TWI665361B - Building structure with cellular glass - Google Patents

Abstract

The invention is an architectural structure having a twinned crystal fiber board, comprising at least: a base plate, which may be a steel plate; or a calcium silicate plate, wherein the base plate is provided with a groove portion, which is set for the twinned mineral fiber plate, and Each side wall of the groove portion is respectively provided with a symmetrical joint portion or a joint groove; the side wall is provided with an inner and outer extension surface to match the shape of the crystallized mineral fiber plate; and then the groove portion is used as a sealing member The opening is closed to completely fix the crystallized mineral fiber board; the Cellular Glass, commonly known as glass foam or foamed glass, is set up and down on the side of the aforementioned crystallized mineral fiber board. And an extending surface, wherein the upper extending surface is disposed to match an outer extending surface of the base plate, and the lower extending surface is disposed to match an inner extending surface of the base plate.

Description

Building structure with twinned mineral fiber board

The invention relates to a building structure with a twinned crystal fiber board, which is applied to a roof board structure, a partition board structure, a wall board structure and a light steel frame ceiling structure. In buildings such as solar energy structures, the building structure is provided with fire and flame resistance.

According to the currently marketed composite steel plate, such as Taiwan's new patent No. M261538 "composite honeycomb aluminum plate", it is a honeycomb aluminum plate made of aluminum extrusion type. The honeycomb aluminum plate has high thermal conductivity because it is made of metal material. The problem of high cost can only be used for indoor installation as a sound insulation, heat insulation and shock absorption. If the stone block is to be combined with the honeycomb aluminum plate, it must be glued with the glue material, which is not suitable for the outer wall or roof structure.

Secondly, for example, Taiwan's new bulletin No. 458052 "Composite steel plate structure" or Taiwan's new patent No. M281995 "insulation wall panel" mainly consists of a plate body, a heat insulating sheet and a foamed cotton body. The bottom of the plate body; the foamed cotton body is filled between the plate body and the heat insulating sheet. The conventional person uses the foamed cotton body as the heat and sound insulation, but ignores the foamed cotton body such as the PU foam material as a kind of flammable substance, and in the event of a fire, toxic smoke and gas are generated. It will cause significant harm to people or things in the building. Moreover, if the foamed cotton body is heated, there will be a problem of secondary foaming. If the conventional person is used as an external wall or a roof, it is affected by the high temperature of the sun, and the foamed cotton body is foamed again. The surface of the partition wall is not even, which destroys the surface beauty.

Another example is Taiwan's new bulletin No. 467244, "Improvement of the combination of double-layer steel plates", which is mainly composed of outer steel plates, inner steel plates and foaming agents. The disadvantage is the use of foamed cotton as insulation and sound insulation. In the event of a fire, toxic fumes and gases will be produced, which will cause significant harm to people or objects in the building, and the foaming agent will have secondary foaming problems.

Another example is Taiwan's new patent No. M384892, "Fireproof steel plate structure", which is mainly composed of upper plate, lower plate, rock wool layer and foam layer. It is provided with a space between the upper plate and the lower plate to form a rock wool layer. The first clearance space and the second clearance space are formed on both sides, and the first and second clearance spaces are filled with the foam layer. The disadvantage is that the foamed cotton layer is used for caulking. If a fire occurs, toxic fumes and gases will be generated, which will cause serious harm to people or objects in the building. Moreover, the rock wool layer cannot be flattened, so that the bonding surfaces of the upper and lower plates are not evenly distributed.

To this end, the inventor, in the application of composite steel plate and building materials design and manufacturing experience, and for the fire and flame resistance of metal building materials, the use of twinned mineral fiber plate to replace the traditional foaming agent, rock wool, phenolic acid with strong acid value Resin, invented the case.

The object of the present invention is to provide a powdered material by using recycled glass, and appropriately adding a bonding material to prepare a fireproof, flame-resistant, crystallized mineral fiber board, and to crystallize the mineral fiber board and the base layer board. Combining to form a composite board having a twinned mineral fiber board, and then applying the composite board to various building structures, such as roofing sheets; or partition boards; or wall boards; or light steel frame ceilings to enhance green building materials Safety and environmental protection requirements.

