KR20070109021A - Water-proof connection structure for metal shingle - Google Patents

Abstract

A water-proof connection structure of a metal shingle is provided to preclude a female projection from being removed from a male projection, and to prevent the metal shingle from being removed from a roof. One of two metal shingles(1,21) is integrated by bending a male projection(3) to an edge of a horizontal direction of a roof plate body(2). The other of the metal shingles is integrated by folding a female projection(23) to an edge of horizontal direction of a roof plate body(22). A lifting up side wall part(4), an upper wall part(5), and a lifting down side wall part(6) are integrated. An attachment part(7) is connected to the outside of the horizontal direction from the lifting down side wall part. A lifting up side wall part(26), an upper wall part(25), and a lifting down side wall part are integrated. A lower curved surface projection inner fitted part(8), an inner curved surface recessed part, and an upper curved surface projection inner fitting part(10) are integrated. An upper curved surface projection outer fitting part(30), an outer curved surface recessed part, and a lower curved surface projection outer fitted part(28) are integrated. A back pressure room(11) of the rainfall infiltration prevention is formed between outer and inner curved surface recessed parts(29,9). A lower end part(11a) and an upper end part(11b) of the room are closed.

Description

WATER-PROOF CONNECTION STRUCTURE FOR METAL SHINGLE}

Figure 1 shows a first embodiment of the waterproof connection structure of the metal roof plate of the present invention, Figure 1 (a) is a perspective view of the main portion taken out of the waterproof connection structure of the metal roof plate, AA cross-sectional perspective view of Figure 2, FIG. 1B is an enlarged view of part B of FIG. 1A, and FIG. 1C is an enlarged view of part C of FIG. 1A.

2 is a perspective view of a part of a building roof showing a state of use of the metal shingles.

Fig. 3 is a longitudinal sectional front view of an essential part showing a second embodiment of the waterproof connection structure of the metal roof plate of the present invention, which corresponds to Fig. 1 (b).

Fig. 4 is a longitudinal sectional front view of an essential part showing the third embodiment of the waterproof connection structure of the metal roof plate of the present invention, which corresponds to Fig. 1 (b).

FIG. 5 is a longitudinal front view of a main part of the waterproof connection structure of the metal roof plate of the prior art, and corresponds to FIG. 1 (b).

<Description of the code | symbol about the principal part of drawing>

One… Metal shingles, 2... Shingles body,

3... Male stone masonry, 4... Rising Side Wall,

5... Upper wall portion, 6.. Lower Wall,

7... . Attachment portion, 8.. Lower curved protrusion inner fitting portion,

9... .. inner surface curved recess, 10.. Upper curved protrusion inner fitting portion,

11... Back pressure chamber, 11a... The lower end of the thread,

11b... Seal upper end 13... Upper curved protrusion inner fitting part,

14... .. inner surface curved recess, 15.. Lower curved protrusion inner fitting part,

19... Water gutter, 21... Metal shingles,

22... Roof plate body, 23... Female Relief,

24... Descending side wall portion, 25.. Upper Wall,

26... Rising side wall portion 27... Drip gutter,

28... Sub-curved outward fitting,

29... Outer curved recess, 30.. Upper curved protrusion outer fitting part,

33... Upper curved protrusion outer fitting part,

34... Outer curved recess, 35.. Sub-curved outward fitting,

36... Back pressure chamber, 36a... The bottom of the thread,

36b... Thread top

L1... Width dimension between upper coupling parts,

L2... Width between sub-joints,

H1... Height dimension between upper coupling part-curved recesses,

H2... Height dimension between subjoint and curved recesses.

The present invention relates to a waterproof connection structure of a metal roof board.

The waterproof connection structure of the metal roof board of the present invention is intended to have the following premise configuration as shown in FIG. 1 (invention) or FIG. 5 (prior art), for example.

BRIEF DESCRIPTION OF THE DRAWINGS The 1st Embodiment of the waterproof connection structure of the metal roof board of this invention is shown, FIG. 1 (a) is a principal part drawing out perspective view of the principal part of the waterproof connection structure of a metal roof board, and the AA line cross section perspective view of FIG. 1 (b) is an enlarged view of portion B of FIG. 1 (a), and FIG. 1 (c) is an enlarged view of portion C of FIG. 1 (a).

Fig. 5 is a longitudinal front view of a main portion of the waterproof connection structure of the metal roof plate of the prior art, and corresponds to Fig. 1 (b).

One of the two metal roof shingles (1) and (21) parallel to the left and right of the metal shingles (1), males for waterproof and fitting connection to the horizontal outer edge of the roof shingles (2) The masonry folds are folded and bent to form one after another. On the other hand, the other metal roof plate 21 is folded and bent by a female protrusion 23 for waterproof and fitting connection to the transverse inner edge of the roof plate body 22 thereof. It is then formed.

By covering the male protrusion (3) with the female protrusion (23) from above to be fitted from the outside, the two metal roof plate (1) (21) is configured to fit and connect to each other in a waterproof shape.

The male protrusion 3 is successively continued from the outer edge of the roof plate body 2 in order, and the upward side wall portion 4 extending upward, and the upper wall portion extending horizontally outward. Section 5, and the downward side wall part 6 extending downwards are formed by following one by one. From the lower side wall portion 6, the attachment portion 7 to the roof of the building is directed outward in the horizontal direction.

The female protrusion 23 is sequentially continued from the inner edge portion of the roof plate body 22, and the upward side wall portion 26 extending upward, the upper wall portion 25 extending in the horizontal direction and the downward downward extension The side wall portion 24 is formed in one piece.

In the above-described configuration, as a specific waterproof connection structure between the male protrusion 3 and the female protrusion 23, there is one shown in Fig. 5 in the prior art (Japanese Patent Laid-Open No. 11-210177).

Fig. 5 is a longitudinal front view of a main portion of the waterproof connection structure of the metal roof plate of the prior art, and corresponds to Fig. 1 (b).

Inclined horizontally stepped portions 81 and 82 are formed at each intermediate height of the rising side wall portion 4 and the falling side wall portion 6 of the male protrusion 3. Inclined transversely downward jaw portions 83 and 84 are formed at each intermediate height of the rising side wall portion 26 and the falling side wall portion 24 of the female protrusion 23.

