JP2006183453A - Prism glass panel and its construction method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a prism glass panel and its construction method, capable of coping with an installation part of various dimensions and shapes, capable of reducing weight, without requiring labor for construction, without causing water leakage, and suitable for a general house. <P>SOLUTION: This prism glass panel 10 is composed of a plurality of prism glass 11, a grating frame 13 for supporting the prism glass 11, a gasket 12 also serving as a spacer arranged between the grating frame 13 and the prism glass 11, and a joint part 14 between the mutual prism glass 11. The grating frame 13 has a plurality of frame bodies 13d for supporting the plurality of prism glass 11, and a base body 13a for supporting these frame bodies. The construction method comprises a process of fixing the grating frame 13 to a skeleton 16, a process of installing the gasket 12 also serving as the spacer provided with strip projection pieces 12c to 12f abutting on the frame bodies 13d on the prism glass 11, a process of fixing the prism glass 11 to the frame bodies 13d, and a process of fixing the frame bodies 13d to the base body 13a of the grating frame 13. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a prism glass panel used for building skylights, floors such as corridors, wall surfaces, and the like, and a method of constructing the same. The prism glass is a glass having a square or circular top surface, a side wall extending downward from the periphery of the top surface, and an annular bottom surface of the side wall, and the entire cross section is formed in a reverse concave shape. It is a block.

  When the light is taken using the prism glass, conventionally, as described in Patent Document 1, the top surface 1a having a square or circular plane shape as shown in FIG. A block-shaped prism glass 1 having a side wall 1b extending downward from the periphery and an annular bottom surface 1c of the side wall 1b and having an entire cross section formed in an inverted concave shape is used. Around the side wall 1b and the bottom surface 1c of the prism glass 1, the cross section is substantially L-shaped as shown in FIG. 7B, one side has a substantially square shape with a predetermined dimension, and has a predetermined thickness on the outer peripheral surface. Is fitted to the frame spacer 2 on which the strip protrusion pieces 2 a to 2 f are formed, and is installed in the lattice frame 3. At this time, the strip protrusions 2a, 2b, 2c and 2d of the frame spacer 2 are brought into contact with the lattice frame 3, and the strip protrusions 2e and 2f are applied to the periphery of the side wall 1b and the bottom surface 1c of the prism glass 1. Therefore, before the waterproof cosmetic mortar 4 is dried and solidified, kneading water in which the cement component in the waterproof cosmetic mortar 4 is partially dissolved or a waterproof layer agent having a low viscosity is formed between the prism glass 1 and the frame spacer 2. There is no leakage from between the frame-shaped spacer 2 and the lattice frame 3, and the floor of the building is not soiled. Further, even after the construction, even if the waterproof decorative mortar 4 or the waterproof layer 5 deteriorates and cracks, rainwater or the like is generated between the prism glass 1 and the frame spacer 2 or between the frame spacer 2 and the lattice frame 3. It does not enter and does not leak.

  The lattice frame 3 has a lattice shape that is substantially the outer dimension of the prism glass 1 in order to support the plurality of prism glasses 1, and the strip protrusions 2a, 2b, 2c, and 2d of the frame spacer 2 are in contact with each other. Thus, the cross section is L-shaped or inverted T-shaped. The lattice frame 3 is made of a metal such as cast iron having excellent mechanical strength and durability.

  The joint portion 6 has a two-layer structure in which a waterproof layer 5 is provided at the interface with the prism glass 1, the frame spacer 2, and the lattice frame 3, and a waterproof decorative mortar 4 is provided on the waterproof layer 5. The waterproof layer 5 is made of SBR (styrene butadiene rubber), and the waterproof decorative mortar 4 is made of cement and sand.

By placing the prism glass 1 with the frame spacer 2 on the edge 3a of the lattice frame 3 made of cast iron and forming the waterproof layer 5 and the waterproof decorative mortar 4 in this order on the joint portion 6, FIG. As shown in Fig. 4, after the prism glass panel 7 is manufactured, it is carried into the site, fixed to the housing 8, and then constructed. In addition, the prism glass panel 7 may be manufactured and applied in the same manner as described above after the lattice frame 3 is attached to the housing in the field.
JP 2002-21248 A

  However, the conventional prism glass panel 7 cannot be applied to the clean state with high accuracy unless it is a specialized technician. In addition, since the mortar 4 is used, not only the curing and curing period of the mortar 4 (at least one day) is required, but also the surface of the prism glass 1 may be soiled when finishing the joint portion 6, which requires troublesome cleaning. I need it. Further, the weight of the mortar 4 is heavy, and the strength of the material for fixing the casing 8 and the prism glass panel 7 to the casing 8 is required, and a material having a large cross-sectional area is used, resulting in an increase in cost. Further, when a dedicated cast iron frame is used for the lattice frame 3, there are various problems such that the panel dimensions cannot be designed freely.

