panels can not be kept flat and swell outwardly, and cracks are generated in the stone panels.

On the other hand, in order to insulate the building, a heat insulating material is inserted between the stone panel and the building. When the heat insulating material is first inserted, the difference between the tolerance of the portion where the heat insulating material is placed, The insulation material is struck downward as the seal passes. As a result, the space between the stone panel and the building becomes vacant at the upper end of each unit insulation, so that the insulation can not be secured.

In order to provide the decorative panel with the decorative panel on the outer wall of the building together with the panel of stone, the decorative panel is attached and installed in a state in which the panel is kept at a predetermined distance from the surface of the panel There is a problem that the installation cost of the wall finishing work of the building is increased because the installation of the stone panel and the heat insulating material are separately made by separate processes.

In addition, the conventional external finishing material installation method does not have a structure capable of absorbing and dispersing a strong impact applied to a building due to natural disasters such as an earthquake or a typhoon. Thus, when an external impact is generated, the outer wall is damaged, There is a problem of causing breakage.

Korean Patent No. 10-1353096 (Jan. 13, 2014) Korean Patent Registration No. 10-1188812 (Oct. Korean Patent Laid-Open No. 10-2011-0122423 (November 10, 2011)

The inventors of the present invention have made intensive studies to develop a stone panel structure having improved dustproof characteristics, durability, light weight, easy installation and maintenance, and as a result, it has been found that, as described later, Can satisfy not only the above requirements but also provide additional advantages, and have accomplished the present invention.

SUMMARY OF THE INVENTION Accordingly,

A lightweight insulation stone panel structure for a building exterior member integrally bonded to a heat insulating material,

Wherein the adjusting plate engaging groove is horizontally formed at the upper and lower ends and is engaged with the upper or lower panel by an adjusting plate, the joining portion of the panel is silicon-filled in the outside, The inside of the locking groove is made of epoxy-filled stone panel for building exterior material;

A rigid polyurethane insulation material layer adhered to a back surface of the stone panel;

A film-like aluminum back sheet layer adhered to the back surface of the rigid polyurethane heat insulating material layer;

A "T" -shaped adjustment plate coupled to upper and lower ditch grooves of the stone panel, and having a slope such that the thickness becomes thicker toward the end;

An "L" -shaped fixing bracket fixed to the outer wall of the building or the supporting steel through an anchor bolt;

A slope is formed such that the thickness becomes thicker toward the end, and the outer side is elastically contacted with the stone panel while the inner side is engaged with the fixed metal A fixed cap having an inner side and an outer side to form a simultaneous engagement structure;

A first shock absorbing member disposed between the anchor bolt and the fixing bracket and interposed by a bolt connection and having an elastic layer adhered to the inner and outer metal plate layers; a second shock absorbing member interposed between the first shock absorbing member and the first shock absorbing member A horizontal vibration preventing member composed of at least one second shock absorbing member made of a ring-shaped elastic material and a third shock absorbing member made of a shock absorbing spring interposed between the second shock absorbing members by bolt connection; And

A first shock absorbing member disposed between the adjustment plate and the fixing bracket and interposed by bolt engagement and having an elastic layer adhered to the inner and outer metal plate layers; a second shock absorbing member interposed between the first shock absorbing member and the first shock absorbing member And a vertical vibration preventing member composed of at least one second shock absorbing member made of a ring-shaped elastic material and a third shock absorbing member made of a shock absorbing spring interposed between the second shock absorbing members by bolt connection And to provide a lightweight insulation stone panel structure for vibration isolation.

According to the dustproof lightweight insulation stone panel structure integrally bonded to the heat insulating material according to the present invention, a heat insulating layer having a certain thickness is integrally formed on a stone panel made of stone processed to a predetermined size and thickness, It is possible to quickly and easily apply the finishing work to the outer walls of various buildings, thereby providing a useful effect of shortening the construction period and reducing the construction cost. In addition, since the cost of the finishing material is low, it is economical and light in weight, so that it does not burden the load of the building, it is durable and easy to maintain and repair, so it can be effectively used for finishing work for building finishing.

