JP3640211B2 - Disaster prevention tile - Google Patents

Description

The present invention relates to a disaster prevention tile that prevents the flat roof tile from being displaced and lifted by strong winds to improve wind resistance and also improves waterproof performance.

(Function, performance, action, etc. required for disaster prevention tiles)
The first function required for disaster prevention tiles is wind resistance that prevents scattering due to strong winds during typhoons. In addition, the second function and the like that are required to be equivalent to the wind resistance performance are required to have excellent waterproof performance in a storm. In addition, in the case of flat roof tiles, the working length is often adjusted during construction, and the function for adjusting the working length is a necessary condition as the third function. That is, with respect to the working length, there is a variation in the construction of the roof tile pitch during actual construction, and it is necessary to adjust the working length even if it is not.

  Therefore, the mobility in the working direction, which is the third function, must be secured, the strong connection or fixing property, which is the first function, must be secured, and the seemingly conflicting functions must be satisfied at the same time. There wasn't. This relationship is the same in the relationship between the second waterproof function and other functions.

  In the following, the conventional technology will be described in detail, but in the conventional technology, the wind resistance performance (first function), waterproof performance (second function), and working length adjustment function (third function) are all achieved at the same time. There was no.

(Prior art 1)
As a conventional disaster prevention roof tile, there is a known wind-resistant flat roof tile described in [Claim 3] of JP-A-8-93141 and shown in FIGS. 13 to 16 of this specification. That is, the wind resistant thick flat roof tile of the prior art 1 is a thick flat roof tile that has a stacked structure in which the stepped portion of the pier covering portion a and the insertion receiving portion b is accommodated in the thickness of one roof tile. The hook receiving part b is formed at the end on the head c side of the insertion receiving part b by a water guiding band d and a water return e and having a surface at substantially the same level as the back surface of the roof tile, A roof tile formed by forming a notch h in the vicinity thereof and forming a locking projection i having a back surface portion that is substantially the same as or slightly higher on the top surface of the top surface. The locking protrusions i of the upper side restrain the locking receiving portion f of the upper tile on the oblique side and prevent it from swinging.
JP-A-8-93141

  In the conventional wind resistant thick flat roof tile of prior art 1, when the bottom g locking projection i is formed, a bottom notch h is formed in the vicinity of the center on the bottom g side (in the conventional manufacturing method, the notch is not cut). This is essential, and this point will be described later). For this reason, the water return j on the side edge of the butt h side has to be displaced toward the head c side near the center even if it is straight on both sides. . As a result, the water return j is in a deformed state at the butt g side edge, and the water flowing portion l between the water return j on the butt g side and the parallel inner water return k is in a deformed state. Therefore, the water return j near the center approaches the inner water return k or approaches the head c of the upper tile to be polymerized, and the distance between the two becomes shorter. The backflow rainwater blown from the water could not be received reliably, or the drainage could not be performed smoothly, and the waterproof performance was insufficient.

(Technical background of prior art 1)
Although the prior art 1 and the drawbacks thereof have been described due to the bottom notch h formed near the center on the bottom g side, the bottom notch h needs to be formed in order to form the bottom g locking projection i. The reason will be described below. That is, in the conventional roof tile forming method, since the upper and lower molds (molds) are formed by moving the material up and down in the vertical direction and pressurizing the raw material, the shape having a space portion in the middle in the vertical direction (such as a bowl shape) In this molding, the part forming mold for molding the space part was brought into contact with and caught by the upper molding part of the space part in the collar part when the mold was raised after pressure molding, and the collar part molding was impossible. .