  Therefore, the present invention is a prism glass panel that can be freely designed in panel dimensions, is light in weight, does not require time and labor for construction, does not leak, and is suitable for ordinary houses and a prism glass panel construction method. It is an issue to provide.

  The prism glass panel according to the present invention is a prism glass panel having a plurality of prism glasses, a lattice frame that supports the prism glasses, and a joint between the prism glasses, wherein the lattice frame includes a plurality of prism glasses. A plurality of frame bodies that support the frame body and a base body that supports the frame body, and the frame body supports the plurality of prism glasses aligned in one direction. It is more preferable that the frame body is one that aligns and supports a plurality of prism glasses to which a frame-like spacer-use gasket having a strip protrusion piece provided on the outer periphery is attached.

  The lattice frame used in the present invention has a plurality of frames that support a plurality of prism glasses and a base that supports the plurality of frames, according to the dimensions of the place where the prism glass panel is installed. The number and length of the frame bodies are set, and the base body corresponding to the number and length of the frame bodies is used. Any frame can be used as long as it has a size and shape capable of supporting a plurality of prism glasses in a state where water does not leak from the gaps. In addition, it is preferable that the frame body supports a plurality of prism glasses in one direction because the frame can be finely adapted to the size of the place where the prism glass panel is installed. Further, when the frame body supports and aligns a plurality of prism glasses to which a frame-like spacer / gasket having a strip protrusion piece provided on the outer periphery is provided, there are the following advantages.

  That is, the spacer combined gasket has a frame shape that comes into contact with the outer periphery of the prism glass, and when the strip projection piece that is fitted to the outer peripheral surface of each prism glass and contacts the frame body is provided, the spacer combined gasket is attached. By simply fitting the prism glass into the frame, installation can be completed easily and accurately, even if you are not a specialized technician. A larger number of strip protrusions is better, but from an economical viewpoint, it is preferable that the outer peripheral surface is 3 or more because a stable waterproof effect can be obtained. Further, even after the construction, even if the waterproof layer is deteriorated and cracked, rainwater or the like does not enter from between the prism glass and the spacer gasket or between the spacer gasket and the frame, so that water does not leak. That is, the spacer-use gasket spacer is fitted on the outer peripheral surface of each prism glass (may be further bonded), and the spacer-use gasket is provided with a strip projection piece that contacts the frame. Even if there are variations in the actual dimensions of the frame, there is no gap between the prism glass, the spacer-use gasket, and the frame, so that liquid does not enter the room. Furthermore, since the prism glass and the spacer gasket, or the spacer gasket and the lattice frame are in close contact with each other by the protrusions on the surface of the spacer gasket, the position of the prism glass is difficult to shift during construction. It is preferable that the strip protrusion piece of the spacer-use gasket is in contact with another prism glass because the sealing performance is further improved. Furthermore, when providing a frame body that supports a plurality of prism glasses on the lattice frame, the strip protrusion pieces that contact the frame body should be formed with a sufficiently long dimension relative to the members of the intervening frame body. Thus, it becomes possible to maintain the distance between the prism glasses with the spacer gaskets equal to the distance between the prism glasses via the frame member, and set the widths of the vertical and horizontal joint portions to the same dimensions. It becomes easy.

  As the base of the lattice frame used in the present invention, it is possible to support a plurality of frame bodies that support a plurality of prism glasses and to be installed on a casing, and to be used if it has mechanical strength and durability as a building. Is possible. For example, when the base body has a structure in which side frame portions corresponding to the length of the frame body are connected by a connecting member, when the number of frame bodies of the lattice frame is increased, the length corresponding to the number of frame bodies is increased. If a connecting member is prepared, the side frame part is connected by welding, bolting, etc. with a connecting member of an appropriate length according to the required number of rows of glass blocks, that is, the number of frames. Thus, the substrate can be manufactured in a short time. Moreover, you may change not only a number but the length of a frame. In that case, the connecting member and the side frame portion matched with the number of frames and the length are prepared. Since the size types of these members are determined by the combination of the size and number of glass blocks, they do not increase at all. When there are dimensional restrictions for general houses, there are actually several types.

