JP2011042955A - Connection structure of component member in eaves structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a connection structure of component members in a laterally extending eaves structure, which has a long eaves panel disposed along the exterior wall of a building in the lateral extension direction. <P>SOLUTION: In this connection structure, one of eaves component members is designated as a first component member (M1) and the other is designated as a second component member (M2), and with both members facing each other, the members are connected to each other through a long connection member (26) extending in the extension direction (L). The first component member (M1) and the second component member (M2) form a tunnel-like space (44) of receiving grooves (32)(38) facing each other in the vertical direction when the upper projection (29) of the first component member is fitted to the upper recess (35) of the second component member and the lower projection (36) of the second component member is fitted to the lower recess (30) of the first component member. When the receiving grooves (32)(38) are vertically expanded by press-fitting the connection member (26) into the tunnel-like space (44), an upward fitting rib (33) is fitted into a packing storage groove (31) and a packing (43) is compressed, and a downward fitting rib (37) is fitted into a locking groove (39). <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a connecting structure of constituent members in a horizontal-type eaves structure provided with an elongate eaves panel arranged in a laterally extending direction along an outer wall of a building.

  The fence structure attached to the outer wall of the building is classified into a “vertically stretched type” and a “horizontal stretch type” depending on the layout of the fence panel.

  As shown in FIG. 11 (A), the “longitudinal-type” eaves structure has a large number of eaves panels p1 arranged so as to extend in the outdoor direction from the outer wall of the building through the support member S1 in the lateral direction of the outer wall. By arranging in a row, the ridge structure P1 is formed. Therefore, since a relatively short ridge panel p1 corresponding to the width W is only required to be transported to the site, transportation is easy. Further, since the eaves panel p1 is obtained by cutting a long panel according to the output width W, there is an advantage that it is possible to design the eaves structure P1 having a free output width dimension.

  However, in the case of the “longitudinal type”, it is necessary to prepare a number of eaves panels p1 by accurately cutting a long panel according to the width W as described above, and it is arranged in the field. Since a large number of eaves panels p1 must be connected to each other one by one, the operation becomes complicated. And even if it tries to arrange | position the eaves panel p1 in the corner corner part C1 of an outer wall, since it cannot be supported, there exists a problem that the corner eaves part PC cannot be formed.

  On the other hand, as shown in FIG. 11 (B), the “horizontal-type” ridge structure is formed by arranging a long ridge panel p2 in the lateral extension direction L along the outer wall of the building. The structure P2 is formed. Therefore, the corner flange PC can be formed by extending the flange panel p2 so as to reach the corner corner portion C2 of the outer wall. Since the eaves panel p2 is fixed to the outer wall through the support member S2, the load of the corner eaves part PC formed integrally with the eaves panel p2 is supported by the support member S2.

  However, in the case of the “horizontal type”, the base member b fixed to the outer wall of the building via the support member S2, the eaves panel p2 arranged in the width direction W from the base member, and the eaves panel p2 Since the scissors constituting body P2 is supported in a cantilevered manner by the support member S2 in a state where the tip members e arranged at the tip of each other are connected to each other, a high connection strength is required at each connecting portion. In this regard, for example, when the eaves structure P2 is rigidized by the beam member B and the beam member B is supported by the support member S2, the design of the eaves structure P2 is impaired by the exposed beam member B, which is desirable. Absent.

JP 2000-1405078 A

  The above-mentioned “horizontal type” ridge structure has a connection structure that facilitates connection and realizes a strong connection with respect to the connecting portions of the base member b, the heel panel p2, and the tip member e. Providing is a challenge.

  In addition, in order to increase the protruding width W of the fence structure P2, a plurality of fence panels p2, p2 are arranged side by side in the outdoor direction. In this case, adjacent fence panels p2, With respect to the mutual connecting portions of p2, it is an object to provide a connecting structure that facilitates connecting work and realizes strong connection.

  Furthermore, it is required that the connecting portions of the constituent members of the heel construction P2 as described above are connected in a watertight manner so that rainwater does not penetrate the connecting portions and drop downward.

  This invention provides the connection structure which solved the said subject regarding the structural member in the eaves structure of a "horizontal tension type".