In a state where the female protrusion 23 is inserted from the outside into the male protrusion 3 from the outside, the upper wall 25 of the female protrusion 23 and the upper wall 5 of the male protrusion 3 are formed. The seal material 85 is clamped in between. Each jaw portion 83, 84 of the female protrusion 23 is coupled to each step 81, 82 of the male protrusion 3. Above the engaging portion of the jaw portions 83, 84 and the step portions 81, 82, intrusion of rainwater by the capillary phenomenon occurs between the male protrusion 3 and the female protrusion 23. The gaps 86 and 87 are not formed.

The prior art has the following problems.

1. During a strong wind or a storm, the rainwater is scattered on the roof plate body 2 of one metal roof plate 1 by a strong wind, and the rising side wall portion 4 of the male-shaped ledge 3 is formed. And the downward side wall part 24 of the female type protrusion 23 of the other metal roof plate 21 flow upward.

Therefore, in order to prevent the rainwater from penetrating into the roof of the building 41 through the fitting surface between the male protrusion 3 and the female protrusion 23, the seal member 85 is necessary. As a result, the parts cost and the assembly cost of the seal member 85 are increased. Moreover, the fall of durability by age-deterioration in the material surface of the seal member 85 cannot be eliminated.

2. Generally, when the other metal roof plate 21 tries to be pulled up by the negative pressure generated at the time of passage of the wind under strong wind and storm, the female type protrusion 23 is drawn by this pulling force. Temporarily escapes from the male protrusion 3 and the metal roof plate 21 may come off from the roof 42.

The act of preventing the female protrusion 23 from escaping from the male protrusion 3 is performed by the resilient restoring force of the female protrusion 23 so that the jaws 83 and 84 are moved to the step portions 81 and 82. Follow the force to join

On the other hand, the seal member 85 is a force for pushing up the female protrusion 23 against the male protrusion 3 so as to act as a negative (-), so that the female protrusion 23 is easy to escape. When the other metal roof plate 21 is pulled up by the negative pressure generated at the time of passage of the strong wind under strong wind and storm, the female protrusion 23 escapes from the male protrusion 3, and One metal roof plate 21 is likely to come off from the roof 42.

The subject of this invention is mainly as follows.

(1) Strong and long-lasting strong winds are strongly prevented from entering the building's roof through fitting surfaces of male and female projections, even under the adverse conditions of shocking and violent repetition.

(2) By eliminating the seal member in the prior art, the seal member component cost and assembly cost are reduced, and the degradation of durability due to aging deterioration in the material of the seal member is eliminated.

(3) When the other metal roof plate is about to be pulled up by the negative pressure generated at the time of strong wind passage under strong wind and storm, the female protrusion is released from the male protrusion, and this one metal roof plate is peeled off from the roof. Strongly prevent throwing away.

(4) The assembling work of fitting the female projections from the top to the male projections can be performed easily and quickly.

(5) The female protuberance further strengthens the prevention of escape from the male protuberance.

(6) Even if a small amount of rainwater invades the innermost part of the gap between the projections between the male projection and the female projection, an effective seal here prevents the rainwater from entering the building roof. To prevent that.

The waterproof connection structure of the metal roof board of the present invention is a specific waterproof connection structure of the male protrusion 3 and the female protrusion 23 in order to solve the above problems in the above-described configuration, for example, illustrated in FIG. As described above, the following feature configuration is added.

BRIEF DESCRIPTION OF THE DRAWINGS The 1st Embodiment of the waterproof connection structure of the metal roof board of this invention is shown, FIG. 1 (a) is a principal part taking-out longitudinal perspective view of the waterproof connection structure of a metal roof board, and is AA sectional perspective view of FIG. 1 (b) is an enlarged view of portion B of FIG. 1 (a), and FIG. 1 (c) is an enlarged view of portion C of FIG. 1 (a).

Claim 1  Invention, see FIG. 1

The lower side surface protruding inner fitting portion 8 which is continuous at least from the bottom side to the upward side wall portion 4 of the male protrusion 3 in order from the bottom to the inner side in the shape of a protrusion. ), The inner curved concave portion 9 in the concave shape and the upper curved projection inner joining portion 10 in the protruding shape are subsequently formed.

The descending side wall portion 24 of the female protrusion 23 is continuous at least from the top to the bottom in order, and the upper curved protrusion-outward fitting portion 30, which is protruded inward in the horizontal direction, becomes outer in shape. The curved concave portion 29 and the lower curved protrusion-outward fitting portion 28 that is formed in a protruding shape are subsequently formed as one.

By the elastic restoring force of the female protrusion 23, the upper curved protrusion outer fitting portion 30 and the lower curved protrusion outer fitting portion 28 of the lower side wall portion 24 of the female protrusion 23 is The upper curved protrusion inner fitting portion 10 and the lower curved protrusion inner fitting portion 8 of the rising side wall portion 4 of the male protrusion 3 are brought into close contact with each other to be fitted.

A back pressure chamber 11 for preventing rainwater intrusion is formed between the outer curved concave portion 29 and the inner curved concave portion 9.

The lower end portion 11a of the back pressure chamber 11 is the lower curved projection outer fitting portion 28 of the lower side wall portion 24 of the female protrusion 23 and the rise of the male protrusion 3. It is closed by the close contact with the lower curved protrusion inner fitting part 8 of the side wall part 4. The upper end portion 11b of the back pressure chamber 11 includes the upper curved protrusion-outward fitting portion 30 of the lower side wall portion 24 of the female protrusion 23 and the rising side wall portion of the male protrusion 3 ( It is closed by the close contact with the upper curved protrusion inner fitting part 10 of 4).

Invention of claim 2, see FIG.

The invention of claim 2 is characterized in that the following feature configuration is added in the invention of claim 1.

The lower side wall portion 6 of the male protrusion 3 is continuously formed in order from the top to the bottom, in order from the top to the bottom, and the upper curved protrusion inner fitting portion 13, which is protruded outward in the transverse direction, the inner side being concave. The curved concave portion 14 and the lower curved protrusion inner fitting portion 15 that is projected are subsequently formed as one.

The raised side wall portion 26 of the female type protrusion 23 is continuously formed in order from at least downward to upward, and has a lower curved protrusion-outward fitting portion 35 that protrudes outward in the horizontal direction, and the outer side becomes concave. The curved concave portion 34 and the upper curved protrusion-outward fitting portion 33 which is in the form of a protrusion are subsequently formed as one.

By the elastic restoring force of the female protrusion 23, the upper curved projection outer fitting portion 33 and the lower curved projection outer fitting portion 35 of the rising side wall portion 26 of the female protrusion 23 is The upper curved protrusion inner fitting portion 13 and the lower curved protrusion inner fitting portion 15 of the lower side wall portion 6 of the male protrusion 3 are brought into close contact with each other.