(Related to the problems of prior art 1)
Hereinafter, the relationship between wind resistance performance and waterproof performance, which are the first and second functions of conventional disaster prevention tiles, will be described. Wind resistance performance is enhanced and raised by pressing the upper tile head engaging portion (locking receiving portion f) with the bottom tile bottom engaging portion (locking protrusion i). How much the wind speed can withstand the high wind pressure varies depending on the strength of the engaging portions of the upper and lower roof tiles. In the prior art 1, the locking receiving portion f on the head c side has many connecting portions with the water guide band d, but the connecting portion with the water return j of the locking projection i on the butt g side is the upright portion i. In particular, unless the strength of the buttocks engaging portion (locking protrusion i) is sufficient, the wind does not withstand strong wind pressure and breaks, and sufficient wind resistance performance cannot be obtained. Therefore, in order to secure and raise the strength of the buttocks engaging portion (locking protrusion i), it is necessary to increase the cross-sectional area of the maximum load load portion in the buttocks engaging portion (locking protrusion i). It is effective to increase the cross-sectional area by increasing the length in the buttocks direction (flow direction). However, in the prior art 1, all the bottom of the bottom engaging portion (locking protrusion i) is a bottom notch h, and increasing the length of the engaging portion is the length of the bottom notch h. This is directly connected to the increase of the height, and as a result, the formation position of the water return j moves from the butt side to the head side, and the waterproof performance described above further decreases. In other words, as the waterproof performance increases as the polymerization length in the flow direction increases, the bottom of the bottom engaging portion (locking protrusion i) becomes the bottom notch h as in the prior art 1. If this is the case, the polymerization length will be shortened by the length of the bottom notch h, and the waterproof performance will be reduced. The longer the bottom engaging portion (locking projection i), the higher the wind resistance, and the bottom notch h The longer the (locking protrusion i), the more contradictory conditions were that the waterproof performance was reduced. Therefore, considering that the conventional technology 1 cannot satisfy both wind resistance and waterproof performance, and the disaster prevention tile (wind resistant tile) needs to be strong against both wind and rain, the conventional technology 1 is unsolved. It can be said that this problem existed.

(Conventional technology 2)
Moreover, as a conventional disaster prevention roof tile, it is described in [Prior Art] of JP-A-8-93141, and a wind-resistant thick roof tile illustrated in FIGS. 17 to 18 of this specification is known. That is, the wind-resistant thick flat roof tile shown in FIG. 17 of the prior art 2 has a locking projection o on the side near the head n at the side end of the tile insertion receiving portion m, near the center of the edge on the side of the bottom p. As shown in FIG. 18, when the concave notches q are formed, and the zigzag tiles are laid together, as shown in FIG. Infiltrated into the roof, the swinging of the roof tiles and floating prevention were performed.

  Therefore, even in the wind resistant thick flat roof tile of the above prior art 2, since the recessed portion q is formed in the bottom portion p, there is a problem that the water return r becomes irregular and the waterproof performance is insufficient. There was also a problem in the function of adjusting the working length, which is the third function. That is, with regard to the function of adjusting the working length of the disaster prevention roof tile according to the prior art 2, the bottom tile bottom engaging portion (recessed portion q) is located above the roof top engaging portion (locking protrusion o). The upper roof tile is relatively slid in the head bottom direction (flow direction) while being pressed. On the other hand, as the working length adjustment function, if the engagement area (overlapping area) of the upper and lower engagement parts is not constant or not less than a certain value, considering the wind resistance performance, it has a sufficient working length adjustment function. I can't say that. Therefore, the engagement method in the prior art 2 is such that the bottom tile bottom engaging portion (recessed portion q) has the upper tile head engaging portion (locking projection o) in the vertical direction (vertical direction). Even though the working length can be adjusted by the length of the engaging portion, the windproof performance is achieved when the engaging area is not constant or the engaging area is small (shallow). Problems occur.

  As described above, the conventional disaster prevention tiles (conventional techniques 1 and 2) did not have a technique that satisfies all of the first, second, and third functions of wind resistance performance, waterproof performance, and working length adjustment function at the same time.

  In view of the problem that the three functions (wind resistance, waterproofing, adjustment function) based on the above-mentioned conventional technology could not be achieved at the same time, the present invention solves the above problem by simultaneously achieving the three functions with the novel disaster prevention tile.