  A first invention of the present invention relates to a connecting structure of a base member and a heel panel in a “horizontal type” ridge structure, and the base member and the heel panel are formed by extrusion molding in the extending direction L. It is composed of a molding material, one of which is a first component member and the other is a second component member, with both members facing each other, via a long connecting member extending in the extending direction L, Provide a connecting structure.

  The second invention of the present invention relates to a connecting structure of a heel panel and a tip member in a “horizontal type” ridge structure, wherein the heel panel and the tip member are extruded in the extending direction L. It is composed of a molding material, one of which is a first component member and the other is a second component member, with both members facing each other, via a long connecting member extending in the extending direction L, Provide a connecting structure.

  A third invention of the present invention relates to a connection structure of a plurality of heel panels arranged in a side-by-side manner in a “horizontal-type” ridge structure, and the heel panel is extruded in the extending direction L. A long connection extending in the extension direction L with both members facing each other, with one of the adjacent saddle panels as the first component and the other as the second component Provided is a structure for connecting to each other via a member.

  In the first to third aspects of the invention, the first component has an upper convex portion at the upper portion and a lower concave portion at the lower portion, and a packing storage groove is formed on the upper surface of the upper convex portion with respect to the facing portion. A receiving groove is formed on the lower surface, and an upward fitting rib is provided on the lower edge of the lower concave portion. The second component member has an upper concave portion at the upper portion and a lower convex portion at the lower portion with respect to the facing portion. Providing a downward fitting rib on the upper edge of the upper concave portion, forming a receiving groove on the upper surface of the lower convex portion and forming a locking groove on the lower surface, and storing the packing in the packing storage groove The upper convex part of the first component member is fitted into the upper concave part of the second component member, and the lower convex part of the second component member is fitted into the lower concave part of the first component member so as to face each other from above and below. Press-fit the connecting member into the tunnel-like space formed by the groove Thus, the receiving groove is expanded in the vertical direction, the fitting rib of the second component member is fitted into the packing storage groove of the first component member, the packing is compressed, and the fitting rib of the first component member is compressed. It is comprised so that it may fit in the latching groove | channel of a 2nd structural member.

  In a preferred embodiment of the present invention, the long connecting member extending in the extending direction L is integrally provided with a rod-like portion that is press-fitted into the tunnel-like space and a rib that protrudes from a side surface of the rod-like portion. The first component member and the second component member are provided with opposing portions on both sides of each receiving groove, and push the receiving groove in the vertical direction. When the connecting member is pressed into the tunnel-like space, the rod-like portion expands the receiving groove in the vertical direction when the connecting member is pressed into the tunnel-like space when the facing portions facing each other are separated from each other. The rib is configured to be inserted into the gap.

  In this case, the connecting member has a rod-shaped portion formed in a rectangular cross section, and ribs projecting from both side surfaces of the rod-shaped portion, and the receiving grooves are opposed to each other from above and below the first component member and the second component member. Are formed in a substantially U-shaped cross section, and a protrusion is formed at the bottom of both receiving grooves.

  According to the first to third aspects of the present invention, the upper convex portion 29 of the first component member M1 in which the packing 43 is stored in the packing storage groove 31 is fitted into the upper concave portion 35 of the second component member M2, With the lower convex portion 36 of the second constituent member M2 fitted into the lower concave portion 30 of the first constituent member M1, the connecting member 26 is inserted into the tunnel-like space 44 formed by the receiving grooves 32 and 38 facing from above and below. By press-fitting, the receiving grooves 32 and 38 are expanded in the vertical direction, the fitting ribs 37 of the second component member M2 are fitted into the packing storage grooves 31 of the first component member M1, and the packing 43 is compressed. Since the fitting rib 33 of the first component member M1 is fitted into the locking groove 39 of the second component member M2, a strong connection structure 7 is achieved, and the first component member M1 is connected via the connection structure 7. And the entire second component M2 Was rigid body, it is possible to provide a canopy structure 1 bear on the support cantilever.