Rainwater intrusion prevention between the outer curved concave portion 34 of the rising side wall portion 26 of the female protrusion 23 and the inner curved concave portion 14 of the lower side wall portion 6 of the male protrusion 3 The back pressure chamber 36 is formed. The lower end portion 36a of the back pressure chamber 36 is the lower curved projection fitting portion 35 of the rising side wall portion 26 of the female protrusion 23 and the lower side wall portion 6 of the male protrusion 3. It is closed by intimate contact with the lower curved projection inner fitting portion 15. The upper end portion 36b of the back pressure chamber 36 is an upper curved protrusion-outward side fitting portion 33 of the rising side wall portion 26 of the female protrusion 23 and the lower side wall portion of the male protrusion 3 ( It is closed by close contact with the upper curved projection inner fitting portion 13 of 6).

Invention of claim 3, see FIG. 1

The invention of claim 3 is characterized in that the following feature configuration is added in the invention of claim 2.

Lower coupling portion between the lower curved protrusion inner fitting portion 8 of the rising side wall portion 4 of the male protrusion 3 and the lower curved protrusion inner fitting portion 15 of the lower side wall portion 6. The width dimension L2 between the upper and lower curved protrusion inner fitting portions 10 of the rising side wall portion 4 and the upper curved protrusion and protrusion inner fitting portions 13 of the lower side wall portion 6 are between. It was set to a value wider than the width dimension (L1) between the upper coupling portions of.

Invention of claim 4, see FIG. 1

The invention of claim 4 is characterized in that the following feature configuration is added in the invention of claim 2 or 3 above.

Each of the upper curved protrusion inner fittings formed in each of the rising side wall portions 4 and 26 and the falling downward side wall portions 6 and 24 of the male and female protrusions 3 and 23, respectively. From the sections 10 and 13 and each of the upper curved protruding outer fitting portions 20 and 33, the inner curved concave portions 9 and 14 and the respective outer curved concave portions 29 located below them. The height dimension (H1) between the upper coupling part and the curved recesses between the upper and lower ends of the upper and lower surfaces is between the inner curved recesses 9 and 14 and the outer curved recesses 29 and 34, respectively. Set to a value that is lower than the height dimension (H2) between the subcombination portion-curve recess between the subsurface protrusion inner fitting portions 8 and 15 and the subsurface protrusion outer fitting portions 28 and 35, respectively. It was.

Invention of claim 5, see FIG.

The invention of claim 5 is characterized in that the following feature configuration is added in the invention of claim 1, 2, 3 or 4.

The lower end portion 27 of the descending side wall portion 24 of the female type protrusion 23 is formed as a drip tray trough 27 by directing it to the lower side than the lower curved projection outer fitting portion 28 and then turning U inward. .

This drip trough 27 approaches or contacts the rising side wall 4 of the male protrusion 3.

Invention of claim 6, see FIGS. 1 and 4

The invention of claim 6 is characterized in that the following features are added to the invention of claim 1, 2, 3, 4 or 5.

The water end part 19 of the attachment part 7 which directs outward from the lower end part of the said male type | mold descending side wall part 6 is turned off in the horizontal direction by U-turning to the upper periphery. It is formed as a trough 19. The water blocking trough 19 is brought into close contact with the roof plate body 22 in which the female protrusion 23 is continuously formed.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of the waterproof connection structure of the metal roof board of this invention is described based on drawing.

Embodiment 1, Claims 1, 2, 3, 4, 5, 6, and FIG. 1 and FIG. 2

Fig. 1 shows Embodiment 1 of a waterproof connection structure of a metal roof plate of the present invention. Fig. 1 (a) is a perspective view of a main portion taken out of the waterproof connection structure of a metal roof plate, and is a cross-sectional perspective view taken along line AA of Fig. 2. 1 (b) is an enlarged view of portion B of FIG. 1 (a), and FIG. 1 (c) is an enlarged view of portion C of FIG. 1 (a). 2 is a partial perspective view of a building roof showing a state of use of the metal shingles.

In Fig. 2, reference numeral 41 denotes a building such as a gymnasium, a factory, or a house, and 42 denotes a roof of the building. 1 and 21 are metal roof boards, 2 and 22 are roof board bodies, 3 are male protrusions, and 23 are female protrusions.

The waterproof connection structure between the metal roof boards (1) and (21) is constructed as follows as shown in FIG.

As shown in Fig. 1 (a), each metal roof plate (1) (21) has a male-shaped protrusion on the horizontal outer edge (right edge) of the roof plate body (2) (22), respectively. (3) (3) are formed, and female protrusions 23 and 23 are formed in the transverse inner edge portion (left edge portion).

As shown in Fig. 1 (b), one of the two metal roof boards 1 and 21 parallel to the left and right sides of the metal roof board 1 is in the transverse direction of the roof plate body 2 thereof. The male type projections 3 for waterproof and fit connection are folded and bent at one edge to form one after the other. On the other hand, the metal roof plate 21 of the other side is formed by folding and bending the female type protrusion 23 for waterproof and fitting connection to the inner side edge part of this roof plate main body 22 at one side.

By covering the male protrusion (3) with the female protrusion (23) from above to be fitted from the outside, the two metal roof plates (1) (21) are configured to fit and connect to each other in a waterproof shape.

The male protrusion 3 is sequentially formed from the outer edge portion of the roof plate body 2 so that the upward side wall portion 4 extending upward, and the upper wall portion 5 having a circular cross section extending outward in the horizontal direction. ) And the downward side wall portion 6 extending downwards is formed in one. The attachment portion 7 is directed from the descending side wall portion 6 to the roof 44 of the building 41 in the transverse direction outward. This attachment portion 7 is fixed to the roof 42 of the building 41 with a screw nail 3.

The female protrusion 23 is sequentially formed from an inner edge portion of the roof plate body 22, and an upward side wall portion 26 extending upwardly and an upper wall portion 25 having an arcuate cross section extending in the horizontal direction. And a downward side wall portion 24 extending downward in one.

The raised side wall portion 4 of the male protrusion 3 is successively arranged in order from bottom to top, and the lower curved protrusion inner fitting portion 8, which is protruded in the horizontal direction, and the inner curved surface which is concave. The concave portion 9 and the upper curved projection inner fitting portion 10, which are projected, are subsequently formed as one.