  In addition, since the root cause of the prior art is due to the manufacturing technology, when forming the disaster prevention roof tile by the upper and lower molds, the engaging convex part including the insertion space is formed integrally with the tile body, and the difference is caused during the press molding. The press-molding portion is advanced into the insertion space to eliminate the raw material of the insertion space, and the hook-shaped engagement convex portion is formed to manufacture a disaster prevention tile satisfying three functions.

In the present invention, at the time of installation, the crosspiece (7) of one disaster prevention roof tile (1) and the insertion part (8) of the other disaster prevention roof tile (1) which are adjacent in the horizontal direction at the same stage are superposed. In the flat plate-shaped disaster prevention tile in which the engagement convex part (16) of the disaster prevention roof tile (1D) and the engagement insertion part (17) of the upper disaster prevention roof tile (1U) are engaged,
The engaging projection (16)
A: It is integrally provided on the upper surface of the water return (6) provided higher than the surface of the tile body (2) in front of the bottom (4).
Lee: It does n’t protrude beyond the back (4)
C: Consists of an upright part (18) and a horizontal part (19) that bends from the upper end of the upright part (18) in a direction opposite to the upper engaging insertion part (17).
D: The lateral sides of the base end of the upright part (18) and the front side of the flow direction are joined to the upper surface of the water return (6), and the rear side of the base part of the upright part (18) in the flow direction The side is located at the approximate trailing edge of the water return (6)
E: The entire lower surface of the horizontal portion (19) is opposed to the upper surface of the water return (6), and an insertion space (20) is formed therebetween.

According to the disaster prevention tile according to the present invention, the engagement convex portion (16) of the lower disaster prevention tile (1D) and the engagement insertion portion (17) of the upper disaster prevention tile (1U) are engaged with each other at the time of installation. Therefore, the wind-resistant function (1st function) with respect to a strong wind etc. is expressed, and the disaster prevention roof tile (1) can be prevented from floating. Further, the engaging convex part (16) is integrally provided on the upper surface of the water return (6) provided higher than the surface of the tile main body (2) in front of the butt (4). 18) and the front edge of the lateral both sides and flow direction base end of the of that bound to the upper surface of the water flashing (6). In addition, the engaging projection (16), Lee: than the ass (4) have a protrude toward the rear. Further, the engaging convex portion (16) is integrally provided on the upper surface of the water return (6) provided higher than the surface of the tile main body (2) in front of the butt (4). Since the entire lower surface of 19) faces the upper surface of the water return (6) and the insertion space (20) is formed between them, the cross-sectional area can be increased by increasing the width in the flow direction.

  Further, the engaging convex part (16) is integrally provided on the upper surface of the water return (6) provided higher than the surface of the tile main body (2) in front of the butt (4). 18) Both sides of the base end in the horizontal direction and the front side in the flow direction are connected to the upper surface of the water return (6), and E: The entire lower surface of the horizontal portion (19) is the upper surface of the water return (6). Since the insertion space (20) is formed between them, the water return 6 also exists in the place facing the entire lower surface of the horizontal part (19), blocking intruding rainwater and waterproofing performance (second function) ) Can be fully demonstrated.

  In addition, the engaging convex portion (16) includes: a horizontal portion (bending in a direction facing the engaging insertion portion (17) on the upper stage when erected from the upper end (18) and the upper end of the rising portion (18). 19) O: The entire lower surface of the horizontal part (19) faces the upper surface of the water return (6) and forms an insertion space (20) between them. The flow direction position of the upper disaster prevention tile (1U) can be adjusted by a predetermined amount, so that the work length of the tile, which is the third function, can be adjusted while maintaining the connected state of the upper and lower tiles. Can be achieved. Therefore, according to the present invention, the wind resistance performance, waterproof performance, and work length adjustment function, which are the first, second, and third functions, are all satisfied, and it has a very practical value as a disaster prevention tile.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In the basic configuration of the flat disaster prevention tile 1 having wind resistance function according to the present invention, as shown in FIG. As shown in FIGS. 1, 2, and 3, the short end portion (front and rear sides in FIG. 1) of the roof tile body 2 is formed with the head 3 and the buttocks 4, respectively, and the drooping 5 protrudes from the lower end of the head 3. In addition, on the surface of the tile body 2, a single water return 6 is provided in front of the bottom 4 in the transverse direction of the tile body 2. Note that the clear shape of the sag 5 is shown in FIG. 3, and is simplified in other drawings.