  In addition, at the time of connection, the tip of the connection member 26 is inserted into the opening end of the tunnel-shaped space 44 formed by the receiving grooves 32 and 38 of the first component member M1 and the second component member M2, and then the connection member 26 Thus, the press-fitted connecting member 26 enters the receiving grooves 32 and 38 from the tip while expanding the receiving grooves 32 and 38, and firmly bonds the first component member M1 and the second component member M2 over the entire length. , Work can be done quickly and easily.

  And since it is the structure which is located in the upper part of the connection structure 7 and compresses the packing 43 with the fitting rib 37, the bottom part of the receiving grooves 32 and 38 is made into the upper and lower surfaces of the connection member 26 with the restoring force of the compressed packing 43 In this way, it is possible to achieve a water-tight seal free from rain leakage and the like, while achieving a connection without rattling.

  According to the fourth aspect of the present invention, the connecting member 26 is configured such that the ribs 28 are formed integrally with the rod-shaped portion 27 so that the connecting member 26 is maintained in a straight state without being bent in the extending direction L. Therefore, the press-fitting work into the tunnel-like space 44 as described above becomes easy.

  According to the fifth aspect of the present invention, the rod-shaped portion 27 of the connecting member 26 is formed to have a rectangular cross section, and the receiving grooves 32 and 38 are formed to have a substantially U-shaped cross section while projecting to the bottom portion. Since the strips 34 and 40 are formed, the frictional resistance at the time of press-fitting the rod-like portion 27 is reduced, and the press-fitting work is facilitated. Even if the rain 43 is allowed to enter due to deterioration of the packing 43 or the like, since the protrusions 34 and 40 are pressed against the upper and lower surfaces of the rod-shaped portion 27, the rain water can be prevented from passing therethrough.

It is sectional drawing which shows the state which connected each structure body mutually regarding the collar structure of this invention. It is sectional drawing which shows the state which isolate | separated each structure from each other regarding the bag structure of this invention. It is a perspective view which shows one Example of a connection member. It is sectional drawing which shows embodiment which connected the eaves panel regarding the eaves structure of this invention, and showed the state which connected each structure. It is sectional drawing which expands and shows a connection structure regarding the collar structure of this invention. The connection method of a connection structure is shown, (A) is sectional drawing which shows the state before connection, (B) is sectional drawing which shows the state in connection, (C) is a cross section which shows the state after connection. It is sectional drawing which shows a connection state regarding a connection structure. It is sectional drawing which shows the state which attached the suspending member to embodiment which attached the coffin panel continuously regarding the coffin structure of this invention. It is sectional drawing which expands and shows the A section of FIG. It is sectional drawing which shows the state which attached the suspension member to embodiment which increased the number of continuous installation of the coffin panel regarding the coffin structure of this invention. The reference example for understanding this invention is shown, (A) is a top view which shows the cocoon structure of "vertically stretched form", (B) is a top view which shows the ridge structure of "horizontal form" is there.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

  1 is a “horizontal type” in which a long eaves panel 2 as described above based on FIG. 11 (B) is arranged in a laterally extending direction L along an outer wall 3 of a building. The cocoon structure is constructed.

  The scissor structure 1 includes a base member 5 fixed to the outer wall 3 via a support member 4, a tip member 6 that constitutes the leading edge of the scissor structure 1, and a space between the base member 5 and the tip member 6. The base member 5, the heel panel 2, and the tip member 6 are made of a metal molding material such as an aluminum molding material extruded in the extending direction L.

  Therefore, with respect to each other of the base member 5 and the eaves panel 2, a connection structure 7a is provided in which one is a first component member M1 and the other is a second component member M2, and can be connected in a state where both members face each other. ing.

  In addition, with respect to each other of the heel panel 2 and the tip member 6, a connection structure 7b is provided in which one is a first component member M1 and the other is a second component member M2, which can be connected in a state where both members face each other. ing.

  Furthermore, as shown in FIG. 4, regarding the embodiment in which two or more heel panels 2, 2 are connected in the width direction, one of the adjacent heel panels 2, 2 is the first component member M <b> 1 and the other A second structure member M2 is provided with a connection structure 7c that can be connected in a state where both members face each other.

  As shown in FIG. 2, the support member 4 includes a plate-like portion 9 that is fixed to the outer wall 3 of the building by a bolt 8 such as an anchor bolt, and projects forward (outdoor direction) above and below the plate-like portion 9. An upper lip 10 and a lower lip 11 are provided.