The descending side wall portion 24 of the female protrusion 23 is successively arranged in order from top to bottom, and the upper curved protrusion-outward fitting portion 30, which is protruded inward in the horizontal direction, the outer curved surface which is concave. The concave portion 29 and the lower curved projection outer fitting portion 28, which is in the form of a protrusion, are subsequently formed as one.

By the elastic restoring force of the female protrusion 23, the upper curved protrusion outer fitting portion 30 and the lower curved protrusion outer fitting portion 28 of the lower side wall portion 24 of the female protrusion 23 is The upper curved protrusion inner fitting portion 10 and the lower curved protrusion inner fitting portion 8 of the rising side wall portion 4 of the male protrusion 3 are brought into close contact with each other to be fitted.

A back pressure chamber 11 for preventing rainwater intrusion is formed between the outer curved concave portion 29 and the inner curved concave portion 9.

The lower end portion 11a of the back pressure chamber 11 includes the lower curved protrusion outer fitting portion 28 of the lower side wall portion 24 of the female protrusion 23 and the rising side wall portion of the male protrusion 3 ( It is closed by the close contact with the lower curved protrusion inner fitting part 8 of 4). The upper end portion 11b of the back pressure chamber 11 includes the upper curved protrusion-outward fitting portion 30 of the lower side wall portion 24 of the female protrusion 23 and the rising side wall portion of the male protrusion 3 ( It is closed by the close contact with the upper curved protrusion inner fitting part 10 of 4).

The lower side wall portion 6 of the male protrusion 3 is continuously formed in order from the top to the bottom, in order from the top to the bottom, and the upper curved protrusion inner fitting portion 13, which is protruded outward in the transverse direction, the inner side being concave. The curved concave portion 14 and the lower curved protrusion inner fitting portion 15 that is projected are subsequently formed as one.

The raised side wall portion 26 of the female type protrusion 23 is continuously formed in order from at least downward to upward, and has a lower curved protrusion-outward fitting portion 35 that protrudes outward in the horizontal direction, and the outer side becomes concave. The curved concave portion 34 and the upper curved protrusion-outward fitting portion 33 which is in the form of a protrusion are subsequently formed as one.

By the elastic restoring force of the female protrusion 23, the upper curved projection outer fitting portion 33 and the lower curved projection outer fitting portion 35 of the rising side wall portion 26 of the female protrusion 23 is The upper curved protrusion inner fitting portion 13 and the lower curved protrusion inner fitting portion 15 of the lower side wall portion 6 of the male protrusion 3 are brought into close contact with each other.

Rainwater intrusion prevention between the outer curved concave portion 34 of the rising side wall portion 26 of the female protrusion 23 and the inner curved concave portion 14 of the lower side wall portion 6 of the male protrusion 3 The back pressure chamber 36 is formed. The lower end portion 36a of the back pressure chamber 36 is a lower curved protrusion fitting outer portion 35 of the rising side wall portion 26 of the female protrusion 23 and a lower side wall portion 6 of the male protrusion 3. It is closed by intimate contact with the lower curved projection inner fitting portion 15. The upper end portion 36b of the back pressure chamber 36 is the upper curved projection outer fitting portion 33 of the rising side wall portion 26 of the female type protrusion 23 and the lower side wall portion 6 of the male type protrusion 3. ) Is closed by intimate contact with the upper curved projection inner fitting portion 13.

Lower coupling portion between the lower curved protrusion inner fitting portion 8 of the rising side wall portion 4 of the male protrusion 3 and the lower curved protrusion inner fitting portion 15 of the lower side wall portion 6. The width dimension L2 between the upper and upper surfaces is different between the upper curved protrusion inner fitting portion 10 of the rising side wall portion 4 and the upper curved protrusion inner fitting portion 13 of the lower side wall portion 6. The coupling portion was set to a value wider than the width dimension L1.

It was formed in each of the rising side wall portions 4 and 26 and the falling side wall portions 6 and 24 of the male and female protrusions 3 and 23, respectively. (10) (13) and each of the upper curved projections 20 and 33, respectively, the inner curved recesses 9 and 14 and the outer curved recesses 29 located below them. The height dimension (H1) between the upper coupling part-curve recessed part between up to 34 is from each said inner curved recessed part 9 and 14 and each outer curved recessed part 29 and 34, respectively. It was set to a value lower than the height dimension (H2) between the subcombination-curved recesses between the protruding inner fitting portions 8 and 15 and each of the lower curved protrusion fitting outer fitting portions 28 and 35.

The lower end portion 27 of the descending side wall portion 24 of the female type protrusion 23 is formed as a drip tray trough 27 by directing it to the lower side than the lower curved protrusion outer fitting portion 28 and then turning U inward. . This drip trough 27 approaches or contacts the rising side wall 4 of the male protrusion 3.

A water blocking trough 19 of the attachment portion 7, which is directed toward the other side from the lower end portion of the male-shaped protrusion descending side wall portion 6, is opened in the horizontal direction by U-turning around the upper portion. To form). The water blocking trough 19 is brought into close contact with the roof plate body 22 in which the female protrusion 23 is continuously formed.

Embodiment 2, Claims 1, 2, 3, 4, 5, 6 and 3

Fig. 3 is a longitudinal sectional front view of an essential part showing a second embodiment of the waterproof connection structure of the metal roof plate of the present invention, which corresponds to Fig. 1 (b).

In Embodiment 2, in the configuration of Embodiment 1, a part of the configuration is changed as follows.

The bent cross-sectional shapes of the upper wall portion 5 of the male protrusion 3 and the upper wall portion 25 of the female protrusion 23 are shown in FIG. 3 from the cross-sectional upward projecting arc shape shown in FIG. It is changed into the cross-sectional sentence shape.

Embodiment 3, Claims 1, 2, 3, 4, 5, 6 and 4

Fig. 4 is a longitudinal sectional front view of an essential part showing the third embodiment of the waterproof connection structure of the metal roof plate of the present invention, which corresponds to Fig. 1 (b).

In Embodiment 3, in the configuration of Embodiment 1, a part of the configuration is changed as follows.

Each bent cross-sectional shape of the upper wall portion 5 of the male protrusion 3 and the upper wall portion 25 of the female protrusion 23 is shown in FIG. 4 from the cross-sectional upward projecting arc shape shown in FIG. It is changed into the cross-sectional mountain shape.

The waterproof connection structure of the metal shingles of the core of the present invention is suitable for the waterproof connection structure of the metal shingles used in buildings such as gymnasiums, factories, or houses.

The waterproof connection structure of the metal roof board of the present invention has the following effects.