  The water return 6 provided on the above-described bottom 4 is slightly different in shape in the first embodiment of FIGS. 1 to 7 and in the second embodiment of FIG. And it is decisively different. That is, in the prior art 1, in order to form the locking projection i, the tail notch h must be formed in the water return j, but in the first and second embodiments of the present invention, The engagement protrusion 16 is formed integrally on the water return 6 (part of the flat terrace 6b), and the shape of the water return 6 in the vicinity of the formation of the engagement protrusion 16 is exactly the same as its surroundings. That is, it is not provided with a notch or is not cut, and is formed in a uniform flat terrace shape or a jetty shape, and these are referred to as a solid shape water return 6 in the present invention.

  Moreover, the long one end part (right side in FIG. 1) of the roof tile body 2 is formed as a lower notch bar 7 and a strip is provided on the other end edge part (left side in FIG. 1) with a step on the lower side. And is formed as an insertion portion 8. The insertion portion 8 has a length from the bottom 4 to the vicinity of the head 3 and a width of overlap with the crosspiece 7 of the roof tile body 2, along the long end of the surface and the end on the bottom 4 side. A bowl-shaped water return 9 is provided, and a water return protrusion 10 is provided in the center of the surface in the length direction of the insertion portion 8. In addition, the front-end | tip part of the insertion part 8 and the front-end | tip part of the water return 9 in the insertion part 8 are not a clear shape by the relationship which forms the droop 5, or a level | step difference is reduced gradually, or one part Is omitted.

  Moreover, water return 11, 11a and terraces 12, 12a are respectively provided in the flow direction in the both ends of the surface of the tile body 2 in succession to the tail 4 so that water does not leak during the joining. If so, the terraces 12 and 12a may be omitted. Further, V-shaped recesses 13 and 13a are provided on the surface of both ends of the water return 6 of the butt 4 and convex portions 14 and 14a are provided at corresponding positions on the back surface, and nail holes 15 and 15a are provided in the vicinity of the water return 6 and the recess 13. Is provided.

  In the disaster prevention tile 1 having such a basic configuration, as shown in FIGS. 1 to 6, the engagement convex portion 16 and the engagement insertion portion 17 as the component requirements of the wind resistance function are arranged near the center of the top surface of the water return 6 of the bottom 4. And are provided at the side end portions of the insertion portion 8, respectively. That is, as shown in FIGS. 1 and 3, in the vicinity of the center of the water return 6 provided on the butt 4 (other than the portion where the recess 13 is formed), the water return 6 has a planar terrace shape. More specifically, a water return 6 is formed by an inclined surface 6a rising from the center of the roof tile 2 toward the tail 4 and a flat terrace 6b having a predetermined width in the flow direction, and the inclined surface 6a is substantially formed. It consists of water return 6. As shown in FIGS. 2, 5, and 6, the upright part 18 and the horizontal part 19 on one side (the cross 7 side) are connected to the vicinity of the center of the upper surface of the flat terrace 6 b in the water return 6, and the lower part of the horizontal part 19 A hook-like engagement convex portion 16 having an insertion space 20 into which the engagement insertion portion 17 can be inserted from one side (the crosspiece 7 side) protrudes (between the upper surface of the water return 6 and the lower surface of the horizontal portion 19). It is provided in the shape. Since the flat terrace 6b is wider in the flow direction than the water return 6 at both ends, the engaging projection 16 is also formed wider in the flow direction than the water return 6. ing.