1 is a plan view of a lightweight insulation stone panel structure according to the present invention.
2 is a sectional view of a lightweight insulation stone panel structure according to the present invention.
Fig. 3 is an enlarged cross-sectional view of a state in which the fixed metallic material according to the present invention is applied.
4 is a cross-sectional view and plan schematic view of an adjusting plate according to the present invention.
5 is a cross-sectional view of an adjustment plate according to a further embodiment of the present invention.
6 (a) is a schematic view of a fixed cap showing a state in which it is fastened to an adjustment plate;
6 (b) is an explanatory view showing the state of the fixed cap before it is fastened to the adjustment plate.
Fig. 7 is a view for explaining the fastening state of the horizontal vibration-proof member of the present invention, and Fig. 8 is an exploded exploded view of Fig.
9 is a schematic view of the first shock absorbing member.
10 is a view for explaining another preferred embodiment of the horizontal vibration-proof member according to the present invention.
Fig. 11 is a view for explaining the fastening state of the vertical vibration-proof member of the present invention, and Fig. 12 is an exploded exploded view of Fig.
13 is a view for explaining a vertical vibration-damping member according to a further embodiment of the present invention.
14 is a view for explaining a modified form of the vertical vibration-proof member according to a further embodiment of the present invention.
15 is a view for explaining a vertical vibration damping member according to another preferred embodiment of the present invention.

The present invention, in one aspect,

A lightweight insulation stone panel structure for a building exterior member integrally bonded to a heat insulating material,

Wherein the adjusting plate engaging groove is horizontally formed at the upper and lower ends and is engaged with the upper or lower panel by an adjusting plate, the joining portion of the panel is silicon-filled in the outside, The inside of the locking groove is made of epoxy-filled stone panel for building exterior material;

A rigid polyurethane insulation material layer adhered to a back surface of the stone panel;

A film-like aluminum back sheet layer adhered to the back surface of the rigid polyurethane heat insulating material layer;

A "T" -shaped adjustment plate coupled to upper and lower ditch grooves of the stone panel, and having a slope such that the thickness becomes thicker toward the end;

An "L" -shaped fixing bracket fixed to the outer wall of the building or the supporting steel through an anchor bolt;

A slope is formed so as to be thicker toward the end portion, and the outer side is elastically contacted with the stone panel when fastened, and the inner side is engaged with the fixed metal piece A fixed cap which forms a simultaneous engagement structure of the inner side and the outer side;

A first shock absorbing member disposed between the anchor bolt and the fixing bracket and interposed by a bolt connection and having an elastic layer adhered to the inner and outer metal plate layers; a second shock absorbing member interposed between the first shock absorbing member and the first shock absorbing member A horizontal vibration preventing member composed of at least one second shock absorbing member made of a ring-shaped elastic material and a third shock absorbing member made of a shock absorbing spring interposed between the second shock absorbing members by bolt connection; And

A first shock absorbing member disposed between the adjustment plate and the fixing bracket and interposed by bolt engagement and having an elastic layer adhered to the inner and outer metal plate layers; a second shock absorbing member interposed between the first shock absorbing member and the first shock absorbing member And a vertical vibration preventing member composed of at least one second shock absorbing member made of a ring-shaped elastic material and a third shock absorbing member made of a shock absorbing spring interposed between the second shock absorbing members by bolt connection (EN) Disclosed is a lightweight insulation stone panel structure for vibration isolation.

The present invention, in a further aspect,

Wherein the first shock absorbing member comprises a first metal layer interposed by bolting, an elastic layer adhered to both ends of the first metal layer, and a second metal layer adhered to the elastic layer. Lt; / RTI >

The invention, in another further aspect,

Wherein the horizontal vibration-damping member is arranged symmetrically on two front and rear sides of the fixing bracket.