The building structure with the twinned crystal fiber board of the invention comprises at least a concrete structure layer, a steel frame and a composite composite plate; the steel frame is arranged above the concrete structure layer, and the concrete structure layer and the steel are arranged by bolting elements The plurality of composite panels are disposed above the steel frame, and the composite plate is formed by stacking the base plate and the twinned crystal fiber plate, and is disposed on the side of the composite plate. The structure is such that the composite plates adjacent to the complex array can be combined into a flat shape in the horizontal direction through the corresponding combined structure; the composite plate is bolted down from the composite plate to the steel frame by the bolting component, and combined with the steel frame In one.

The building structure with the twinned crystal fiber board of the invention comprises at least a steel beam, a first steel plate and a composite composite plate; the first steel plate is arranged above the steel beam, and the steel beam is connected by a bolting component The first layer of steel plate is bolted into one body; the plurality of composite array plates are disposed above the first layer of the steel plate, and the composite plate is formed by stacking the base plate and the twinned crystal fiber plate on each other, and is formed on the composite plate. The side is provided with a combined structure, so that the composite plates adjacent to the complex array can be combined into a flat shape in the horizontal direction through the corresponding combined structure; the first layer of the steel plate and the composite plate are bolted by the bolting elements, the foregoing The bolting element is bolted from the composite plate to the first steel plate, and the steel beam, the first steel plate and the composite plate are integrated into one body.

The building structure with the twinned crystal fiber board of the invention comprises at least a steel beam, a steel frame and a composite composite plate; the steel frame is arranged above the steel beam, and the steel beam and the steel frame are integrated into one; The composite plate is disposed above the steel frame, and the composite plate is formed by stacking the base plate and the twinned mineral fiber plate, and a combined structure is arranged on the side of the composite plate to make the complex array adjacent to each other. The composite plates can be combined with each other in a horizontal direction through a corresponding bonding structure to form a flat shape; a recessed groove is disposed above the twinned crystal fiber plate of the composite plate, and a solar panel is disposed in the recessed groove, and the solar panel is A control element and a connecting element are provided, the control element being disposed below the composite panel, and the connecting component is for connecting the control elements of adjacent solar panels.

In this way, in order to enable the inspector to fully understand the present invention, the following is illustrated by the following figures: as shown in FIGS. 1-6, the embodiment (1) of the present invention includes:

The base plate 1 is made of a steel plate, and the base plate 1 is provided with a groove portion 10. The depth of the groove portion 10 is different depending on the thickness of the twinned crystal fiber plate, and the side walls 11 of the groove portion 10 are respectively provided with symmetry. In the joint portion 110, the opposite side of the joint portion is a joint groove 111 (see FIGS. 5 and 6), the groove portion 10 is provided with an open surface 12, and the corresponding side wall 11 of the open surface 12 is provided with an engagement protrusion. The edge 13 (see FIGS. 1 and 3); the side wall 11 is provided with an inner extension surface 14 or an outer extension surface 15, the inner extension surface 14 extends inwardly to a portion of the groove portion 10, and the outer extension surface 15 is Extending to the outer side of the side wall 11 to match the shape of the twinned mineral fiber board 2, and being provided for the twinned mineral fiber board 2; the inner inner surface 14 is provided with a groove 140 for the installation of the adjacent composite board combination.

The base plate 1 is provided with a sealing member 16, and the sealing member 16 is matched with the thickness of the lower surface of the twinned crystal fiber plate, and the groove portion 160 is formed, and the joint portion 162 or the coupling groove 163 is provided on the side wall 161, and The upper surface 164 and the lower surface 165 are disposed, and the upper surface 164 is provided with a recess 166 for facilitating the installation and assembly of the adjacent composite plates. The side wall 167 of the closing member 16 is provided with an engaging hole 168 and is slightly curved with the side wall 167. The elastic end 169 is folded (see Figures 1 and 3). Thus, after the base plate 1 is combined with the twinned crystal fiber plate 2, the sealing member 16 can be combined with the open surface 12 of the base plate 1 and quickly passed through the elastic end 169 of the side wall 167 of the closure member 16 The open surface 12 of the base plate 1 corresponds to the engaging flange 13 of the side wall 11, and the engaging flange 13 is inserted into the engaging hole 168 (see FIGS. 2 and 3), and the base plate 1 and the closed layer can be closed. The pieces 16 are integrated into one (Fig. 4-6).