Invention of claim 1, see FIG. 1

(Effect 1) Even under a bad condition in which strong and long-lasting strong winds blow rapidly and violently, the room pressure P1 in the back pressure chamber 11 rapidly rises due to the intrusion of a small amount of rain water, and thus the lower close contact portion ( Since it is strongly prevented from intrusion of further rainwater into the back pressure chamber 11 from 37), the rainwater passes between the fitting surface between the male ridge 3 and the female ridge 23 and the roof of the building 41. (42) Strongly prevents intrusion into.

The invention of claim 1 has the following feature configuration.

The raised side wall portion 4 of the male protrusion 3 is a lower curved protrusion inner fitting portion 8 that is continuous at least from bottom to top in order, and becomes protruding in the horizontal direction and becomes concave. The inner curved concave portion 9 and the upper curved projection inner fitting portion 10 that is projected are subsequently formed as one.

The descending side wall portion 24 of the female protrusion 23 is continuous at least from the top to the bottom in order, and the upper curved protrusion-outward fitting portion 30, which is protruded inward in the horizontal direction, becomes outer in shape. The curved concave portion 29 and the lower curved protrusion-outward fitting portion 28 that is formed in a protruding shape are subsequently formed as one.

By the elastic restoring force of the female protrusion 23, the upper curved protrusion outer fitting portion 30 and the lower curved protrusion outer fitting portion 28 of the lower side wall portion 24 of the female protrusion 23 is The upper curved protrusion inner fitting portion 10 and the lower curved protrusion inner fitting portion 8 of the rising side wall portion 4 of the male protrusion 3 are brought into close contact with each other to be fitted.

A back pressure chamber 11 for preventing rainwater intrusion is formed between the outer curved concave portion 29 and the inner curved concave portion 9.

The lower end portion 11a of the back pressure chamber 11 includes the lower curved protrusion outer fitting portion 28 of the lower side wall portion 24 of the female protrusion 23 and the rising side wall portion of the male protrusion 3 ( It is closed by the close contact with the lower curved protrusion inner fitting part 8 of 4). The upper end portion 11b of the back pressure chamber 11 includes the upper curved protrusion-outward fitting portion 30 of the lower side wall portion 24 of the female protrusion 23 and the rising side wall portion of the male protrusion 3 ( It is closed by the close contact with the upper curved protrusion inner fitting part 10 of 4).

From this characteristic configuration, it works as follows.

In the case of strong wind and storm, the rainwater is blown over the roof plate body 2 of one metal roof plate 1 by a strong wind, and the rising side wall part 4 of the male-shaped ledge 3 and the other metal roof plate It is going to flow upward between the falling-side wall part 24 of the female-shaped protrusion 23 of (21).

The rainwater which is about to flow upward is almost blocked by the lower curved contact inner contact portion 8 and the lower curved contact outer contact portion 28 by close contact with the lower curved contact inner engagement portion 8.

When the strong wind is strong and lasts for a long time, the strong winds of the strong wind are repeated, so that the rainwater may tear off the sealing portion of the lower close contact portion 37 and invade the back pressure chamber 11.

However, the back pressure chamber 11 formed relatively narrowly compresses the indoor air layer compared to the intrusion amount of the extremely small amount of rain water, and the indoor air is combined with the upper curved projection inner fitting portion 10 and the upper curved projection outer fitting portion 30. ) Is almost sealed by this upper close contact portion 38 by the close contact, so that the room pressure Pl of the back pressure chamber 11 rapidly rises in pressure.

This rapidly rising room pressure P1 acts as a force for pushing the rainwater invading into the back pressure chamber 11 from the lower close contact portion 37 to the atmosphere side, and thus back pressure from the lower close contact portion 37. Rainwater is more strongly prevented from entering the seal 11.

As a result, even in a bad condition in which strong, long-lasting strong winds blow shockingly and repeatedly, the room pressure P1 in the back pressure chamber 11 rapidly rises due to the intrusion of a very small amount of rain water, and thus the lower close contact portion ( Since it is strongly prevented from intrusion of further rainwater into the back pressure chamber 11 from 37), the rainwater passes between the fitting surface between the male ridge 3 and the female ridge 23 and the roof of the building 41. (42) It can be strongly prevented to break in.

(Effect 2) The structure for maintaining the high room pressure P1 of the back pressure chamber 11 is abbreviate | omitted the seal member 85 in a prior art, and the components cost and assembly cost of this seal member 85 are reduced. In addition, the degradation of durability due to aging deterioration in the material surface of the seal member 85 is eliminated.

When the room pressure P1 of the back pressure chamber 11 rapidly rises in pressure due to the intrusion of a small amount of rain water, the rising side wall portion of the male protrusion 3 is used as a configuration for sealing and maintaining the pressure of the indoor air. 4) is formed by close contact with the lower curved projection inner fitting portion 8 formed bent at the lower curved projection inner fitting portion 8 formed at the lower side wall portion 24 of the female protrusion 23. The seal member 85 in the prior art shown in FIG. 5 can be omitted.

Thereby, the component cost and assembly cost of this seal member 85 can be reduced. Moreover, the fall of durability by the aged deterioration in the material surface of the seal member 85 can also be eliminated.

(Effect 3) The fitting engagement force of the close contact between the upper curved protrusion outer fitting portion 30 and the upper curved protrusion inner fitting portion 10 means that the female protrusion 23 exits from the male protrusion 3. When the other metal roof plate 21 tries to be lifted up by the negative pressure generated during the passage of strong winds under strong winds and storms, so that it acts as a plus (plus) as an extra stop. The female protrusion 23 can be pulled out of the male protrusion 3 and the metal roof plate 21 can be strongly prevented from being peeled off from the roof 42.

Generally, when the other metal roof plate 21 tries to be pulled up by the negative pressure which arises at the time of the wind passage under a strong wind and a storm, the female protrusion 23 is a male protrusion 3 by this pulling force. ), The metal roof plate 21 may come off from the roof 42.

In the invention of claim 1, the action of preventing the female protrusion 23 from escaping from the male protrusion 3 is additional to the following [protrusion prohibition structure 1] in addition to the [protrusion prohibition structure 2]. As it acts, the escape prevention force of the female protrusion 23 is strengthened, and the escape can be strongly prevented.

[Protrusion Shape Prohibited Structure 1] Lower Curved Projection of Lower Side Wall 24 of Female Protruding 23 The outer fitting engagement portion 28 protrudes from the lower side of the raised side wall 4 of the male protrusion 3; The inner fitting portion 8 is brought into close contact with each other so as to be fitted.