  On the other hand, the base member 5 constitutes a hollow body in which the upper plate portion 12 and the lower plate portion 13 positioned above and below are connected by the inner wall 14 and overlaps the upper lip 10 and the lower lip 11 from above and below. The fixing pieces 15 and 16 are integrally provided. The upper plate portion 12 forms an inclined wall having a downward slope toward the outside, and the fixing pieces 15 and 16 extend from the upper plate portion 12 and the lower plate portion 13 through stepped portions inward. By being provided, stepped pockets 17 and 18 are formed, respectively.

  Therefore, the fixing pieces 15 and 16 are fixed to the upper lip 10 and the lower lip 11 by screws 19 and 20, respectively, and as shown in FIG. 21 and the lower stepped pocket 18 is closed by fitting the lid plate 22.

  The eaves panel 2 constitutes a hollow panel in which an upper plate portion 23 and a lower plate portion 24 positioned above and below are connected by a plurality of inner walls 25, 25 at a substantially central portion.

  The tip member 6 is configured to be selectable from a nose tip member 6a as shown by a solid line in FIG. 2 and a heel member 6b as shown by a chain line.

  In the illustrated embodiment, the connection structures 7a, 7b, and 7c have substantially the same configuration, and will be described below as the connection structure 7. In the present invention, at least one of the connecting structures 7a, 7b, and 7c includes the connecting structure 7 of the present invention, and other connecting structures may employ different structures from the present invention. good.

  The connecting structure 7 of the present invention is configured such that the first component member M1 and the second component member M2 face each other via a long connecting member 26 extending in the extending direction L as shown in FIG. Connected to The connecting member 26 is integrally provided with a rod-like portion 27 extending the entire length in the extending direction L of the first component member M1 and the second component member M2, and a rib 28 protruding from the side surface of the rod-like portion 27, such as aluminum. It is extrusion-molded with a metal, a tough synthetic resin, a high hardness rubber or the like. As shown in the figure, the connecting member 26 has a rod-like portion 27 formed in a thick section rectangle, and relatively thin plate-like ribs 28, 28 projecting on both side surfaces of the rod-like portion 27, so that the cross section is almost as a whole. It is formed in a cross shape and thereby extends in a straight line without being curved in the extending direction L. That is, since the connecting member 26 is thin and long, it is easy to bend in the extending direction when the cross section is a simple circle or rectangle, but the ribs 28 and 28 are integrally provided on the rod-like portion 27. The straight line state is maintained without bending in the extending direction, and the press-fitting work to the connecting structure 7 as described later is facilitated. Accordingly, in the case of the example shown in the figure, a cross section having a substantially cross-sectional shape in which the ribs 28 are provided on both side surfaces of the rod-shaped portion 27 is shown, but the number of the ribs 28 is not questioned.

  As shown in FIG. 5, the connecting structure 7 is located at the facing portion of the first component member M <b> 1 and the second component member M <b> 2 that face each other so as to match each other in the vertical direction when connected. With respect to the reference horizontal lines C1 and C2 extending in the middle portion in the thickness direction and the vertical reference vertical line V that matches the longitudinal direction when connected, the protrusions and the recesses are fitted, and the grooves and ribs are fitted. It is comprised so that it may fit.

  The first component member M1 is located at the facing portion, and is provided with an upper convex portion 29 in the upper portion, a lower concave portion 30 in the lower portion, a packing storage groove 31 on the upper surface of the upper convex portion 29, and on the lower surface. A receiving groove 32 is formed, and an upward fitting rib 33 is provided at the lower edge of the lower recess 30. The opening edge 31 a inside the packing housing groove 31, the center of the receiving groove 32, and the fitting The outer edge 33a of the rib 33 is configured to substantially match the reference vertical line V. The receiving groove 32 is formed in a substantially U-shaped cross-section that is located slightly above the reference horizontal line C1 and opens downward. The receiving groove 32 is provided with opposing portions 32a and 32a on both sides of the opening edge, and the center of the bottom of the receiving groove 32. A protrusion 34 is provided on the surface.