  The prism glass panel of the present invention is characterized in that it is 110 kg or less per square meter, the average mass per square meter of the grid frame is preferably 60 kg or less, and the grid frame has a structure in which steel materials are welded. More preferably it is.

  If the weight per square meter of the prism glass panel exceeds 110 kg, many workers, heavy machinery, special transporters, etc. will be required during construction. If the weight is 110 kg or less, heavy machinery and special transporters will be required. It becomes easy to carry in to the site even without using. In order to reduce the weight of such a prism glass panel, when the average mass per square meter of the most heavy lattice frame is 60 kg or less, the prism glass panel can be more easily formed than the other members. Weight reduction can be realized. Therefore, by changing the lattice frame from a conventional cast iron structure to a steel material welded, it is possible to reduce the weight, improve the degree of freedom during construction, and reduce the cost while maintaining the required strength. Furthermore, if a frame for supporting a plurality of prism glasses is provided on the lattice frame, the prism glass panel can be reduced in weight by the amount of beam members being reduced. The longer the frame, the more prism glass can be supported. However, in order to ensure the required strength, the base beam members are placed below the frame at any interval, regardless of the size of the prism glass. It may be reinforced.

  In the prism glass panel of the present invention, the lattice frame has a dew-proof coating applied to the lower exposed surface, which suppresses condensation on the lower surface of the lattice frame, which causes rust and unwanted dripping. This is preferable.

  Furthermore, the prism glass panel of the present invention is characterized in that a transparent resin plate is attached below the prism glass, and when the space between the prism glass and the transparent resin plate is a sealed space, the prism glass panel is hermetically sealed. Since the space acts as a heat insulating layer like a greenhouse, the heat transmissibility is reduced and the occurrence of condensation is greatly suppressed, so it is suitable for indoor use.

  In the present invention, the transparent resin plate attached below the prism glass is preferably a transparent polycarbonate, acrylic, or other transparent material used as a building material. It is lightweight and does not scatter even if the prism glass is broken, making it suitable for indoor use.

In the present invention, the joint portion means one formed by filling a space excluding the lattice frame between the prism glasses. As what is filled in this joint, it can be used if it is lighter than conventional mortar and has a specific gravity as small as 1.6 or less and is excellent in weather resistance, and is a rubber material excellent in weather resistance, A resin material or other elastic material is preferable because the specific gravity of the entire joint portion can be easily adjusted to 1.0 or less, and the sealing property is excellent. In addition, since the specific gravity of 1.6 or less can also be expressed by density, and the density of water is about 1000 kg / m ³ , in this case, it is 1600 kg / m ³ or less. In addition, in order to reduce weight and improve waterproofness, it can also be used as a spacer because the apparent specific gravity is extremely reduced by 30% by volume or more of the joint part having a void forming function such as a hollow part or a protruding part that exhibits a waterproof effect. It is preferable that it is filled with a gasket because the weight can be further reduced. When the volume of the spacer combined gasket is 30% by volume or less of the joint part, another filler having a large specific gravity is used. Moreover, since it becomes necessary to use many other fillers, simplification of a construction process will be inhibited. When a curable filler is used, if the material of the outer surface of the joint is made of silicone (specific gravity: 0.9 to 1.0) that can be colored with a specific gravity of 1.6 or less, the color tone of the interior of a house or the like It is more preferable because it can be colored in conformity to the color and can secure waterproofness.

  The construction method of the prism glass panel according to the present invention is a construction method of constructing a prism glass panel having a plurality of prism glasses, a lattice frame supporting the prism glass, and a joint portion between the prism glasses on the housing, The lattice frame includes a plurality of frame bodies that support a plurality of prism glasses, and a base body that supports the frame bodies, the step of fixing the frame body to the base body of the lattice frame, and the base body of the lattice frame And a step of fixing the prism glass to the frame, and is provided with strip protrusions that come into contact with the frame supporting the plurality of prism glasses. It is preferable to have a step of attaching the spacer combined gasket to the prism glass and a step of fixing the prism glass to the frame body. More preferably comprising the step of attaching a plate, a step of fixing the substrate lattice frame the precursor is a substrate of the lattice frame, it is more preferable that the step of building frame and bolting through the mounting member.