[Protrusion-Shaped Prohibition Structure 2] The upper curved projection 30 of the lower side wall portion 24 of the female protrusion 23 is the upper curved surface of the rising side wall portion 4 of the male protrusion 3. The inner protruding portion 10 is brought into close contact with each other so as to be fitted.

The fitting force of the close contact between the upper curved projection outer fitting portion 30 and the upper curved projection inner fitting portion 10 of the [projection-extraction prohibition structure 2] is the “back pressure chamber 11 described in the above (Effect 1). ) To prevent the female type protrusions 23 from escaping from the male type protrusions 3 in addition to the action of maintaining the pressure of the room pressure P1 that has risen in pressure. Engagement locking force ”as a positive force. That is, as a force for pushing up the female protrusion 23 against the male protrusion 3, the seal member 85 of the prior art shown in FIG. It is the opposite of the case of negative action.

Therefore, the fitting engagement force of the close contact between the upper curved protrusion outer fitting portion 30 and the upper curved protrusion inner fitting portion 10 means that the female protrusion 23 escapes from the male protrusion 3. When the other metal roof plate 21 is about to be pulled up by the negative pressure generated during the passage of strong winds under strong winds and storms, the female type protrusion ( 23 can escape from the male ridge 3, and this one metal roof plate 21 can be strongly prevented from peeling off from the roof 42. As shown in FIG.

Invention of claim 2, see FIG.

The invention of claim 2 exhibits the following effects in addition to (effect 1), (effect 2) and (effect 3) of the invention of claim 1.

(Effect 4) (Effect 1) of the invention of claim 1 strongly preventing the ingress of rainwater into the building roof, (Effect 2) the omission of the seal member 85 of the prior art and (Effect 3) Reinforcing the prevention of the escape from the male protrusion 3 of the female protrusion 23 is further strengthened.

The invention of claim 2 has the following feature configuration.

In the descending side wall portion 6 of the male protrusion 3, the upper curved protrusion inner fitting portion 13, which is continuous at least from top to bottom and sequentially protruding outward in the horizontal direction, becomes concave. The inner curved concave portion 14 and the lower curved protrusion inner fitting portion 15 that are projected are subsequently formed as one.

The raised side wall portion 26 of the female protrusion 23 is formed in a concave shape with a lower curved protrusion-outward fitting portion 35 that is continuous at least from bottom to top and sequentially protrudes outward in the horizontal direction. The outer curved recessed portion 34 and the upper curved protrusion-outward fitting portion 33 which is in the form of a protrusion are subsequently formed as one.

By the elastic restoring force of the female protrusion 23, the upper curved projection outer fitting portion 33 and the lower curved projection outer fitting portion 35 of the rising side wall portion 26 of the female protrusion 23 is The upper curved protrusion inner fitting portion 13 and the lower curved protrusion inner fitting portion 15 of the lower side wall portion 6 of the male protrusion 3 are brought into close contact with each other.

Rainwater intrusion prevention between the outer curved concave portion 34 of the rising side wall portion 26 of the female protrusion 23 and the inner curved concave portion 14 of the lower side wall portion 6 of the male protrusion 3 The back pressure chamber 36 is formed. The lower end portion 36a of the back pressure chamber 36 is a lower curved protrusion fitting portion 35 of the rising side wall portion 26 of the female protrusion 23 and a lower side wall portion 6 of the male protrusion 3. It is closed by intimate contact with the lower curved projection inner fitting portion 15. The upper end portion 36b of the back pressure chamber 36 is the upper curved projection outer fitting portion 33 of the rising side wall portion 26 of the female protrusion 23 and the lower side wall portion 26 of the male protrusion 3. ) Is closed by intimate contact with the upper curved projection inner fitting portion 13.

From this characteristic configuration, it works as follows.

In the invention of claim 2, the upper curved projection outer fitting portion 33, the lower curved projection outer fitting portion 35, and the male protrusion 3 of the rising side wall portion 26 of the female protrusion 23 are formed. The configuration of the upper curved projection inner fitting portion 13, the lower curved projection inner fitting portion 15, and the back pressure chamber 36 for preventing rainwater penetration is the female type of the invention of claim 1 above. The upper curved projection outward fitting portion 30 of the lower side wall portion 24 of the protrusion 23, the lower curved projection outer fitting portion 28, the upper curved surface of the rising side wall portion 4 of the male protrusion (3) Compared with the configuration of the protruding inner fitting portion 10, the lower curved protrusion inner fitting portion 8, and the back pressure chamber 11 for preventing rainwater intrusion, they are similarly configured and function similarly.

For this reason, (Effect 1) of the invention of claim 1 strongly prevents the ingress of rainwater into the building roof, (Effect 2) the omission of the seal member 85 of the prior art, and (Effect 3) (2) The invention of claim 2 can further strengthen the prevention of the escape from the male protrusion 3 of the female protrusion 23.

Invention of claim 3, see FIG. 1

The invention of claim 3 exhibits the following effects in addition to (effect 1), (effect 2), (effect 3) of the invention of claim 1 and (effect 4) of the invention of claim 2.

(Effect 4) As the width dimension L2 between the lower coupling portions is wider than the width dimension L1 between the upper coupling portions, both of the lower curved protrusion protrusion outer fitting portions 28 of the female protrusion 23 ( 35) and both upper curved projection outer fitting portions 30 and 33, both lower curved projection inner fitting portions 8 and 15 and both upper curved projection inner fitting portions of the male protrusion 3; With respect to 10) and 13, the assembling work to be fitted from above can be performed easily and quickly.

The invention of claim 3 has the following feature configuration.

Lower coupling portion between the lower curved protrusion inner fitting portion 8 of the rising side wall portion 4 of the male protrusion 3 and the lower curved protrusion inner fitting portion 15 of the lower side wall portion 6. The width dimension L2 between the upper and the upper curved protrusion inner fitting portions 10 of the rising side wall portion 4 and the upper curved protrusion inner fitting portions 13 of the lower side wall portion 6 are different between any one of them. The coupling portion was set to a value wider than the width dimension L1.

From this characteristic configuration, it works as follows.

Since the width dimension H2 between the lower coupling portions becomes a value wider than the width dimension H1 between the upper coupling portions, the lower curved projection-outward fitting portions 28 and 35 of both female protrusions 23 are formed. 2) both lower curved protrusion protrusion outer fitting portions of the female protrusion 23 are easy to pass quickly through both upper curved protrusion inner fitting portions 10 and 13 of the male protrusion 3 with light force. 28) 35 and both upper curved projection outer fitting portions 30 and 33, both lower curved projection inner fitting portions 8 and 15 and both upper curved projection inner projections of the male protrusion 3; With respect to the recessed portions 10 and 13, the assembling work to be fitted from above can be easily and quickly performed efficiently.