Cellular Glass, commonly known as glass foam or foamed glass, is provided with an upper extension surface 20 and a lower extension surface 21 on the side of the twinned crystal fiber board 2, and the upper extension surface 20 is The upper extension surface 20 of the side of the twinned crystal fiber board 2 is disposed above the outer extension surface 15 of the base layer board 1 in combination with the outer surface 15 of the base layer board 1; The lower extending surface 21 of the fiberboard 2 is disposed in cooperation with the inner extending surface 14 of the base plate 1, so that the lower extending surface 21 is extended in the inner extending surface 14 of the base plate 1; The lower extending surface 21 of the plate 2 is provided with a recess 22 for respectively forming a recess 140 (such as FIG. 5) of the inner extending surface 14 of the base layer 1 and a recess 166 of the closing member 16, so that the base layer can be The plate 1, the closure member 16 and the twinned mineral fiber plate 2 are combined into a composite plate c (Fig. 4-6). The composite plate is combined with the groove 140 provided in the inner extending surface 14 of the base plate 1 by using the groove 22 provided on the lower extending surface 21 of the twinned crystal fiber board 2, and the twin crystallized mineral fiber board 2, the other recess 22 provided on the lower extending surface 21 is combined with the recess 166 of the closing member 16 (as shown in Fig. 2-7), of course, the coupling recess (Fig. 8) can be omitted on the composite panel. Match the actual use needs.

Next, in the embodiments (2) and (3) of FIG. 7-9, a coating layer 3 is formed by coating the above-mentioned twinned crystal fiber board 2 with a coating material, and the coating layer 3 is made of a waterproof coating and heat resistant. Various coatings such as paints and fireproof coatings are used. As for the edge of the crystallized mineral fiber board 2, it is impossible to have an acute angle, an obtuse angle or an arc angle.

5, 6 and 9, when the composite panels c adjacent to each other are to be combined with each other, the joint portion 110 of the side wall 11 of the base layer 1 of the first composite panel c1 and the corresponding adjacent second composite panel c2 are The bonding grooves 111 of the side wall 11 of the base plate 1 are combined with each other (as shown in Figs. 5, 6, 9, 10-13), so that adjacent composite plates can be tightly integrated into one body.

Further, as shown in Figs. 10-13, the application examples (1) to (3) of the foregoing embodiments (1) to (3) are shown. 10(11), the steel frame b is disposed above the concrete structural layer a, and the concrete structural layer a and the steel frame b are bolted together by the bolting component a0; the steel frame b A composite plate c is disposed on the upper side, and the steel frame b and the composite plate c are interposed between the steel plate b and the composite plate b, and the plugging element b0 is crystallized from the groove 140 of the base plate 1 of the composite plate. The groove 22 of the lower extending surface 21 of the mineral fiber board 2, or the groove 166 of the self-closing member 16 and the groove 22 of the lower extending surface 21 of the twinned crystal fiber board 2 are integrally integrated, and the steel can be The frame b and the composite plate c are fastened.

As shown in the application example (2) of Fig. 12, the steel beam d is provided, and the first steel plate e is disposed above the steel beam d, and the steel beam d is bolted to the first steel plate e by the bolting member d0; a composite plate c is disposed above the first steel plate e, and the first steel plate e and the composite plate c are bolted between the first and second composite plates e, and the plugging member b0 is connected to the base plate 1 of the composite plate. The groove 140 is recessed with the groove 22 of the lower extending surface 21 of the twinned crystal fiber board 2, or the groove 166 of the self-closing member 16 and the groove 22 of the lower extending surface 21 of the twinned crystal fiber board 2 In one piece, the aforementioned steel frame b and the composite plate c can be fastened.