  As a process of fixing the frame body to the base of the lattice frame, it is possible to use welding, detachable bolting, fitting, fitting and fasteners, or the like. The process of fixing the base of the lattice frame to the casing means the process of fixing only the base of the grid frame as a part of the prism glass panel, the base of the lattice frame fixing the frame and the base, and welding. , Detachable bolts, fittings, fittings and fasteners, etc. can be used. As a process of fixing the prism glass to the frame body, the prism glass is attached to the frame body through a thing that acts as a buffering material that does not apply a load that breaks the prism glass, or a thing that acts as a sealing material that prevents water leakage. It means to fix. In addition, as a process of attaching a spacer combined gasket, which is provided with strip protrusions that come into contact with the frame, to the prism glass, the elastic spacer combined gasket having a slightly smaller opening than the prism glass is expanded and fitted into the prism glass. It is possible to apply an adhesive on the outer periphery of the prism glass or the inner surface of the gasket serving as a spacer, and to bond them together. As a process of fixing the prism glass with the spacer combined gasket attached to the frame, the prism glass with the spacer combined gasket attached is fixed to the frame fixed to the lattice frame or the frame not fixed to the lattice frame. This means a process, and if the strip protrusions on the outer periphery of the spacer gasket are fitted into the frame body, they can be installed almost evenly.

  The process of attaching a transparent resin plate below the prism glass is to fit a transparent polycarbonate, acrylic, or other transparent resin plate of approximately the same dimensions as the bottom surface of the prism glass into the lattice frame, or transparent to the lower surface of the lattice frame. The resin plate can be fixed with screws, guide rails, or the like.

  As a step of bolting the base of the lattice frame to the housing via the mounting member, the base of the lattice frame as a part of the prism glass panel, the base of the lattice frame to which the frame is fixed, and only the base are fixed to the housing. It means a process, and the mounting member is attached to the frame for fixing the aligned prism glass by welding, detachable bolting, fitting, fitting and fasteners, etc., and this mounting member is bolted to the housing What is necessary is just to join.

  The prism glass panel according to the present invention is a prism glass panel having a plurality of prism glasses, a lattice frame that supports the prism glasses, and a joint between the prism glasses, wherein the lattice frame includes a plurality of prism glasses. Since there are a plurality of frame bodies that support the frame body and a base body that supports the frame body, various dimensions can be obtained by setting the length and number of the frame bodies according to the dimensions of the place where the prism glass panel is installed. A panel using existing prism glass can be easily produced for the opening having a shape. Further, if the frame body supports the plurality of prism glasses in one direction, it is possible to cope with the size of the place where the prism glass panel is installed. Furthermore, when the frame body is intended to align and support a plurality of prism glasses having frame-shaped spacer / gaskets provided with strip protrusions on the outer periphery, the prism glass with the spacer / gasket attached is latticed. Since the desired construction accuracy can be simplified simply by fitting the frame body, the construction time is shortened, and as a result, the construction cost can be reduced.

  In addition, since the prism glass panel of the present invention is 110 kg or less per square meter, it can be easily carried into the site without using heavy equipment or special transport equipment during construction, and comparison with general houses, etc. Even if the structure is weak, it can be carried in without problems. In addition, when the average mass per square meter of the lattice frame is 60 kg or less, it is possible to significantly reduce the weight as compared with a conventional cast iron frame or the like. Furthermore, if the lattice frame has a structure in which steel materials are welded, the panel dimensions can be freely designed, and it becomes possible to flexibly and inexpensively cope with various houses and buildings and various portions thereof.

  Further, in the prism glass panel of the present invention, the dew condensation on the lower surface of the lattice frame is suppressed if the lattice frame is coated with a dew-proof coating mainly composed of colloidal silica on the exposed surface below the lattice frame. It is possible to prevent rust and dripping dripping.

  Furthermore, the prism glass panel of the present invention has a spacer-like gasket in the shape of a frame that comes into contact with the outer periphery of the prism glass, and is provided with strip protrusions that come into contact with the frame of the lattice frame. Positioning and retaining of the prism glass can be realized by the compression effect of the fins on the side of the (rubber).

  In addition, the prism glass panel of the present invention is provided with a transparent resin plate below the prism glass, and is suitable for indoor use, so even if the prism glass is damaged, This makes it possible to prevent the fragments from falling and to ensure safety compared to the prior art. In addition, by providing a sealed space between the prism glass and the transparent resin plate and providing a heat insulating layer with air, the heat transmissivity is reduced and the occurrence of condensation can be significantly suppressed.