  On the other hand, as shown in FIGS. 1, 5, and 6, a part near the tip of the water return 9 provided at the side end of the insertion portion 8 is bent inward, and the flow direction is outside the bent portion 21. Is provided with a band-plate-shaped engagement insertion portion 17 having a predetermined length. The shape of the bent portion 21 of the water return 9 is inwardly inclined, flowing direction, outwardly inclined from the bottom 4 to the head 3, and the bent portion 21 is generally “]” bracketed, and is raised and lowered. The water inclined portions are formed as upper and lower locking portions 22 and 22a, respectively. In other words, the upper and lower locking portions 22 and 22a regulate the length of the engagement insertion portion 17 having a predetermined length in the flow direction.

  FIG. 8 is a plan view showing the disaster prevention roof tile 1 of the second embodiment, and the major difference from the first embodiment of FIGS. 1 to 6 is the structure of the water return 6 provided on the bottom 4 side. That is, the water return 6 of the second embodiment is provided in a straight line with substantially the same width on the bottom 4 side, and the shape near the center of the water return 6 is a solid jetty as compared with that of the prior art 1, and this is applied. The point which formed the engagement convex part 16 on the jetty is different from the thing of 1st Example.

  Next, the operation of the disaster prevention tile according to the present invention will be described. As shown in FIG. 4, when a large number of disaster prevention tiles 1 are installed in a staggered manner, the head 3 of the upper disaster prevention tile 1U partially overlaps on the bottom 4 of the lower disaster prevention tile 1D, and at each stage The adjacent disaster prevention tiles 1D1 and 1D2 are superposed with the insertion portion 8 inserted into the lower notch portion of the crosspiece 7, and the terraces 12 and 12a of both are also adjacent to each other.

  As shown in FIGS. 5 and 6, the lower-stage disaster prevention tiles 16 </ b> U and 1 </ b> D of the upper and lower-stage disaster prevention roof tiles 1 </ b> U and 1 </ b> D are engaged with the engagement protrusions 16 and the engagement plugs 17. By inserting the engagement insertion portion 17 of the upper disaster prevention roof tile 1U from the side into the insertion space 20 of the engagement convex portion 16 of the roof tile 1D, both are engaged and the vertical positional relationship is restricted.

  Further, in the engagement between the engagement convex portion 16 and the engagement insertion portion 17, the engagement insertion portion 17 has a predetermined length, so that the engagement position in the flow direction can be adjusted. Further, even if the positional relationship in the flow direction between the engagement convex portion 16 and the engagement insertion portion 17 can be adjusted, there are upper and lower locking portions 22 and 22a at the upper and lower positions in the flow direction of the engagement insertion portion 17, respectively. However, since the engagement convex portion 16 is freely abuttable, the adjustment amount is limited, but the engagement state in the flow direction is ensured without detachment.

  In addition, at the junction of the disaster prevention tiles 1D1 and 1D2 that are adjacent to each other in the horizontal direction, rainwater that has flowed from the gaps between the junctions of the water return 11 and 11a and the terraces 12 and 12a flows into the plug 8 To do. Even if the amount of rainwater is large and the flowing water speed is high, it is decelerated by the water return ridge 10 protruding from the center of the insertion portion 8 and is stopped by the water return 9 on the side edge, and flows to the head 3 side. Then, a part of the flowing water on the insertion portion 8 is guided by the engaging portion 22 above the bent portion 21 continuous with the water return 9 and smoothly flows downward at the place where the engagement insertion portion 17 is formed. .

  Corresponding to the locations where the water return 11, 11a and terraces 12, 12a are formed, the rear surface of the disaster prevention roof tile 1 is provided with a notch recess 23 at a position corresponding to the mating to improve healing.