Invention of claim 4, see FIG. 1

The invention of claim 4 exhibits the following effects in addition to (effect 1), (effect 2), (effect 3) of the invention of claim 1 and (effect 4) of the invention of claim 2.

(Effect 5) The inclined angle θ1 of the lower inclined walls 30a and 33a of both upper curved protrusion fitting outer portions 30 and 33 of the female protrusion 23 is made small, and the female protrusion 23 is formed. The prevention of the escape from the male-like protrusions 3) is further enhanced.

The invention of claim 4 has the following feature configuration.

Each of the upper curved protrusion projection inner fitting portions formed on each of the rising side wall portions 4 and 26 and the falling side wall portions 6 and 24 of the male and female protrusions 3 and 23, respectively. (10) (13) and each of the upper curved projections 20, 33, and each of the inner curved recesses 9 and 14 and the outer curved recesses 29 located below them. The height dimension (H1) between the upper coupling part-curve recessed part between up to 34 is from each said inner curved recessed part 9 and 14 and each outer curved recessed part 29 and 34, respectively. It was set to a value lower than the height dimension (H2) between the subcombination-curved recesses between the protruding inner fitting portions 8 and 15 and each of the lower curved protrusion fitting outer fitting portions 28 and 35.

From this characteristic configuration, it works as follows.

The upper coupling portion-curved recessed height dimension H1 is set to a value lower than the lower coupling portion-curved recessed height dimension H2, so that both upper curved protruding outer fitting portions of the female protrusion 23 are formed. Since the inclination angle θ1 of the lower inclined walls 30a and 33a of (30) and (33) can be made small, both of the upper curved protrusion protrusion outer fitting portions 30 and 33 have both upper curved protrusion inner fittings. The fall prevention force becomes strong with respect to the part 10 and 13, and it can further strengthen the prevention force of the escape | egress from the male type | mold protrusion 3 of the female type | mold protrusion 23. As shown in FIG.

Invention of claim 5, see FIG.

The invention of claim 5 exhibits the following effects in addition to (effect 1), (effect 2) and (effect 3) of the invention of claim 1.

(Effect 6) As the rainwater received by the trough 27 is discharged to the atmosphere smoothly without rising again, the water blocking performance at the lower close contact portion 37 is improved, so that the building 41 Intrusion of rainwater into the roof 42 is more strongly prevented.

The invention of claim 5 has the following feature configuration.

The lower end portion 27 of the descending side wall portion 24 of the female type protrusion 23 is formed as a drip tray trough 27 by directing it to a lower side than the lower curved protrusion outer fitting portion 28 and then turning U inward. . This drip trough 27 approaches or contacts the rising side wall 4 of the male protrusion 3.

From this characteristic configuration, it works as follows.

When the rainwater blows from one metal roof plate 1 between the rising side wall portion 4 of the male ridge 3 and the falling side wall portion 24 of the female ridge 23, Most of the rainwater is blocked by the access or contact portion between the rising side wall portion 4 and the drip trough 27, so that only a small portion of the rainwater does not pass.

Only a part of the rainwater after this passage is in close contact with the lower curved protrusion inner fitting portion 8 of the male protrusion 3 and the lower curved protrusion outer fitting coupling portion 28 of the female protrusion 23. It is blocked by the fall, and is received by the drip trough 27 and flows along the inclination of the trough, and is discharged to the atmosphere from the lower end of the trough slope.

Rainwater received by the drip trough 27 is separated from the rainwater that rises between the drip trough 27 and the rising side wall portion 4, so that it is smoothly drawn into the atmosphere without being rolled up by the rising rain water and rising again. Is discharged.

As a result, the lower close contact portion 37 between the lower curved protrusion inner fitting portion 8 and the lower curved protrusion outer fitting portion 28 is less water as the amount of rain that reaches the excitation becomes weaker. The breaking performance is improved, and the ingress of rainwater on the roof 42 of the building 41 can be more firmly prevented.

Invention of claim 6, see FIG. 1

The invention of claim 6 exhibits the following effects in addition to (effect 1), (effect 2) and (effect 3) of the invention of claim 1.

(Effect 7) Even if a very small amount of rainwater invades into the innermost part 39 between the gaps between the projections between the male protrusion 3 and the female protrusion 23, this may occur. The rain water is sealed by the trough close contact portion 40 between the water blocking trough 19 and the roof plate body 22, so that it is surely prevented from invading into the roof 42 of the building 41.

The invention of claim 6 has the following feature configuration.

The water end groove 19 of the attachment portion 7, which is directed outward from the lower end portion of the male-shaped protrusion descending side wall portion 6, is opened in a horizontal direction by U-turning around the upper portion thereof. It is formed as). The water blocking trough 19 is brought into close contact with the roof plate body 22 in which the female protrusion 23 is continuously formed.

From this characteristic configuration, it works as follows.

Here, a case in which extremely small amount of rainwater invades into the innermost part 39 between the gaps between the projections between the male protrusion 3 and the female protrusion 23 is described. .

The rainwater that penetrates the innermost part 39 between the protrusions is sealed by the trough close contact portion 40 between the water blocking trough 19 and the roof plate main body 22, and thus the water blocking trough 19 or the projections. It flows along the inclination of the innermost part 39 between clearance gaps, and is discharged | emitted to air | atmosphere.

For this reason, even if a small amount of rainwater invades the innermost part 39 between the gaps between the projections between the male protrusion 3 and the female protrusion 23, this rainwater has occurred. Is sealed by the trough close contact portion 40 between the water blocking trough 19 and the roof plate body 22, so that it is surely prevented from invading into the roof 42 of the building 41.