  The construction method of the prism glass panel according to the present invention is a construction method of constructing a prism glass panel having a plurality of prism glasses, a lattice frame supporting the prism glass, and a joint portion between the prism glasses on the housing, The lattice frame includes a plurality of frame bodies that support a plurality of prism glasses, and a base body that supports the frame bodies, the step of fixing the frame body to the base body of the lattice frame, and the base body of the lattice frame And fixing the prism glass to the frame, by setting the number and length of the frame according to the dimensions of the place where the prism glass panel is installed, A prism glass panel using existing prism glass can be easily constructed in a short period of time for openings of various sizes and shapes. In addition, the method includes a step of attaching a spacer-use gasket, which is provided with a strip protrusion piece that comes into contact with a frame supporting a plurality of prism glasses, to the prism glass, and a step of fixing the prism glass to the frame. It becomes possible to construct a prism glass panel efficiently. In addition, by having a process of attaching a transparent resin plate below the prism glass, even if the prism glass is damaged, it is possible to prevent the fragments from falling, and a prism glass panel that is safer than before can be obtained. It becomes possible to construct. In addition, when the base of the lattice frame is bolted to the housing via the mounting member, it can be attached and detached according to the shape and size of the mounting member to the housing for various houses and buildings and various locations. It becomes possible to respond flexibly and inexpensively.

  FIG. 1 is an enlarged sectional view of a main part of a prism glass panel according to the present invention. FIG. 2A is a plan view of a spacer combined gasket, and FIG. 2B is a cross-sectional view. 3A is a plan view of the prism glass panel 10, FIG. 3B is a longitudinal sectional view, and FIG. 3C is a transverse sectional view different from FIG. 4A is a plan view of the lattice frame, and FIG. 4B is a cross-sectional view of the lattice frame. FIG. 5A is a plan view of another prism glass panel 10a, FIG. 5B is a longitudinal sectional view, and FIG. 5C is a transverse sectional view different from FIG. FIG. 6A is a longitudinal sectional view of a prism glass panel construction example of the present invention, and FIG. 6B is a sectional view different from FIG. 6A by 90 °.

  In the figure, 10 is a prism glass panel, 11 is a prism glass, 12 is a spacer gasket, 13 is a lattice frame, 14 is a joint, 14a is a backup material, 14b is a sealing material, 15 is a transparent resin plate, 16 is a casing, Reference numeral 17 denotes an attachment member for attaching the prism glass panel 10 to the housing 16, and 18 and 19 denote fixing bolts.

  As shown in FIG. 1, the prism glass 11 has a square or circular top surface 11a having a planar shape, a side wall surface 11b extending downward from the periphery of the top surface 11a, and a bottom surface 11c having a recessed center. This is a glass block formed in a reverse concave shape as a whole. The prism glass 11 has dimensions of 200 mm on one side, 200 mm on the other side, and 50 mm in height, and a pattern 11 d that refracts light is formed on the back surface (inner surface) of the top surface 11 a.

As shown in FIGS. 1 and 2, the spacer gasket 12 has a substantially L-shaped cross section that fits around the side wall surface 11b and the bottom surface 11c of the prism glass 11, and one side of the inner surface has a predetermined dimension (for example, The strips 12c to 12f are formed on the outer peripheral surface of the upright portion 12a and have a predetermined thickness (for example, approximately 20 mm), and the protrusions have a small protruding dimension on the inner peripheral portion. Projection pieces 12g to 12i are formed. In the spacer gasket 12, the strip projection pieces 12 c to 12 f abut against the frame body 13 d of the lattice frame 13, and the strip projection pieces 12 g to 12 i are the peripheral surface of the side wall surface 11 b of the prism glass 11 and the horizontal portion 12 b is the bottom surface. 11c and the support surface 13e of the frame 13d, the liquid such as water does not leak between the prism glass 11 and the spacer gasket 12 or between the spacer gasket 12 and the frame 13d. The grid frame 13 and the floor of the building are not soiled. In addition, after the construction as shown in FIGS. 3A to 3C, the spacer combined gasket 12 needs to have 30% or more of the dimension (area) from the bottom surface 11c of the prism glass 11 to the side wall surface 11b. In the example, 70% was used. The prism glass panel 10 having such a configuration has a mass per unit area of 78 kg / m ² , which is approximately 40 kg (35% reduction compared to the conventional prism) and lighter than the conventional prism glass panel.