  Next, the packing polymerization state of the plurality of disaster prevention tiles 1 will be described. As shown in FIG. 7, when the plurality of disaster prevention roof tiles 1 are overlapped at the same position in the packaged state, the engaging convex portion 16 is in an upward projecting state on the surface side. Since the planar terrace 6b to be formed is higher than the roof tile body 2 through the step of the inclined surface 6a, the lower side of the planar terrace 6b is a storage notch 24 of the engaging convex portion 16.

  Next, regarding the decisive difference between the present invention and the prior art 1 (whether there is a butt cut portion), the reason why the configuration of the present invention is possible, that is, the molding method will be described. FIG. 9 is a cross-sectional view of a mold for pressure-molding the disaster prevention tile 1, FIG. 10 is an enlarged cross-sectional view of a mold showing the main part of the formation portion of the engagement convex portion 16, and (a) is an upper and lower mold 32, 33. (B) shows a state in which the raw material of the insertion space 20 is removed and the hook-like engagement convex portion 16 is formed, and FIG. 11 shows the concave portion of the upper mold where the engagement convex portion 16 is formed. FIG. 12 is a schematic view showing a two-stage molding state, (a) shows a raw material put into the cavity 31 of the mold 30, and (b) shows upper and lower dies 32, 33. (C) shows an intermediate state in which the press molding portion 37 is in the process of being advanced and the insertion convex portion 16 is formed with the insertion space 20, and (d) shows the insertion space 20 on the side. The state where the hook-shaped engagement convex part 16 formed in the part is formed is shown. The mold 30 is composed of upper and lower molds 32 and 33 (including side frames) that form a cavity 31 that is a raw material charging space. In the illustrated example, the lower mold 33 molds the back surface of the disaster prevention tile 1 and the upper mold 32 is disaster prevention. The entire surface including the surface of the roof tile 1 and the insertion space 20 of the engagement convex portion 16 is formed, and a partial forming die 34 for forming the insertion space 20 is disposed at a place where the engagement convex portion 16 is formed. That is, a substantially trapezoidal convex portion forming portion 35 that forms the engaging convex portion 16 including the insertion space 20 is cut out at a predetermined position of the upper die 32, and the lower die 33 is formed outside the convex portion forming portion 35. An extended external forming part 36 (a part of the side frame) is installed. In addition, a press molding part 37 having a shape corresponding to the insertion space 20 can be moved forward and backward in the direction of the convex part forming part 35 by a cylinder 37a on the partial forming die 34 arranged outside the external forming part 36 of the convex part forming part 35. Is arranged. Further, a concave portion 38 is formed in a part of the surface of the upper mold 32 where the convex portion forming portion 35 is formed and is located at the back of the position corresponding to the insertion space 20 facing the convex portion forming portion 35. An opening is made so that the side faces the cavity 31. That is, the concave portion 38 is formed in front of the position where the press molding portion 37 of the partial forming die 34 has advanced into the convex portion forming portion 35. Accordingly, the molding surface of the mold 30 corresponds to the upper and lower molding surfaces of the upper and lower molds 32 and 33, the inner surface of the side frame, the inner surfaces of the convex portion forming portion 35 and the concave portion 38, and the inner surface of the outer forming portion 36. The tip of the press molding part 37 in the forming die 34 also constitutes a part of the molding surface of the mold 30.