The invention, in another further aspect,

Wherein the vertical vibration damping member comprises a cushion spring interposed between the adjusting plate and the fixing bracket by a bolt coupling and a cushion spring protection cap slidably disposed on the outer side of the cushion spring, The present invention provides a lightweight insulation stone panel structure for a dustproof case, characterized in that it is a building bolt made of nacre.

The invention, in another further aspect,

Wherein the adjustment plate and the bracket are formed with a release barrier for receiving the buffer spring protection cap and preventing the buffer spring from protruding.

The invention, in another further aspect,

Wherein the vertical vibration preventing member comprises a buffer spring interposed between the adjusting plate and the fixing bracket by bolts, and the adjusting plate and the bracket are formed with spring seating grooves for receiving the buffer springs and preventing the buffer springs from being separated. A lightweight insulation stone panel structure is provided.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a lightweight insulation stone panel structure for a building exterior according to a first embodiment of the present invention will be described in detail with reference to the accompanying drawings.

It is to be understood that the terminology or words used herein are not to be construed in an ordinary or preliminary sense and that the inventor may properly define the concept of a term to describe its invention in the best possible way And should be construed as meaning and concept consistent with the technical idea of the invention.

FIG. 1 is a plan view of a lightweight insulation stone panel structure for a dustproof building exterior material according to the present invention, FIG. 2 is a sectional view of a lightweight insulation stone panel structure for a dustproof building exterior material according to the present invention, FIG. 4 is a sectional view and a plan view of a control panel of a stone panel structure according to the present invention. FIG.

In the lightweight insulation stone panel structure for a dustproof building exterior material according to the present invention, the stone panel 100 is integrally joined with the heat insulating material layer 200, is formed in a generally flat shape and has a substantially rectangular shape, but its kind is not particularly limited And any natural stone or artificial stone that can be used as a cladding sheath may be used without limitation.

The thickness of the stone panel 100 may be 0.3 mm to 20 mm, preferably 0.5 mm to 10 mm, and most preferably 5 mm to 7 mm. If the thickness of the stone panel is less than 0.3 mm, there is a possibility that the workability of the stone panel is difficult and the overall strength is lowered. If the thickness exceeds 20 mm, overload, workability, economical efficiency and / .

In the stone panel 100, the adjusting grooves of the adjusting plate 310 are horizontally formed at the upper and lower ends thereof, and are engaged by the adjusting plate 310 together with the upper or lower panel. The joining portion of the panel 100 is silicon- , The inside of the latching groove of the adjusting plate 310 is epoxy filled. The width and depth of the grooves formed therein are preferably such that the adjustment plate 310 is accommodated.

In the prior art, it is difficult to use a panel having a groove formed in a thin stone. However, the present invention has various merits such as economical efficiency and efficiency by providing a thin stone having a groove.

A heat insulating material layer 200 is adhered to the back surface of the stone panel 100. It is preferable to use hard polyurethane as a material of the heat insulating material.

In the prior art, the polyurethane insulation layer 200 is installed separately from most of the stone panel 100 for keeping warm, flame retardant and heat-insulating, and is disposed between the outer wall 400 of the building and the supporting steel, However, according to the present invention, the polyurethane insulation material layer 200 integrated with the stone panel 100 by the adhesive can support and reinforce the stone panel 100 in addition to the simplicity of construction, economy and efficiency, and improve the durability have.

A film-like aluminum back sheet layer 210 is adhered to the back surface of the rigid polyurethane heat insulating material layer 200 so that the stone panel 100, the heat insulating material layer 200 and the back sheet layer 210 form a single set of stone panels .

Such a stone panel set is joined to the adjustment plate 310 of the fixed hardware 300 at the same time by combining the two upper and lower sets.

The fixed hardware 300 for fixing the set of stone panels to the outer wall of the building includes the adjusting plate 310, the bolts 320, the fixing brackets 330, the anchor bolts 340, the horizontal vibration preventing members and the vertical vibration preventing members .