  Moreover, since the material of the spacer combined gasket 12 is EPDM (ethylene-propylene-diene monomer rubber: specific gravity 0.86) which is an elastic material, it is excellent in weather resistance, water resistance and sealability. The hardness of the rubber constituting the spacer gasket 12 is 60 to 80 degrees according to the stipulation of the durometer hardness test of JIS 5756 “Building Gasket”. In this embodiment, 70 degrees is used. did.

As shown in FIGS. 4A and 4B, the frame body 13d of the lattice frame 13 has a lattice shape having a substantially outer size width of the prism glass 11 in order to support the plurality of prism glasses 11. The three frame bodies 13d with which the strip projection pieces 12c, 12d, 12e and 12f of the spacer gasket 12 abut are fixed to the base body 13a. The base 13a has a structure in which the side frame portion 13b is connected by a connecting member 13c. The lattice frame 13 is made of a metal such as stainless steel having excellent mechanical strength and durability, and has a welded structure. Such a lattice frame 13 has a mass per unit area of a conventional cast iron frame of about 67 kg / m ² , whereas the lattice frame 13 has a mass of about 40 kg / m ² . Contributes greatly to weight reduction. The exposed surface 13f below the lattice frame 13 is sprayed with a dew-proof coating mainly composed of colloidal silica to form a coating film 13g having a thickness of about 1 mm. Even under the conditions of dew condensation, the dew-proof performance is exhibited such that no dew condensation occurs for up to 6 hours.

  The joint part 14 has a structure having a backup material 14a and a sealing material 14b made of silicone of a color suitable for the surface at the interface between the prism glass 11, the spacer gasket 12 and the frame body 13d of the lattice frame 13 and the joint part 14. It is. Further, the volume occupied by the spacer gasket 12 in the joint portion 14 is about 40% of 30% or more. If the dimension from the bottom surface 11c of the prism glass 11 to the side wall surface 11b is 100%, the process of providing the backup material 14a and the sealing material 14b can be simplified, and the construction time can be further shortened and the manufacturing cost can be reduced. The effect of is remarkable.

The backup material 14a is made of polyethylene closed cell foam. The mass per unit area of the joint portion 14 and the prism glass 11 is 53 kg / m ² in the conventional mortar specification, whereas it is 38 kg / m ^{2 in} the specification of this embodiment, and the prism glass panel. 10 contributes to weight reduction. In addition, by using silicone for the sealing material 14b on the outer surface of the joint portion 14, the weather resistance is good and the color tone can be selected quite freely. It is possible to change the color tone.

  Under the prism glass 11 in the frame body 13d of the lattice frame 13, a transparent resin plate 15 made of polycarbonate having a thickness of 2 mm is laid and arranged. Even if the prism glass 11 is broken, the fragments are dropped. The structure is prevented by the transparent resin plate 15. Further, by forming a heat-insulating layer 21 with air having a thickness of 45 mm by interposing a spacer-use gasket 12 between the prism glass 11 and the transparent resin plate 15 made of polycarbonate, a thermal conductivity is obtained. It is possible to significantly reduce the occurrence of condensation. Further, by selecting the transparency and color tone of the transparent resin plate 15, it is possible to adjust the color tone according to the light control, the surrounding color tone, or the color tone conspicuous with respect to the surroundings.

  Further, as shown in FIGS. 3A to 3C, mounting members 17 for mounting to the housing 16 are fixed to the lattice frame 13 of the prism glass panel 10 with a plurality of fixing bolts 18. As shown in FIGS. 6A and 6B, the mounting member 17 is supported by the housing 16 and is detachably fixed by a fixing bolt 19.

  Next, the prism glass panel 10a in which the frame body 13d of the lattice frame 13 shown in FIGS. 4A and 4B is increased will be described. In this embodiment, as shown in FIGS. 5A to 5C, the frame 13d of the lattice frame 13 is increased by one in accordance with the size of the opening of the housing, and the connecting member 13c matched to the size is used. The side frame 13b is fixed to the connected base 13a, the spacer gasket 12 is fitted to the prism glass 11, and the prism glass 11 having the spacer gasket 12 fixed thereto is fitted into the frame 13d of the lattice frame 13 so as to be aligned. Thereafter, the joint portion 14 is formed to form the prism glass panel 10a.