As shown in the application example (3) of Fig. 13, a steel beam d is provided, and a first steel plate e is disposed above the steel beam d, and is bolted and fixed, and a steel frame b is placed above the first steel plate e, and is bolted. The component e1 is integrally formed with the first steel plate e and the steel frame b; a composite plate c is disposed above the steel frame b, and the steel frame b and the composite plate c are bolted by the bolting element b0, and the The element b0 is bolted from the groove 140 of the base plate 1 of the composite plate and the groove 22 of the bottom surface 21 of the twinned crystal fiber plate 2, or the groove 166 of the self-sealing member 16 and the crystallized mineral fiber The groove 22 of the lower extending surface 21 of the plate 2 is bolted into one body, and the steel frame b and the composite plate c can be fastened.

14 and 15 are embodiments (4) of the present invention, comprising: a base plate 1 composed of a steel plate, the base plate 1 is provided with a groove portion 10, and the depth of the groove portion 10 is matched with a crystallized mineral fiber plate. The groove portion 10 is provided with an open surface 12, and the corresponding side wall 11 of the open surface 12 is provided with an engaging flange 13 (refer to FIGS. 1 and 3); the side wall 11 is provided with an inner extending surface 14 or an outer extension surface 15, the inner extension surface 14 extends inwardly to a portion of the groove portion 10, and the outer extension surface 15 extends to the outer side of the side wall 11 to cooperate with the twinned crystal fiber board 2 The inner extending surface 14 is further provided with an upright surface 141. The vertical surface 141 is provided with a coupling groove 142, or no coupling groove is provided (as in the fifth embodiment of FIG. 16); the outer extending surface 15 is further provided with an upright surface 151. The foregoing façade 151 is provided with a joint portion 152, or no joint portion (such as the fifth embodiment of FIG. 16); the base plate 1 is provided with a closing member 16, and the seal member 16 is extended under the twinned crystal fiber plate. The thickness of the surface, the structure of the aforementioned sealing member, and the combined structure with the base material are all implemented as described above The examples are the same and will not be described here.

Cellular Glass, commonly known as glass foam or foamed glass, is provided with an upper extension surface 20 and a lower extension surface 21 on the side of the twinned crystal fiber board 2, and the upper extension surface 20 is In combination with the outer surface 15 of the base plate 1 , an upper extending surface 20 is disposed on the side of the twinned crystal fiber board 2 to be disposed above the outer surface 15 of the base layer 1; the twin crystallized mineral fiber The lower extending surface 21 of the plate 2 is disposed in cooperation with the inner extending surface 14 of the base plate 1, so that the lower extending surface 21 is extended in the inner extending surface 14 of the base plate 1, so that the base plate 1 can be The sealing member 16 and the twinned crystal fiber board 2 are combined to form a composite board.

Further, as shown in Figs. 17-22, the application examples (1) to (6) of the foregoing embodiment (4) are shown. The working examples (1) and (2) of FIGS. 17 and 18 are provided with a steel frame b above the concrete structural layer a, and the concrete structural layer a and the steel frame b are bolted together by the bolting component a0; A composite plate c is disposed above the steel frame b, and the steel frame b and the composite plate c are bolted by the bolting member b0, and the hole b1 left over the bolting member b0 is further filled with a caulking material. When the b2 is closed, the steel frame b and the composite plate c can be fastened. The coating layer can be formed by coating with the coating 3 on top of the composite sheet c of the application example (II) of Fig. 18.