  The second component member M2 is located at the facing portion, and is provided with an upper concave portion 35 at the upper portion, a lower convex portion 36 at the lower portion, and a downward fitting rib 37 at the upper edge of the upper concave portion 35. A receiving groove 38 is formed on the upper surface of the side projection 36 and a locking groove 39 is formed on the lower surface. The outer edge 37 a of the fitting rib 37, the center of the receiving groove 38, and the locking groove 39. The inner groove wall 39a is substantially aligned with the reference vertical line V. The receiving groove 38 is formed in a substantially U-shaped cross section that is located slightly below the reference horizontal line C2 and opens upward, and is provided with opposing portions 38a and 38a on both sides of the opening edge, and the bottom center of the receiving groove 38 A protrusion 40 is provided on the surface.

  The first component member M1 is located on the reference horizontal line C1, and faces the hollow portion from the back surface of the facing portion 32a inside the receiving groove 32 and the lower concave portion 30 (in the direction opposite to the facing direction). A substantially cylindrical reinforcing piece 41 is protruded, and similarly, the second component member M2 is positioned on the reference horizontal line C2 so as to extend from the back surface of the upper recessed portion 35 and the facing portion 38a inside the receiving groove 38 to the hollow portion. A substantially cylindrical reinforcing piece 42 is provided so as to project (toward the direction opposite to the facing direction).

  The connection method of the connection structure 7 configured as described above is shown in FIG.

  As shown in FIG. 6A, in a state where the packing 43 is stored in the packing storage groove 31 of the first component member M1, the reference horizontal line C1 of the first component member M1 is positioned at the lower position, and the second component member M2 By positioning the reference horizontal line C2 at the upper position, the reference horizontal line C2 is faced in a state of being deviated from each other, and the upper convex portion 29 of the first constituent member M1 is made to face the upper concave portion 35 of the second constituent member M2, as shown by the arrows in the figure. And the lower convex portion 36 of the second component member M2 is inserted into the lower concave portion 30 of the first component member M1.

  As shown in FIG. 6B, the fitting rib 37 of the second component member M2 is brought into contact with the inner opening edge 31a of the packing housing groove 31 of the first component member M1, so that the fitting rib of the first component member M1 is brought into contact. When 33 is brought into contact with the inner groove wall 39a of the locking groove 39 of the second component member M2, the first component member M1 and the second component member M2 match the reference vertical line V with each other. In this state, the fitting rib 37 and the packing storage groove 31 and the fitting rib 33 and the locking groove 39 are not yet fitted to each other, and the receiving portions 32a and 38 of the receiving grooves 32 and 38 facing each other vertically are opposed to each other. 38a are close to each other, but as shown by the arrow in the figure, when the first component member M1 is moved upward and the second component member M2 is moved downward along the reference vertical line V, the receiving groove 32 and 38 expand in the vertical direction, and the fitting rib 37 and the packing storage groove 31, and the fitting rib 33 and the locking groove 39 are fitted to each other.

  Therefore, when the rod-shaped portion 27 of the connecting member 26 is press-fitted into the tunnel-like space 44 formed by the receiving grooves 32 and 38 facing vertically, the receiving grooves 32 and 38 are vertically moved as shown in FIG. When the first component member M1 is moved upward as indicated by the arrow U by being pushed out, the second component member M2 is moved downward as indicated by the arrow D, thereby matching the respective reference horizontal lines C1 and C2. The fitting rib 37 is fitted into the packing housing groove 31 to compress the packing 43, and the fitting rib 33 is fitted into the locking groove 39, whereby the connecting structure 7 is firmly connected.

 In order to facilitate the work of press-fitting the rod-shaped portion 27 of the connecting member 26 into the tunnel-shaped space 44, for example, as shown in FIG. 3, a tapered portion 27a may be formed at the tip of the rod-shaped portion 27. It is not essential to form such a tapered portion 27a. In any case, the first component member M1 and the second component member M2 are positioned at the opening end of at least the tunnel-like space 44 where the insertion of the rod-shaped portion 27 is started, as shown by the arrows in FIG. 6B. It is only necessary to apply a force in the direction in which the reference horizontal lines C1 and C2 coincide with each other, insert the tip of the rod-like portion 27 from the open ends of the widened receiving grooves 32 and 38, and press-fit. As a result, the tip of the rod-shaped portion 27 is press-fitted in the extending direction L while expanding the receiving grooves 32 and 38, so that the first constituent member M1 and the second constituent member M2 after press-fitting each other over the entire length of the reference horizontal line C1 , C2 can be matched.