  Next, an example in which the prism glass panel 10 to which the mounting member 17 is fixed is produced and applied will be described.

  First, as shown in FIG. 4A, a length corresponding to the number of frame bodies 13d in which a pair of side frame portions 13b corresponding to the length of the frame body 13d having a size corresponding to the number of prism glasses 11 is arranged in parallel. The base member 13a is manufactured by connecting (welding, screwing, etc.) with the connecting member 13c, and the frame 13d is aligned and fixed to the base member 13a as shown by a broken line as shown in FIG. The lattice frame 13 is produced by welding, screwing, or the like. As shown in FIG. 1, the prism glass 11 is fitted into the surface having the strip protrusions 12g to 12i of the spacer combined gasket 12 shown in FIG. 2, and is adhered with an adhesive (not shown). Next, the prism glass 11 having the spacer gasket 12 fixed thereto is fitted into the frame body 13d of the lattice frame 13 as shown in FIG. 4, and the strip projection pieces 12c to 12f are replaced with the frame body 13d of the lattice frame 13 or other prism glass. 11 is pressed and brought into contact with the strip protrusion pieces 12c to 12f of the spacer-use gasket 12 fixed to the spacer 11. Next, the joint material 14 is filled with a backup material 14a, and a sealing material 14b made of silicone having a suitable color tone is filled and solidified from above. When the sealing material 14b is solidified, the prism glass panel 10 as shown in FIGS. 3A to 3C is completed. The prism glass panel 10 is formed between the prism glass 11 and the spacer combined gasket 12, between the spacer combined gasket 12 and the lattice frame 13, and in the frame 13 d by the protrusions 12 c to 12 i of the spacer combined gasket 12. Since there is no gap between the spacer-use gaskets 12 fixed to each other, the waterproof effect is exhibited immediately after the production.

  Next, the prism glass panel 10 is carried into the field, and the attachment member 17 for attaching to the housing 16 is fixed to the lattice frame 13 with a plurality of fixing bolts 18. Next, the mounting member 17 fixed to the prism glass panel 10 is supported on the casing 16 before the flooring 20 shown in FIGS. 6 (A) and 6 (B) is laid, and the casing is passed through the fixing holes 19 in the drill holes 17a. 16 is fixed. After that, when the flooring 20 is laid, the backup material 14a is filled between the flooring 20 and the prism glass 11 adjacent to the prism glass panel 10, and then the sealing material 14b is filled and solidified from above. 6 (A), the construction of the prism glass panel 10 as shown in (B) is completed in a short period of time.

  As another construction method, first, the lattice frame 13 shown in FIGS. 4A and 4B is fixed to the housing 16 via the mounting member 17. Next, the prism glass 11 having the spacer gasket 12 fixed thereto is fitted into the frame body 13d of the lattice frame 13, and the strip protrusion pieces 12c to 12f are fixed to the structural material of the lattice frame 13 and the other prism glass 11 by using the spacer glass gasket. The twelve strip protrusion pieces 12c to 12f are pressed and brought into alignment. Next, after the flooring 20 is disposed, the back-up material 14a is filled between the joint portion 14 and the flooring 20 and the prism glass 11, and the sealing material 14b is filled from above to be solidified. When solidified, the construction of the prism glass panel 10 as shown in FIGS. 6A and 6B is completed in a short period of time.

  As another construction method, first, the base body 13a of the lattice frame 13 shown in FIGS. 4A and 4B is fixed to the housing 16 via the mounting member 17. Next, the prism glass 11 having the spacer combined gasket 12 fixed thereto is fitted into the frame 13d, and the strip protrusions 12c to 12f are connected to the structural material of the lattice frame 13 and the other prism glass 11 fixed protrusion. The pieces 12c to 12f are pressed and contacted to be aligned. Next, the frame body 13d in which the prism glass 11 is arranged and arranged is attached to the base body 13a of the lattice frame 13 fixed to the housing 16 by screws or other methods. Finally, after the flooring 20 is disposed, the back-up material 14a is filled between the joint portion 14 and the flooring 20 and the prism glass 11, and the sealing material 14b is filled from above to be solidified. When solidified, the construction of the prism glass panel 10 as shown in FIGS. 6A and 6B is completed in a short period of time.