As shown in the application example (3) of FIG. 19, a steel frame b is disposed above the steel beam d, and the steel beam d and the steel frame b are bolted together; a composite plate c is disposed above the steel frame b, and the steel frame is b and the composite plate c are bolted by the bolting element b0, and the bore b1 left above the bolting element b0 is closed by the caulking material b2, the steel frame b and the composite board can be c tied to it. And the solar panel 4 is disposed in the recessed portion of the composite panel c; or the solar panel 4 is disposed on the surface of the composite panel c shown in the application example (4) of FIG. 20, and the control component 5 is disposed under the composite panel. The battery of the electrical storage device, etc., can be provided with the solar panel 4 by the composite panel to provide green energy. Or, as in the application examples (5) and (6) of Figs. 21 and 22, the connecting member 6 is provided on the composite board c, so that the control elements of the adjacent solar panels are connected to each other to provide better green energy efficiency.

23 and 24 are embodiments (6) of the present invention, comprising: a base plate 1 formed by integrally forming a steel plate, wherein the base plate 1 is provided with a groove portion 10, and the depth of the groove portion 10 is matched with twinning. The thickness of the slab is different. The side wall 11 of the groove portion 10 is provided with a symmetrical joint portion 110, and the opposite side of the joint portion is the joint groove 111 (as shown in FIGS. 24 and 25), or there is no combination. The portion and the coupling groove may also be (FIG. 26); the side wall 11 is provided with an inner extension surface 14 or an outer extension surface 15, and the inner extension surface 14 extends inwardly to a portion of the groove portion 10, and the outer extension surface 15 It is extended to the outer side of the side wall 11 to match the shape of the twinned mineral fiber board 2, and is provided for the twinned mineral fiber board 2; the inner extension surface 14 is provided with a groove 140 to utilize the adjacent composite board Install the combination.

Cellular Glass, commonly known as glass foam or foamed glass, is composed of a plurality of twin crystallized mineral fiber sheets 2, as shown in Figure 24, consisting of three blocks, as shown in Figure 25. And (8) and (8) are composed of two blocks, and an upper extension surface 20 and a lower extension surface 21 are provided on the side of the twin crystallized mineral fiber sheet 2, and the upper extension surface 20 is matched with the foregoing The outer surface 15 of the base plate 1 is disposed such that the side of the twinned crystal fiber board 2 is provided with an upper surface 20 which is disposed above the outer surface 15 of the base layer 1; the crystallized mineral fiber board 2 The lower extension surface 21 is disposed in cooperation with the inner extension surface 14 of the base layer panel 1 so that the lower extension surface 21 can be extended in the inner extension surface 14 of the base layer panel 1 so that the base layer panel 1 can be closed. The piece 16 and the twinned crystal fiber board 2 are combined to form a composite board.

27, 28 and 29, respectively, are examples (9) and (10) of the present invention. The embodiment (9) of FIGS. 27 and 28 includes: a base plate 1a composed of a calcium silicate plate, and the base plate 1a is disposed above the twinned crystal fiber plate 2a, and the base plate 1a and the strontium ore are The upper and lower layers of the fiberboard 2a are arranged to offset the angle of the twinned crystal fiber board 2a from the base layer 1a, so that the adjacent two composite boards can be combined with each other by a symmetrical structure to form a flat surface. The composite plates of the left and right sides are connected to each other. Therefore, the first convex portion 1a0 and the second convex portion 2a0 are formed on both sides of the composite plate corresponding to the first convex portion 1a0 of the composite plate and formed with The first recessed portion 1a1, corresponding to the lower portion of the second convex portion 2a0 of the composite panel and forming the second recessed portion 2a1, can constitute the composite panel of the present invention.

The embodiment (10) of FIG. 29 includes: the base plates 1a and 1b, which are composed of a calcium silicate plate, and the base plates 1a and 1b are disposed between the twinned crystal fibers 2a, and the base plates 1a and 1b are provided. The combination with the twin crystallized mineral fiber sheet 2a is such that the aforementioned twinned crystal fiber board 2a is offset from the corner of the base layer 1a, 1b (see Fig. 27), so as to facilitate the adjacent two composite The plates may be combined into a flat shape by a symmetrical structure, and the composite plates adjacent to each other may be combined with each other, and the second convex portion 2a0 and the first concave portion 1a1 are formed to form the composite plate of the present invention. .