  Next, a molding method using the mold 30 having such a configuration will be described. First, as shown in FIG. 12 (b) and FIG. 10 (a), the raw material charged into the cavity 31 is subjected to vertical pressing of the upper and lower molds 32 and 33, so that the cavity 31 and the convex portion forming portion 35 (including the concave portion 38 are included). ), The engaging convex portion 16 including the roof tile body 2 and the insertion space 20 is integrally formed. Next, as shown in FIGS. 12 (c), 12 (d), and 10 (b), a part of the molding surface is obtained by operating the cylinder 37a while maintaining the press molding state by the upper and lower molds 32 and 33. The press forming part 37 of the partial forming die 34 is advanced to the convex part forming part 35, the raw material at the position of the insertion space 20 in the convex part forming part 35 is pressed out, and the upright part 18 where the insertion space 20 exists And a hook-like engagement convex portion 16 composed of the horizontal portion 19 is formed. The raw material present at the position corresponding to the insertion space 20 at the time of molding of the hook-shaped engaging convex portion 16 is the rising portion 18 in the molded product, the horizontal portion 19, and the cavity 31 in the mold 30 (of the roof tile 2). It moves to the side of the water return 6) and the concave portion 38, and the water return 6 of the roof tile body 2, the engaging convex portion 16 comprising the upright portion 18 and the horizontal portion 19 are integrally formed. Then, after partial molding of the engaging convex portion 16 having the insertion space 20, the pressing convex portion 37 is retracted, and then the upper and lower molds 32, 33 are separated vertically to complete the molding, whereby the engaging convex portion 16 is not damaged, and it is formed in a solid shape without adversely affecting the water return 6 as compared with the conventional case. As shown in FIG. 10 (b), if the most advanced position of the press molding portion 37 of the partial forming die 34 is substantially flush with the front surface side of the concave portion 38, the engagement convex portion 16 is slightly surrounded. Even if such burrs are generated, the burrs are naturally separated during drying after molding.

  In short, in each of the embodiments of the present invention, in the vicinity of the center of the top surface of the tail 4 side water return 6 of the roof tile body 2, the upright portion 18 and the horizontal portion 19 from the upright portion 18 to the crosspiece 7 side are integrally formed. The protrusion 16 is formed integrally with the water return 6, the insertion space 20 is provided between the upper surface of the water return 6 and the lower surface of the horizontal portion 19 of the engagement protrusion 16, and the engagement insertion inserted into the insertion space 20. Since the part 17 is provided outside the water return 9 of the insertion part 8, the disaster prevention tiles 1U, 1D located in the diagonally up and down direction when staggering are engaged, and wind resistance function against strong winds (first function) It is possible to prevent floating of the disaster prevention tile 1 and deviation. In addition, the bottom 4 side water return 6 of the tile body 2 provided with the engaging projections 16 is not deformed on the bottom 4 side of the tile body 2, so that the intrusion rainwater blocking and waterproof performance (second function) are sufficiently exhibited. I can do it. Further, since the engaging convex portion 16 is formed as a bowl having an insertion space 20 that can be inserted from the crosspiece 7 side, the longitudinal direction position of the upper disaster prevention roof tile 1U with respect to the lower disaster prevention roof tile 1D is a predetermined amount. By being adjustable, it is possible to facilitate the construction by adjusting the working length of the tile, which is the third function, while maintaining the connected state of the upper and lower tiles. Therefore, according to the present invention, the wind resistance performance, waterproof performance, and work length adjustment function, which are the first, second, and third functions, are all satisfied, and it has a very practical value as a disaster prevention tile.

  The disaster prevention tile 1 is formed by press molding of the upper and lower molds 32 and 33, and the engaging convex portion 16 including the insertion space 20 is integrally formed with the roof tile body 2, and is inserted into the insertion space 20 during the press molding. Since the pressing molding part 37 is advanced and the raw material of the insertion space 20 is pressed and moved to the upright part 18, the horizontal part 19 and the roof tile body 2 side, the roof tile body 2 and the hook-shaped engagement convex part 16 are integrally formed. Since the engaging projection 16 and the roof tile body 2 are integrated, the strength is not impaired, and a special shape (saddle shape) can be easily formed integrally.

  In addition, the engagement insertion portion 17 has a predetermined length in the flow direction, and upper and lower locking portions 22 and 22a are provided at the upper and lower positions in the flow direction of the engagement insertion portion 17, respectively. Even if the upper disaster prevention roof tile 1U is adjustable, the engagement convex portion 16 and the locking portions 22, 22a are in a freely contactable relationship, so that strong wind or swirl from the lower 3 side acts. Even so, the wind-proof function can be ensured without the upper disaster prevention tile 1U separating.