  When the connecting member 26 is press-fitted, the connecting member 26 is provided with ribs 28 and 28 so that the cross-section is formed in a cross shape and maintains a straight state, thereby facilitating the press-fitting operation. Further, since the protrusions 34 and 40 are provided at the bottoms of the receiving grooves 32 and 38, the frictional resistance when the rod-shaped portion 27 is press-fitted is reduced.

  When the rod-like portion 27 spreads the receiving grooves 32, 38, the opposing portions 32a, 32a facing each other and the opposing portions 38a, 38a are separated to form gaps 45, 45. The ribs 28 and 28 are inserted into the gaps 45 and 45.

  As shown in an enlarged view in FIG. 7, in the connection structure 7, the rod-shaped portion 27 pushes up the receiving groove 32 of the first component member M <b> 1 as indicated by an arrow U in a state where the connection member 26 is press-fitted into the tunnel-shaped space 44. At the same time, the receiving groove 38 of the second component member M2 is pushed down as indicated by an arrow D, and the ribs 28, 28 are formed in the gaps 45, 45 formed between the facing portions 32a, 32a and the facing portions 38a, 38a separated from each other. Is inserted.

  Therefore, in the upper part of the coupling structure 7, the packing storage groove 31 storing the packing 43 of the first component member M1 is pushed up as indicated by the arrow U1, and the fitting rib 37 of the second component member M2 is pushed down. While compressing the packing 43, the fitting rib 37 and the packing storage groove 31 are engaged corresponding to the depth E1.

  Further, in the lower part of the connection structure 7, the fitting rib 33 of the first component member M1 is pushed up as indicated by the arrow U2, and the locking groove 39 of the second component member M2 is pushed down as indicated by the arrow D2. Engagement is performed corresponding to the depth E2.

  Thereby, the first component member M1 and the second component member M2 are firmly connected so as not to be separated from each other. In this state, by receiving the restoring force of the compressed packing 43, the bottom portions of the receiving grooves 32 and 38 are strongly pressed against the upper and lower surfaces of the rod-like portion 27, thereby achieving a loose connection.

  Since the upper part of the connection structure 7 is sealed in a watertight manner by the fitting ribs 37 and the packing 43, rainwater does not enter, and therefore rainwater does not drop below the gutter structure 1. . At this time, even if rainwater enters due to deterioration of the packing 43 or the like, the joint between the uppermost fitting rib 37 and the packing storage groove 31 is joined to the lowermost fitting rib 33 and the locking groove 39. Since the path to the part forms a curved labyrinth (maze), it is difficult for rainwater to pass through, and the ridges 34 and 40 provided at the bottom of the receiving grooves 32 and 38 are provided on the rod-shaped part 27. Since it is in pressure contact with the lower surface, it prevents the passage of rainwater.

  As a result, the first component member M1 and the second component member M2 constituting the heel component 1 are firmly connected by the connection structure 7 to make the entire heel component 1 rigid, so that the base member 5 and the heel panel 2 and between the heel panel 2 and the tip member 6 are cantilevered with sufficient strength. However, as shown in FIGS. 8 to 10, when a plurality of eaves panels 2, 2 are arranged side by side in order to increase the protruding width of the eaves structure 1, an eaves device 46 as shown in FIG. The structure 1 may be suspended from the outer wall 3.

  In this case, as shown in FIG. 9, a fixing bracket 48 for fixing the lower bracket 47 of the suspension device 46 is inserted into the hollow portion of the heel panel 2, and the lower bracket 47 is fixed by a bolt / nut 49. 48 can be configured to be secured. For this reason, in the case of the illustrated embodiment, claws 50 and 51 that are opposed to each other are formed on the cylindrical reinforcing piece 42 of the heel panel 2 and the inner wall 25 that is opposed to the cylindrical reinforcing piece 42, respectively. A downward bent piece 48 a of the fixing plate 48 is constructed on the claws 50 and 51 in a state of being superimposed on the lower surface of the upper wall portion 23.