As shown in Fig. 4, the adjustment plate 310 may have a cross-section of a "T" shape, and a slope may be formed such that the thickness of the head portion increases toward the end portion. The adjusting plate 310 is fastened to the latching grooves 101 formed horizontally at the upper and lower ends of the stone panel 100.

5 is a cross-sectional view of a modified version of the adjustment plate 310, characterized in that a step is formed between the neck 313 and the end 314. Since the neck 313 and the flange 314 form a step difference in thickness, the stone panel 100 can be easily joined. The larger the step, the less the gap between the panels 100 is, so that the construction can be simplified.

The fixing bracket 320 has a generally L-shaped cross section, one side of which is connected to the adjusting plate 310 by bolts 320, and the other side of which is fixed to the outer wall of the building or the supporting steel through the anchor bolts 340 do.

In the stone panel structure of the present invention, the stone panel 100 is interlocked with the upper or lower panel by the adjustment plate 310, the joint of the panel is filled with the joint silicon 311 from the outside, The inner side of the adjusting plate latching groove of the fixing plate 312 is filled with the epoxy 312 so that the panel and the adjusting plate are firmly fastened.

In the present invention, the epoxy resin (312) may be an epoxy resin which is commonly used in the art as an epoxy resin.

Fig. 6 (a) is a schematic cross-sectional view of a fixed cap showing a state where the fixed cap is fastened to such an adjusting plate, and Fig. 6 (b) is a sectional view showing a state of the fixed cap before fastening to the adjusting plate according to one embodiment of the present invention.

The fixing cap 500 preferably has a structure in which the outer side is elastically coupled to the panel 100 and the inner side is coupled to the adjustment plate 310, as shown in FIG. 6 (b). The fixed cap 500 improves the durability of the stone panel structure and can stably absorb an external force such as a typhoon or an earthquake. It is possible to prevent the stone from cracking.

The fixing cap 500 is fixed to the adjusting plate 310 in a "C" shape, and is formed of a rigid metal material. A gradient is formed so that the thickness becomes thicker toward the end, And the inner side is engaged with the fixed hardware so that the inner side and the outer side form a simultaneous engagement structure. Accordingly, the fixed cap 500 provides a simultaneous engagement structure inside and outside of the adjustment plate 310.

The durability of the panel structure according to the present invention can be further increased by filling epoxy 312 on the outer side of the fixed cap 500 of the stone panel 100.

When the external force F is applied to the stone and the slide plate is pushed into the groove formed in the panel 100 after the adjustment plate 310 is coupled to the fixed cap 500, the outer side of the adjustment plate 310 provides an elastic force to the panel 100, And the inner side is fixed by mutual engagement with the adjustment plate 310. [

6 (b), it is preferable that the fixing cap 500 is formed to have a slope in its cross section so as to become thicker as it goes to the end, and the thickness of the head portion of the adjusting plate 310 becomes smaller toward the end It may be desirable for the gradient to be thickened (d1 < d2).

Fig. 7 is a view for explaining the fastening state of the horizontal vibration-proofing member of the present invention, Fig. 8 is an exploded exploded view of Fig. 7, Fig. 9 is a schematic view of the first shock- Is a side view.

The horizontal vibration preventing member is disposed between the anchor bolts 340 and the fixing bracket 330 and is interposed by bolt connection. According to one embodiment, the horizontal vibration preventing member may include a first shock absorbing member 341, A third shock absorbing member 343 and at least one second shock absorbing member 342 are interposed in order in the anchor bolt 340 and fastened by a nut 345 engagement.

The first shock absorbing member 341 includes a first metal layer 341b interposed by bolt engagement, an elastic layer 341c bonded to both ends of the first metal layer 341b, and a first metal layer 341b bonded to the elastic layer 341c 2 metal layer 341a. Here, the first metal layer 341b is formed with a fastening hole at the center so as to be interposed by the bolts 341.