  In the above-described embodiment, the case where the number of the frame bodies 13d of the lattice frame 13 is increased is shown, but not only the number but also the length of the frame body 13d may be changed. In the above embodiment, the prism glass 11 has a side of 200 mm × the other side of 200 mm × the height of 50 mm. However, a prism glass panel having a side of 120 mm × the other side of 120 mm × a height of 40 mm is used. It may be produced. Further, in the above embodiment, the mounting member 17 and the prism glass panel 10 are detachably fixed by the fixing bolts 18 and 19, but may be fixed by welding, fixed by fitting, fixed by fitting and fixing pins, etc. Good.

  The present invention is also applicable to panels using pottery other than glass blocks, ceramics and other brittle blocks.

The principal part expanded sectional view of the prism glass panel in this invention. (A) is a top view of the spacer combined use gasket of this invention, (B) is a longitudinal cross-sectional view of (A). (A) is a top view of the prism glass panel and attachment member in this invention, (B) is a longitudinal cross-sectional view of (A), (C) is a cross-sectional view of (A). (A) is a top view of a lattice frame and the member for attachment, (B) is a cross-sectional view of (A). (A) is a top view of the other prism glass panel and attachment member in this invention, (B) is a longitudinal cross-sectional view of (A), (C) is a cross-sectional view of (A). (A) is a longitudinal cross-sectional view of the prism glass panel construction example of this invention, (B) is the top view. (A) is a principal part expanded sectional view of the conventional prism glass panel, (B) is the partial fracture | rupture side surface of a spacer combined use gasket, (C) is the perspective view which fractured | ruptured partially the prism glass panel after construction.

Explanation of symbols

10, 10a Prism glass panel 11 Prism glass 11a Top surface 12 Spacer combined gaskets 12c to 12i Strip protrusion 13 Lattice frame 13a Base 13b Side frame portion 13c Connecting member 13d Frame body 13e Support surface 13f Exposed surface 13g Coating film 14 Joint portion 14a Backup material 14b Sealing material 15 Transparent resin plate 16 Housing 17 Mounting member 17a Drill holes 18, 19 Fixing bolt 20 Flooring material 21 Heat insulation layer

Claims (14)

In a prism glass panel having a plurality of prism glasses, a lattice frame supporting the prism glasses, and joints between the prism glasses,
A prism glass panel, wherein the lattice frame includes a plurality of frames that support a plurality of prism glasses, and a base that supports the frames.   2. The prism glass panel according to claim 1, wherein the frame body supports a plurality of prism glasses in alignment in one direction.   3. The frame body according to claim 1 or 2, wherein the frame body supports and aligns a plurality of prism glasses to which a frame-like spacer gasket having a strip protrusion piece provided on the outer periphery is attached. The prism glass panel described.   The prism glass panel according to any one of claims 1 to 3, wherein the prism glass panel is 110 kg or less per square meter.   The prism glass panel according to any one of claims 1 to 4, wherein the lattice frame has an average mass per square meter of 60 kg or less.   6. The prism glass panel according to claim 5, wherein the lattice frame has a structure in which steel materials are welded.   The prism frame according to any one of claims 1 to 6, wherein a dew-proof paint is applied to a lower exposed surface of the lattice frame.   The prism glass panel according to claim 1, wherein a transparent resin plate is attached below the prism glass.   The prism glass panel according to claim 8, wherein a sealed space is formed between the prism glass and the transparent resin plate.   The prism glass panel according to claim 1, wherein the prism glass panel is used indoors. In a construction method for constructing a prism glass panel having a plurality of prism glasses, a lattice frame supporting the prism glasses, and a joint portion between the prism glasses on the casing,
The lattice frame includes a plurality of frame bodies that support a plurality of prism glasses, and a base body that supports the frame bodies, the step of fixing the frame body to the base body of the lattice frame, and the base body of the lattice frame A prism glass panel construction method comprising: fixing the prism glass to a frame; and fixing the prism glass to a frame.   A step of attaching to the prism glass a spacer-use gasket provided with a strip projection piece that comes into contact with a frame supporting a plurality of prism glasses, and a step of fixing the prism glass to the frame. Item 12. A method for constructing a prism glass panel according to Item 11.   The method for constructing a prism glass panel according to claim 11, further comprising a step of attaching a transparent resin plate below the prism glass.   The prism glass according to any one of claims 11 to 13, wherein the step of fixing the base of the lattice frame to the housing is a step of bolting the base of the lattice frame to the housing via a mounting member. Panel construction method.