DESCRIPTION OF SYMBOLS 1 庇 structure 2 庇 panel 3 outer wall 4 support member 5 base member 6 tip member 7 (7a, 7b, 7c) connection structure M1 first component member M2 second component member 26 connection member 27 rod-like part 28 rib 29 upper convex part 30 Lower concave portion 31 Packing storage groove 32 Receiving groove 32a Opposing portion 33 fitting rib 34 ridge 35 upper concave portion 36 lower convex portion 37 fitting rib 38 receiving groove 38a facing portion 39 locking groove 40 ridge 43 packing 44 tunnel 44 Space 45

Claims (5)

It is a horizontal type ridge structure with a long ridge panel (2) arranged in a lateral extension direction (L) along the outer wall of the building,
The saddle structure (1) includes a base member (5) fixed to an outer wall of a building via a support member (4), a tip member (6) constituting a tip edge of the saddle structure, and It comprises a heel panel (2) disposed between a base member (5) and a tip member (6), and at least the base member (5) and the heel panel (2) are extruded in the extending direction (L). In what is composed of molded metal molding material,
Of the base member (5) and the eaves panel (2), one is a first component member (M1) and the other is a second component member (M2). L is a structure (7a) connected to each other via a long connecting member (26) extending to
The first component member (M1) has an upper convex portion (29) at the upper portion and a lower concave portion (30) at the lower portion, and a packing storage groove (31 on the upper surface of the upper convex portion (29). ) And a receiving groove (32) is formed on the lower surface, and an upward fitting rib (33) is provided on the lower edge of the lower recess (30),
The second component member (M2) is provided with an upper concave portion (35) in the upper portion and a lower convex portion (36) in the lower portion with respect to the facing portion, and a downward fitting rib on the upper edge of the upper concave portion (35). (37) is provided, the receiving groove (38) is formed on the upper surface of the lower convex portion (36) and the locking groove (39) is formed on the lower surface,
The upper convex portion (29) of the first component member (M1) having the packing (43) stored in the packing storage groove (31) is fitted into the upper concave portion (35) of the second component member (M2), and the first 2 formed by receiving grooves (32) and (38) facing from above and below with the lower convex part (36) of the constituent member (M2) fitted into the lower concave part (30) of the first constituent member (M1). By pressing the connecting member (26) into the tunnel-shaped space (44), the receiving groove (32) (38) is expanded in the vertical direction, and the fitting rib (37) of the second component member (M2) is expanded. The packing (43) is inserted into the packing housing groove (31) of the first component (M1) to compress the packing (43), and the fitting rib (33) of the first component (M1) is used as the second component (M2). A connecting structure of component members in the heel component, which is configured to be fitted into the locking groove (39). It is a horizontal type ridge structure with a long ridge panel (2) arranged in a lateral extension direction (L) along the outer wall of the building,
The saddle structure (1) includes a base member (5) fixed to an outer wall of a building via a support member (4), a tip member (6) constituting a tip edge of the saddle structure, and The heel panel (2) is disposed between the base member (5) and the tip member (6), and at least the heel panel (2) and the tip member (6) are extruded in the extending direction. In what is composed of metal forming material,
Of the collar panel (2) and the tip member (6), one is a first component member (M1) and the other is a second component member (M2). L is a structure (7b) connected to each other via a long connecting member (26) extending to
The first component member (M1) has an upper convex portion (29) at the upper portion and a lower concave portion (30) at the lower portion, and a packing storage groove (31 on the upper surface of the upper convex portion (29). ) And a receiving groove (32) is formed on the lower surface, and an upward fitting rib (33) is provided on the lower edge of the lower recess (30),
The second component member (M2) is provided with an upper concave portion (35) in the upper portion and a lower convex portion (36) in the lower portion with respect to the facing portion, and a downward fitting rib on the upper edge of the upper concave portion (35). (37) is provided, the receiving groove (38) is formed on the upper surface of the lower convex portion (36) and the locking groove (39) is formed on the lower surface,