The first and second metal layers may be made of a material such as metal, hardened plastic or fiber cured material, and the elastic layer 341c may be made of rubber or an elastic plastic material so as to effectively absorb vibrations. Reference numeral 344 denotes a washer.

The second shock absorbing member 342 may be disposed on the inside or outside of the first shock absorbing member, and is formed of a ring-shaped elastic material.

The third shock-absorbing member 343 is interposed between the second shock-absorbing members by bolt connection, and is made up of a cushioning spring. The cushioning spring is capable of maintaining a certain elastic force, It is preferable to use a material such as titanium, low carbon steel, stainless steel or the like, and to prevent the rust, it is preferable to apply an anti-rust coating.

10 is a view for explaining another preferred embodiment of the horizontal vibration damping member according to the present invention, wherein two horizontal vibration damping members are arranged symmetrically on the front and rear sides of the fixing bracket 330, 400, the horizontal vibration can be efficiently absorbed.

Fig. 11 is a view for explaining the fastening state of the vertical vibration-proof member of the present invention, and Fig. 12 is an exploded exploded view of Fig.

The vertical vibration preventing member is disposed between the adjusting plate 310 and the fixing bracket 330 and is interposed by bolt connection. According to this embodiment, the first shock absorbing member 323, the at least one second shock absorbing member 324, the third shock absorbing member 325 and the at least one second shock absorbing member 324 are attached to the bolt 321 And are fastened in this order by bolt (326) engagement. Reference numeral 322 denotes a washer.

The first shock absorbing member 323 includes a first metal layer 323b interposed by bolt engagement, an elastic layer 323c bonded to both ends of the first metal layer 323b, and a second metal layer 323b bonded to the elastic layer 323c 2 metal layer 323a. Here, the first metal layer 323b is formed with a fastening hole at a central portion thereof so as to be interposed by the bolts 321.

The first and second metal layers may be made of a material such as a metal, a hardened plastic or a fiber composite cured material, and the elastic layer 323c may be made of rubber or an elastic plastic material so as to effectively absorb vibrations.

The second shock absorbing member 324 can be disposed on the upper and lower sides of the first shock absorbing member, and is made of a ring-shaped elastic material.

The third shock-absorbing member 325 is interposed between the second shock-absorbing members by bolt connection, and is made of a cushioning spring. The cushioning spring is capable of maintaining a certain elastic force, It is preferable to use a material such as titanium, low carbon steel, stainless steel or the like, and to prevent the rust, it is preferable to apply an anti-rust coating.

13 is a view for explaining a vertical vibration-damping member according to a further embodiment of the present invention.

The vertical vibration damping member according to the further embodiment includes a cushioning spring 325 interposed between the adjustment plate 310 and the fixing bracket 330 by a bolt 321 engagement and a cushioning spring 325 slidably disposed outside the full- It may be preferable that it is made up of the buffer spring protection caps 327 and 328 in a cylindrical shape.

The protective caps 327 and 328 prevent the buffer spring 325 from being released and the spring from being exposed to wind and rain to give a durability to the structure. The height of the protective caps 327 and 328 can be set as needed. In addition, one of the upper and lower portions of the protective caps 327 and 328 may be slidably received by the other, but a cylindrical structure may be preferable, though it is not limited thereto.

In the meantime, the bolts 321 and 340 used in the present invention may be more suitable for securing a constant clearance by using construction bolts made of only a certain part of the bolts.

14 is a view for explaining a modified form of the vertical vibration preventing member according to the further embodiment of the present invention shown in Fig.

In this embodiment, the release plate 329 is formed on the adjustment plate 310 and the bracket 330 to receive the buffer spring protection cap and prevent the release of the buffer spring protection cap, so that the structure can be supported more stably.

Fig. 15 is a view for explaining another preferred form of the vertical vibration-damping member. Fig.

The vertical vibration damping member according to this embodiment is composed of a buffer spring 325 interposed between the adjustment plate 310 and the fixing bracket 330 by bolts. The adjustment plate 310 and the bracket 330 are made of a buffer spring (H) for receiving the spring seat (325) and preventing the spring seat (h) from being released. The vertical vibration preventing member according to this embodiment is extremely simple in structure, and is economical and durable.