  Since the bottom 4 side water return 6 is provided with the planar terrace 6b via the inclined surface 6a rising from the roof tile body 2, and the engaging projection 16 is provided on the upper surface of the planar terrace 6b, the water return 6 is substantially Since the inclined surface 6a as the main part is smoothly connected to the roof tile body 2 and the flat terrace 6b, the water return 6 can be formed high to improve the waterproof performance, and the engaging convex part Since the flat terrace 6b provided with 16 can be wider than the water return 6 of the jetty, the engaging projection 16 provided on the wide flat terrace 6b can also be wide in the flow direction. The cross-sectional area of the engaging convex part 16 can be increased and the wind resistance performance which is a 1st function can be improved.

  In addition, since the lower side of the back surface of the flat terrace 6b is formed as a storage notch 24 of the engaging convex portion 16 at the time of packing, when the large number of disaster prevention tiles 1 are stacked on the packing shape, it protrudes from the surface of the flat terrace 6b. The engaging convex portion 16 is housed in the storage cutout 24 on the back surface of the flat terrace 6b, and the practical effect is very large, such as easy to carry without increasing the overall volume when packed.

It is a top view of the disaster prevention roof tile which concerns on this invention. It is a front view of FIG. It is a side view of FIG. It is a top view which shows the staggering of the disaster prevention tile. It is an enlarged plan view which shows the wind-resistant engagement part at the time of staggering. It is principal part sectional drawing of FIG. It is a figure which shows the superposed | packed package form. It is a top view of the disaster prevention roof tile of 2nd Example. It is sectional drawing of a metal mold | die. It is an expanded sectional view of the metal mold | die principal part of an engagement convex part formation location. It is a principal part expanded side view of the engagement convex part formation part in an upper mold | type. It is a schematic diagram which shows the shaping | molding state of an engagement convex part. It is a perspective view of the latching wind-resistant thick flat tile of prior art 1. FIG. FIG. 14 is a plan view of the roof tiles of FIG. FIG. 15 is a perspective view of a main part of the kneading in FIG. 14. FIG. 15 is a cross-sectional view taken along line AA in FIG. 14. It is a perspective view of the wind-resistant thick flat tile of the prior art 2. FIG. FIG. 18 is a perspective view of main parts of the roof tile of FIG. 17.

Explanation of symbols

2 Tile body 4 Butt 6 Water return
6a Inclined surface
6b Planar terrace 7 Pier 8 Insert 9 Water return
16 Engaging projection
17 Engagement plug
18 Upright
19 Horizontal section
20 Plug-in space
22, 22a Locking part
24 storage cutout
32 Upper mold
33 Lower mold
37 Press forming part

Claims (1)

At the time of installation, the crossing (7) of one disaster prevention tile (1) and the insertion part (8) of the other disaster prevention tile (1) that are adjacent in the horizontal direction at the same stage are polymerized, and the disaster prevention tile ( In the flat disaster prevention roof tile in which the engagement protrusion (16) of 1D) and the engagement insertion section (17) of the upper disaster prevention roof tile (1U) are engaged,
The engaging projection (16)
A: It is integrally provided on the upper surface of the water return (6) provided higher than the surface of the tile body (2) in front of the bottom (4).
Lee: It does n’t protrude beyond the back (4)
C: Consists of an upright part (18) and a horizontal part (19) that bends from the upper end of the upright part (18) in a direction opposite to the upper engaging insertion part (17).
D: The lateral sides of the base end of the upright part (18) and the front side of the flow direction are joined to the upper surface of the water return (6), and the rear side of the base part of the upright part (18) in the flow direction The side is located at the approximate trailing edge of the water return (6)
E: The disaster prevention tile characterized in that the entire lower surface of the horizontal portion (19) faces the upper surface of the water return (6) to form an insertion space (20) therebetween.

Images