The upper convex portion (29) of the first component member (M1) having the packing (43) stored in the packing storage groove (31) is fitted into the upper concave portion (35) of the second component member (M2), and the first 2 formed by receiving grooves (32) and (38) facing from above and below with the lower convex part (36) of the constituent member (M2) fitted into the lower concave part (30) of the first constituent member (M1). By pressing the connecting member (26) into the tunnel-shaped space (44), the receiving groove (32) (38) is expanded in the vertical direction, and the fitting rib (37) of the second component member (M2) is expanded. The packing (43) is inserted into the packing housing groove (31) of the first component (M1) to compress the packing (43), and the fitting rib (33) of the first component (M1) is used as the second component (M2). A connecting structure of component members in the heel component, which is configured to be fitted into the locking groove (39). It is a horizontal type ridge structure with a long ridge panel (2) arranged in a lateral extension direction (L) along the outer wall of the building,
The saddle structure (1) includes a base member (5) fixed to an outer wall of a building via a support member (4), a tip member (6) constituting a tip edge of the saddle structure, and Consisting of a plurality of coffin panels (2) and (2) arranged in parallel between the base member (5) and the tip member (6), at least adjacent coffin panels (2) and (2) arranged in parallel Is constituted by a metal molding material extruded in the extension direction,
Of the adjacent saddle panels (2) and (2), one is a first component member (M1) and the other is a second component member (M2), with both members facing each other, the extending direction (L And (7c) connected to each other via a long connecting member extending to
The first component member (M1) has an upper convex portion (29) at the upper portion and a lower concave portion (30) at the lower portion, and a packing storage groove (31 on the upper surface of the upper convex portion (29). ) And a receiving groove (32) is formed on the lower surface, and an upward fitting rib (33) is provided on the lower edge of the lower recess (30),
The second component member (M2) is provided with an upper concave portion (35) in the upper portion and a lower convex portion (36) in the lower portion with respect to the facing portion, and a downward fitting rib on the upper edge of the upper concave portion (35). (37) is provided, the receiving groove (38) is formed on the upper surface of the lower convex portion (36) and the locking groove (39) is formed on the lower surface,
The upper convex portion (29) of the first component member (M1) having the packing (43) stored in the packing storage groove (31) is fitted into the upper concave portion (35) of the second component member (M2), and the first 2 formed by receiving grooves (32) and (38) facing from above and below with the lower convex part (36) of the constituent member (M2) fitted into the lower concave part (30) of the first constituent member (M1). By pressing the connecting member (26) into the tunnel-shaped space (44), the receiving groove (32) (38) is expanded in the vertical direction, and the fitting rib (37) of the second component member (M2) is expanded. The packing (43) is inserted into the packing housing groove (31) of the first component (M1) to compress the packing (43), and the fitting rib (33) of the first component (M1) is used as the second component (M2). A connecting structure of component members in the heel component, which is configured to be fitted into the locking groove (39). The long connecting member (26) extending in the extending direction (L) is integrally formed with a rod-shaped portion (27) press-fitted into the tunnel-shaped space (44) and a rib (28) protruding from a side surface of the rod-shaped portion. And is maintained in a straight posture so as not to bend in the extending direction via the rib,
The first component member (M1) and the second component member (M2) are provided with opposing portions (32a, 32a) (38a, 38a) on both sides of the respective receiving grooves (32), (38). (32) (38) is configured to form a gap (45) (45) by separating the opposing parts apart when the (38) is pushed up and down,
When the connecting member (26) is press-fitted into the tunnel-like space (44), the rod-like portion (27) expands the receiving groove (32) (38) in the vertical direction, and the rib (28) extends into the gap (45). 4. The connecting structure of component members in the bag structure according to claim 1, 2 or 3, wherein the structure is configured to be inserted. The connecting member (26) has a rod-shaped portion (27) having a rectangular cross section, and ribs (28) (28) projecting from both side surfaces of the rod-shaped portion,
The receiving grooves (32) and (38) facing the top and bottom of the first component member (M1) and the second component member (M2) are each formed in a substantially U-shaped cross section, and a ridge (34 5) (40) is formed, and the connecting structure of component members in the bag structure according to claim 1, 2, 3 or 4.

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