In summary, Chen said that the composite board of the present invention has the functions of fireproof, flameproof and recyclable. The inventor entrusted Taiwan Inspection Technology Co., Ltd. (SGS) to carry out "sandwich glass foaming" on February 23, 100. "Fireproofing and fireproofing test of the board", and on March 17th and April 1st, 100, the "Sandwich Glass Mineral Fiber Board 3H" and "Sandwich Glass Mineral Fiber Board 5H" were commissioned to carry out fire prevention. The flame-resistance test is in line with national safety standards. It is obvious that the present invention does have the commercial success and value of improving the safety of metal buildings and meeting the environmental green requirements.

1‧‧‧basic board

10‧‧‧Slots

11‧‧‧ Side wall

110‧‧‧Combination Department

111‧‧‧ joint slot

12‧‧‧Open noodles

13‧‧‧Snap flange

14‧‧‧Inside extension

140‧‧‧ Groove

141‧‧‧Upright

142‧‧‧ joint slot

15‧‧‧Outer extension

151‧‧‧Upright

152‧‧‧Combination Department

16‧‧‧Closed

160‧‧‧Slots

161‧‧‧ side wall

162‧‧‧Combination

163‧‧‧ joint slot

164‧‧‧ upper surface

165‧‧‧ lower surface

166‧‧‧ Groove

167‧‧‧ side wall

168‧‧‧ snap hole

169‧‧‧Flexible end

2‧‧‧矽晶化矿纤板

20‧‧‧Upper extension

21‧‧‧Under extension

22‧‧‧ Groove

3‧‧‧ paint layer

c‧‧‧Composite board

C1‧‧‧ first composite board

C2‧‧‧second composite board

a‧‧‧Concrete structural layer

B‧‧‧ steel frame

A0‧‧‧Equipment components

B0‧‧‧Equipment components

d‧‧‧Steel beam

e‧‧‧First steel plate

D0‧‧‧Equipment components

E0‧‧‧Equipment components

E1‧‧‧Equipment components

4‧‧‧ solar panels

5‧‧‧Control elements

6‧‧‧Connecting components

1a, 1b‧‧‧ basic board

2a‧‧‧矽晶晶矿板

1a0‧‧‧first convex

2a0‧‧‧second convex

1a1‧‧‧ first recess

2a1‧‧‧second recess

1 is an exploded view of an embodiment (1) of the present invention. 2 is a combination diagram of an embodiment (1) of the present invention. Figure 3 is a partial cross-sectional view showing the first embodiment of the present invention. Fig. 4 is a plan view showing an embodiment (1) of the present invention. Figure 5 is a cross-sectional view taken along line A-A of Figure 4; Figure 6 is a cross-sectional view taken along line B-B of Figure 4; Figure 7 is a combination diagram of an embodiment (2) of the present invention. Figure 8 is a combination diagram of an embodiment (3) of the present invention. Figure 9 is an assembly diagram of an embodiment (3) of the present invention. Fig. 10 is a cross-sectional view showing an operation example (1) of the first embodiment (a) to (c) of the present invention. Figure 11 is a cross-sectional view showing an operation example (1) of the embodiments (1) to (3) of the present invention. Figure 12 is a cross-sectional view showing an operation example (2) of the embodiments (1) to (3) of the present invention. Figure 13 is a cross-sectional view showing an operation example (3) of the embodiments (1) to (3) of the present invention. Figure 14 is a combination diagram of an embodiment (4) of the present invention. Figure 15 is a cross-sectional view taken along line A-A of Figure 14; Figure 16 is a cross-sectional view showing the fifth embodiment of the present invention. Figure 17 is a cross-sectional view showing an operation example (1) of the embodiment (4) of the present invention. Figure 18 is a cross-sectional view showing an operation example (2) of the embodiment (4) of the present invention. Figure 19 is a cross-sectional view showing an operation example (3) of the fourth embodiment of the present invention. Figure 20 is a cross-sectional view showing an operation example (4) of the fourth embodiment of the present invention. Figure 21 is a cross-sectional view showing an operation example (5) of the embodiment (4) of the present invention. Figure 22 is a cross-sectional view showing an operation example (6) of the embodiment (4) of the present invention. Figure 23 is an exploded view of the sixth embodiment of the present invention. Figure 24 is a cross-sectional view showing the sixth embodiment of the present invention. Figure 25 is a cross-sectional view showing the seventh embodiment of the present invention. Figure 26 is a cross-sectional view showing an eighth embodiment of the present invention. Figure 27 is a combination diagram of an embodiment (9) of the present invention. Figure 28 is a cross-sectional view showing the nineth embodiment of the present invention. Figure 29 is a cross-sectional view showing a tenth embodiment of the present invention.