Claims (6)

One of the two metal roof shingles (1) and (21) parallel to the left and right of the metal shingles (1) has a male type for waterproof and fitting connection to the horizontal outer edge of the roof shroud body (2). The protrusions 3 are folded to form one by one, and on the other hand, the other metal roof plate 21 is a female type for waterproof and fit connection to the horizontal outer edge of the roof plate body 22 thereof. Fold 23 and fold it to form one, By covering the male protrusion (3) with the female protrusion (23) from the top to the outside, it is configured to fit the two metal roof plates (1) (21) to each other in a waterproof shape, The male protrusion 3 is sequentially formed from the outer edge portion of the roof plate body 2 so that the upward side wall portion 4 extending upwards, the upper wall portion 5 extending horizontally outwards and downwardly extend. The descending side wall part 6 is formed in succession, and the attachment part 7 with respect to a building roof is directed outwardly from this fall side wall part 6, and The female protrusion 23 is sequentially formed from one side edge portion of the roof plate body 22, and the upward side wall portion 26 extending upward, the upper wall portion 25 extending in the horizontal direction and the downward downward extension In the waterproof connection structure of the metal roof board configured to be formed by successively forming the side wall portion 24, The lower side surface protruding inner fitting portion 8, concave, which is continuous to the rising side wall portion 4 of the male protrusion 3 at least from bottom to top in order to protrude inward in the horizontal direction. The inner curved concave portion 9 to be formed and the upper curved projection inner fitting portion 10 to be formed into a protrusion are subsequently formed, The descending side wall portion 24 of the female protrusion 23 is continuous at least from the top to the bottom in order, and the upper curved protrusion-outward fitting portion 30, which is protruded inward in the horizontal direction, becomes outer in shape. The curved concave portion 29 and the lower curved projection outer fitting portion 28 that is formed in a protruding shape are subsequently formed as one, By the elastic restoring force of the female protrusion 23, the upper curved protrusion outer fitting portion 30 and the lower curved protrusion outer fitting portion 28 of the lower side wall portion 24 of the female protrusion 23 is The upper curved protrusion inner fitting portion 10 and the lower curved protrusion inner fitting portion 8 of the rising side wall portion 4 of the male protrusion 3 are brought into close contact with each other, A back pressure chamber (11) for preventing rainwater intrusion is formed between the outer curved recessed portion 29 and the inner curved recessed portion 9, The lower end portion 11a of the back pressure chamber 11 is the lower curved projection outer fitting portion 28 of the lower side wall portion 24 of the female protrusion 23 and the rising side wall of the male protrusion 3. The upper end portion 11b of the back pressure chamber 11 is closed by a close contact with the lower curved protrusion inner fitting portion 8 of the portion 4, and the lower side wall portion 24 of the female protrusion 23 is closed. A metal roof, which is configured to be closed by intimate contact between the upper curved protrusion inner fitting portion 10 and the upper curved protrusion inner fitting portion 10 of the rising side wall portion 4 of the male protrusion 3. Waterproof connection structure of plate. The method of claim 1, The lower side wall portion 6 of the male protrusion 3 is continuously formed in order from the top to the bottom, in order from the top to the bottom, and the upper curved protrusion inner fitting portion 13, which is protruded outward in the transverse direction, the inner side being concave. The curved concave portion 14 and the lower curved protrusion inner fitting portion 15, which are in a protruding shape, are subsequently formed as one, The raised side wall portion 26 of the female type protrusion 23 is continuously formed in order from at least downward to upward, and has a lower curved protrusion-outward fitting portion 35 that protrudes outward in the horizontal direction, and the outer side becomes concave. The curved concave portion 34 and the upper curved protrusion-outward fitting portion 33, which are projecting, are subsequently formed as one, By the elastic restoring force of the female protrusion 23, the upper curved projection outer fitting portion 33 and the lower curved projection outer fitting portion 35 of the rising side wall portion 26 of the female protrusion 23 is In close contact with the upper curved protrusion inner fitting portion 13 and the lower curved protrusion inner fitting portion 15 of the lower side wall portion 6 of the male protrusion 3, respectively. Rainwater intrusion prevention between the outer curved concave portion 34 of the rising side wall portion 26 of the female protrusion 23 and the inner curved concave portion 14 of the lower side wall portion 6 of the male protrusion 3 The back pressure chamber 36 of the back pressure chamber 36 is formed, and the lower end portion 36a of the back pressure chamber 36 has a lower curved protrusion outer fitting portion 35 and a male type of the rising side wall portion 26 of the female protrusion 23. It is closed by close contact with the lower curved projection inner fitting portion 15 of the lower side wall portion 6 of the protrusion 3, and the upper end portion 36b of the back pressure chamber 36 is closed by the female type protrusion 23. As shown in FIG. Closed by close contact between the upper curved projection outer fitting portion 33 of the rising side wall portion 26 and the upper curved projection inner fitting portion 13 of the lower side wall portion 6 of the male protrusion 3. Waterproof connection structure of the metal roof board, characterized in that configured. The method of claim 2, Lower coupling portion between the lower curved protrusion inner fitting portion 8 of the rising side wall portion 4 of the male protrusion 3 and the lower curved protrusion inner fitting portion 15 of the lower side wall portion 6. The width dimension L2 between the upper and upper surfaces is different between the upper curved protrusion inner fitting portion 10 of the rising side wall portion 4 and the upper curved protrusion inner fitting portion 13 of the lower side wall portion 6. Waterproof connection structure of a metal roof plate, characterized in that the coupling portion is set to a value wider than the width (L1). The method according to claim 2 or 3, Each of the upper curved protrusion projection inner fitting portions formed on each of the rising side wall portions 4 and 26 and the falling side wall portions 6 and 24 of the male and female protrusions 3 and 23, respectively. (10) (13) and each of the upper curved projections 20, 33, and each of the inner curved recesses 9 and 14 and the outer curved recesses 29 located below them. The height dimension (H1) between the upper coupling part-curve recessed part between up to 34 is from each said inner curved recessed part 9 and 14 and each outer curved recessed part 29 and 34, respectively. It is set to a value lower than the height dimension (H2) between the sub-joining portion-curved recessed portion between the protruding inner fitting portion 8 and 15 and each of the sub-curved outer fitting engaging portions 28 and 35. Waterproof connection structure of the metal roof board. The method of claim 1, The lower end portion 27 of the lower side wall portion 24 of the female type protrusion 23 is formed as a drip tray trough 27 by directing the lower curved protrusion outward fitting portion 28 downward and then turning U inwardly. The water gutter 27 is a waterproof connection structure of a metal roof plate, characterized in that configured to approach or contact the rising side wall portion 4 of the male-shaped ledge (3). The method of claim 1, A water blocking trough 19 of the attachment portion 7 which is directed outward from the lower end portion of the male-shaped stone descending side wall portion 6 to open in the horizontal direction by U-turning around the upper portion 19 And the water blocking trough (19) is configured to be in close contact with the roof plate body (22) in which the female protrusion (23) is continuously formed.

Images