The lightweight insulation stone panel structure for a building exterior material improved in dustproof property according to the present invention and integrally bonded with a heat insulation material is characterized in that the installation of the stone panel and the heat insulation material as the decorative exterior material having the dust- So that it is possible to reduce the ease of operation, the shortening of the length of air and the construction cost when the decorative outer cover material is applied to the building wall.

Although the lightweight insulation panel of the present invention has been described with reference to the drawings, it is to be understood that the invention is not limited to the embodiments and the drawings disclosed herein, Various modifications may be made by those skilled in the art within the scope of the technical idea.

100: Stone panel 200: Polyurethane insulation layer
300: Fixed hardware 400: Wall
500: fixed cap

Claims (6)

A lightweight insulation stone panel structure for a building exterior member integrally bonded to a heat insulating material,
Wherein the adjusting plate engaging groove is horizontally formed at the upper and lower ends and is engaged with the upper or lower panel by an adjusting plate, the joining portion of the panel is silicon-filled in the outside, The inside of the locking groove is made of epoxy-filled stone panel for building exterior material;
A rigid polyurethane insulation material layer adhered to a back surface of the stone panel;
A film-like aluminum back sheet layer adhered to the back surface of the rigid polyurethane heat insulating material layer;
A "T" -shaped adjustment plate coupled to upper and lower ditch grooves of the stone panel, and having a slope such that the thickness becomes thicker toward the end;
An "L" -shaped fixing bracket fixed to the outer wall of the building or the supporting steel through an anchor bolt;
A slope is formed so as to be thicker toward the end portion, and the outer side is elastically contacted with the stone panel when fastened, and the inner side is engaged with the fixed metal piece A fixed cap which forms a simultaneous engagement structure of the inner side and the outer side;
A first shock absorbing member disposed between the anchor bolt and the fixing bracket and interposed by a bolt connection and having an elastic layer adhered to the inner and outer metal plate layers; a second shock absorbing member interposed between the first shock absorbing member and the first shock absorbing member A horizontal vibration preventing member composed of at least one second shock absorbing member made of a ring-shaped elastic material and a third shock absorbing member made of a shock absorbing spring interposed between the second shock absorbing members by bolt connection; And
A first shock absorbing member disposed between the adjustment plate and the fixing bracket and interposed by bolt engagement and having an elastic layer adhered to the inner and outer metal plate layers; a second shock absorbing member interposed between the first shock absorbing member and the first shock absorbing member And a vertical vibration preventing member composed of at least one second shock absorbing member made of a ring-shaped elastic material and a third shock absorbing member made of a shock absorbing spring interposed between the second shock absorbing members by bolt connection Lightweight insulation stone panel structure for vibration isolation. The method according to claim 1,
Wherein the first shock absorbing member comprises a first metal layer interposed by bolting, an elastic layer adhered to both ends of the first metal layer, and a second metal layer adhered to the elastic layer. . The method according to claim 1,
Wherein the horizontal vibration-damping member is disposed symmetrically on two front and rear sides of the fixing bracket. The method according to claim 1,
Wherein the vertical vibration damping member comprises a cushion spring interposed between the adjusting plate and the fixing bracket by a bolt coupling and a cushion spring protection cap slidably disposed on the outer side of the cushion spring, Wherein the insulation panel is a construction bolt made of nylon. 5. The method of claim 4,
Wherein the adjusting plate and the bracket are formed with a releasing preventing space for accommodating the buffer spring protecting cap to prevent the buffering spring from being detached. The method according to claim 1,
Wherein the vertical vibration preventing member comprises a buffer spring interposed between the adjusting plate and the fixing bracket by bolts, and the adjusting plate and the bracket are formed with spring seating grooves for receiving the buffer springs and preventing the buffer springs from being separated. Lightweight insulation stone panel structure.

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