Claims (13)

An architectural structure having a twinned crystal fiber board, comprising at least: a concrete structural layer; a steel frame disposed above the concrete structural layer, and the concrete structural layer and the steel frame are bolted together by a bolting component; The plate is disposed above the steel frame, and the composite plate is formed by stacking a base plate and a twinned crystal fiber plate, and a combined structure is arranged on a side of the composite plate to make a composite of adjacent arrays The plates can be combined with each other in a horizontal direction through a corresponding joint structure to form a flat shape; the composite plate is bolted down from the composite plate to the steel frame by a bolting member, and integrated with the steel frame. An architectural structure having a twinned crystal fiber board, comprising at least: a steel beam; a first layer of steel plate disposed above the steel beam and bolting the steel beam to the first layer of steel plate by a bolting component; The composite plate is disposed on the first layer of the steel plate, and the composite plate is formed by stacking the base plate and the twinned crystal fiber plate, and a combined structure is arranged on the side of the composite plate to make the composite array The adjacent composite plates can be combined into a flat shape in the horizontal direction through the corresponding combined structure; the first layer of the steel plate and the composite plate are bolted with a bolting member, and the bolting member is tied downward from the composite plate. The steel beam, the first steel plate and the composite plate can be integrated into the first steel plate. According to the second aspect of the patent application, the building structure having the twinned crystal fiber board, wherein the first layer of the steel plate and the composite plate are provided with a steel frame, and the first layer of the steel plate and the steel are provided by the bolting component. The bolts are combined, and the bolting elements are bolted down from the composite board to the first layer of the steel plate, and the steel beam, the first steel plate, the steel frame and the composite plate are integrated into one body. An architectural structure having a twinned crystal fiber board, comprising at least: a steel beam; a steel frame disposed above the steel beam and combining the steel beam and the steel frame; the composite array composite plate is disposed on the steel frame Above, the composite board is formed by stacking a base layer board and a twinned crystal fiber board, and a joint structure is arranged on a side of the composite board, so that the composite board adjacent to the complex array can pass through the corresponding joint structure. The horizontal direction is combined with each other to form a flat shape; a recessed groove is disposed above the twinned crystal fiber board of the composite plate, and a solar panel is disposed in the recessed groove, and the solar panel is provided with a control element and a connecting element, The control element is disposed below the composite panel and the connecting component is used to connect the control elements of adjacent solar panels. The building structure having a crystallized mineral fiber board according to any one of claims 1 to 4, wherein the base layer plate is provided with a groove portion, which is provided by a twinned crystal fiber board, and each of the groove portions The side walls are respectively provided with a symmetrical joint portion or a joint groove; the side wall is provided with an inner extension surface and an outer extension surface to match the shape of the twinned crystal fiber board; and the open surface of the groove portion is closed by a closing member, thereby The crystallized mineral fiber plate is completely fixed, the sealing member is provided with a groove portion, and a joint portion or a joint groove is provided on the side wall, and the upper surface and the lower surface are provided; and the corresponding side of the open surface of the groove portion of the base layer plate is provided The wall is provided with a flange; the twinned crystal fiber board is provided with upper and lower extension surfaces on the side, the upper extension surface is provided with the outer extension surface of the base layer, and the lower extension surface is matched with the base layer The inner extending surface is disposed on the side wall of the sealing member, and the side wall is provided with an engaging hole for engaging the engaging flange of the base plate by the engaging hole of the closing member; thus, the base layer plate is lysed by the foregoing The mineral fiber board is set up to form a fireproof and flame resistant composite board. According to the fifth aspect of the patent application, the composite plate having the twinned crystal fiber board, wherein the side wall of the closing member is provided with a slightly bent elastic end, so that the engaging hole of the closing member is the engaging protrusion of the base plate Edge combination. A composite board having a twinned crystal fiber board according to claim 5, wherein the upper surface of the closing member is provided with a groove. According to the fifth aspect of the invention, the composite plate having the twinned crystal fiber board, wherein the side wall of the groove portion of the base plate is respectively provided with a symmetrical joint portion, and the opposite side of the joint portion is a joint groove; The inner extending surface of the side wall of the base plate extends inwardly to the upper portion of the groove portion; the outer extending surface of the side wall extends to the outer side of the side wall; and the extending surface of the twin crystallized mineral fiber plate is provided The groove, and the corresponding extending groove of the inner layer plate and the sealing member are disposed, so that the base plate, the sealing member and the twinned mineral fiber plate can be combined with each other. The building structure having a crystallized mineral fiber board according to any one of claims 1 to 4, wherein the base layer plate is provided with a groove portion, which is provided by a twinned crystal fiber board, and each of the groove portions The side wall is respectively provided with a symmetrical joint portion or a joint groove; the side wall is provided with an inner extension surface and an outer extension surface to match the shape of the twinned crystal fiber board; the above-mentioned twin crystallized mineral fiber board is arranged on the side and the upper side. The upper extension surface is provided to cooperate with the outer extension surface of the base layer, and the lower extension surface is provided with the inner extension surface of the base layer; thus, the base layer is provided for the twinned crystal fiber board , constitute a composite board of fireproof and flame resistant. According to the ninth aspect of the patent application, the composite plate having the twinned crystal fiber plate, wherein the side wall of the groove portion of the base plate is respectively provided with a symmetrical joint portion, and the opposite side of the joint portion is a joint groove; The inner extending surface of the side wall of the base plate extends inwardly to the upper portion of the groove portion; the outer extending surface of the side wall extends to the outer side of the side wall; and the extending surface of the twin crystallized mineral fiber plate is provided The groove is provided with a corresponding groove on the inner extending surface of the base plate, so that the base plate and the twinned mineral fiber plate can be combined with each other. The architectural structure having a twinned crystal fiber board according to any one of claims 1 to 4, wherein the upper surface of the crystallized mineral fiber board is coated with a coating to form a coating layer, and the coating layer is obtained. For waterproof coatings, heat resistant coatings or fire retardant coatings. The architectural structure having a crystallized mineral fiber board according to any one of claims 1 to 4, wherein the base layer board is a calcium silicate board; and the foregoing crystallized mineral fiber board is disposed on the base board. Above, the above-mentioned base plate and the twinned crystal fiber plate are superposed on top of each other, which is to offset the corner of the base crystal plate from the base plate, so as to facilitate the adjacent composite plate by construction. The symmetrical structures are combined with each other to form a flat shape, and after the base layer and the twinned crystal fiber are stacked on the upper and lower sides, a first convex portion and a second convex portion are formed on both sides of the composite plate, corresponding to the first A first recess is formed above the convex portion, corresponding to the lower portion of the second convex portion and forming a second recess. The architectural structure having a crystallized mineral fiber board according to any one of claims 1 to 3, wherein the base layer is a two-layer calcium silicate board, and the twin crystallized mineral fiber board is disposed in the Between the two layers of calcium silicate plates, the combination of the above two layers of calcium silicate plate and the bismuth crystallized mineral fiber plate is obtained by shifting the aforementioned crystallized mineral fiber plate from the corner of the two-layer calcium silicate plate; When the two-layer calcium silicate plate is combined with the strontized mineral fiber plate, the second convex portion and the first concave portion may be respectively formed on both sides of the composite plate, so that when the adjacent two composite plates are to be combined with each other, The second convex portion of one composite plate may be combined with each other to form a flat shape corresponding to the second concave portion of the other composite plate.