JP6078214B2 - Tile that can prevent backflow - Google Patents

Description

The present invention relates to a tile capable of preventing backflow, and more specifically, an upper flange having a drainage groove on the surface of the main body of the tile and a drainage channel through which rainwater is drained, and frost is formed on the back surface of the main body. A lower flange having a guide projection for discharging, a back surface for preventing raindrops (S) from flowing back, and an auxiliary projection is formed. The upper flange on the surface of the main body has upper and lower portions. A drainage groove formed so as to penetrate therethrough is disposed at the lower part of the upper flange, and a drainage channel having a shape opened downward is formed so that rainwater is drained. In order to discharge the frost, the guide projections are arranged at the lower part of the adhesion surface and are inclined so that the left and right sides are V-shaped, as opposed to the left and right sides and projecting to the back surface, and the guide Arranged between the protrusion and the contact groove, the contact The drainage surface formed flat on the back surface is formed, and the frost is configured to flow to the center of the back surface along the guide protrusion, and is formed in a band shape disposed between the drainage surface and the lower flange. Auxiliary protrusions are formed, and the lower flange is formed so as to rise obliquely as the back surface goes upward, and the frost flowing into the drainage surface flows to the side surface by the protruding auxiliary protrusions and is positioned below The drainage channel is configured to be wide and narrow, giving the maximum drainage distance from the upper flange to the lower flange of the body, and maximizing the surface area, The present invention relates to a tile capable of preventing backflow, characterized in that the backflow is blocked, so that a water leakage phenomenon can be prevented and the corrosion of the frame is prevented.

In general, tiles are kneaded with clay, molded with a mold, dried, baked in a plastic furnace, and used as a roofing material for buildings. It has various forms and patterns, such as flat roof tiles, roof lamps, floor boards, demon roof tiles, arabesque roof tiles, and eaves round roof tiles.

In addition, the tiles made in this way are constructed by overlapping the upper and lower sides of a timber framework in which cross bars and vertical trees are constructed in a lattice pattern at the top of the building.

Next, the tiles that are adjacent to the sides are covered with round tiles.

On the other hand, the conventional roof tile 1 shown in FIG. 1 has a square plate shape and is formed with a round-shaped main body 10 with its right and left sides rising. .

Further, the lower flange 20 protrudes from the back surface of the lower end of the main body 10, and is configured to prevent a phenomenon in which drained rainwater flows back along the back surface of the main body 10.

Further, an upper flange 30 protrudes above the surface 15 of the main body 10 to prevent a phenomenon that rainwater flows backward and leaks into the framework.

Here, lateral flanges 40 project from the left and right sides of the main body 10 so that rainwater does not leak laterally.

Further, in order to construct the roof tile 1 on the framework, as shown in FIG. 2, in the framework F, the first roof tile 1 is placed on the lowermost rung T, and the second roof tile 1 is placed thereon. The lower flange 20 is positioned below the upper flange 30 of the first roof tile 1.

In such a system, the roof tiles 1 are superposed while being mounted from the bottom to the top.

On the other hand, problems of the conventional roof tile 1 formed in this way will be described.

First, as shown in FIG. 2, when it rains, rainwater that flows downward along the main body 10 accumulates at the lower end of the lower flange 20 along the lower end.

At this time, if the wind blows in the opposite direction, the raindrops will pass over the upper flange 30 of the tile 1 arranged below and fall on the frame F, causing water leakage and causing the frame F to corrode. It was.

Here, such a phenomenon occurs when the wind blows in the opposite direction, and even when the roof tiles 1 are superimposed on the upper and lower portions, they are disposed on the lower flange 20 and the lower portion of the roof tile 1 disposed on the upper portion. Since a gap is generated between the surface 15 of the roof tile 1 and the wind passes sufficiently, raindrops can also flow backward.

Secondly, as shown in FIGS. 2 and 3, there is a problem that the roof tile 1 slides down due to gravity due to the construction structure in which the roof tile 1 is simply placed on the framework F.

Third, as shown in FIG. 3, the back surface 13 of the main body 10 is a round surface in a state in which the roof tile 1 is supported by the crossbar T of the framework F, so A rotating phenomenon occurs.

Therefore, when the worker steps on the roof tile 1 and works, the roof tile 1 moves and falls to the ground to cause injury.

Fourth, in winter, frost generated on the back surface 13 of the roof tile 1 falls down on the back surface 13 and falls on the frame F, causing the frame F to corrode.

Korean Design Registration No. 30-0564165 Japanese Patent Application Publication No. 2004-3007675 Japanese Utility Model Registration No. 3100423 Japanese National Utility Model Publication No. 53-095516

The present invention has been made in view of the above problems, and its purpose is to block backflow of rainwater and prevent a water leakage phenomenon. In winter, frost generated on the back surface of the roof tile is An object of the present invention is to provide a backflow-preventable roof tile that is configured to fall on a frame and prevent the frame from corroding as it descends.

In order to achieve the above-described object, the present invention provides a roof tile having an upper flange having a drainage groove and a drainage channel through which rainwater is drained.
On the back surface of the main body, a lower flange having a guide protrusion for discharging frost, a back surface for preventing raindrops S from flowing back, and an auxiliary protrusion is formed.
The upper flange of the surface of the main body is formed with a drainage groove formed so as to penetrate upward and downward, and is disposed at the lower part of the upper flange, and has a shape opened downward so that rainwater is drained. Drainage channels are formed,
In order to discharge frost on the back surface of the main body, it is arranged at the lower part of the adhesion surface, and is inclined so that the left and right sides are V-shaped, as opposed to the left and right sides and protruding on the back surface. The guide projection, and the drainage surface formed flat on the back surface is formed between the guide projection and the contact groove, and is connected to the contact groove, and the frost is formed along the guide protrusion at the center of the back surface. A belt-like auxiliary protrusion is formed between the drainage surface and the lower flange, and the lower flange is formed obliquely as the back surface goes upward. The inflowing frost is guided by the projecting auxiliary protrusions to fall to the main body located below while flowing to the side, and the drainage channel is configured to be wide and narrow, from the upper flange to the lower flange of the main body Give maximum drainage distance Both tiles are designed to have the largest possible surface area on both sides and prevent reverse flow of rainwater, thus preventing water leakage and preventing backflow corrosion. About.

The present invention has the following effects.

First, since the drainage channel of the present invention has a wide upper part and a narrow lower part, the drainage speed becomes faster at the narrow outlet part, and the drainage distance of rainwater drained from the outlet becomes longer. Since the rainwater is sufficiently sent to the drainage channel of the main body located at the bottom, the rainwater is accumulated in the lower flange, and the effect of reducing the reverse flow through the backside of the main body in the reverse direction is reduced compared to the background art There is.

Second, in the present invention, since the back surface of the lower flange is inclined upwardly upward, it is difficult to flow backward, and if there is raindrops flowing backward beyond such a lower flange, It can be shut off again.

Thirdly, in the present invention, since the locking projection is locked to the crosspiece and is fixed to the crosspiece by the nail, the phenomenon of sliding down due to gravity can be prevented.

Fourthly, in the present invention, the surface that contacts the crossbar by the attachment surface is larger than the background art, so when the operator steps on the work, the body rotates and falls to the ground, resulting in injury. Compared with the background art, it can be reduced and can be firmly supported by the cross.

Fifth, in the present invention, it is possible to prevent the phenomenon that the frost falls to the nail and the nail hole penetrating the main body located in the lower portion, corrodes the nail, and corrodes the rung by the guide protrusion and the drainage surface.

Sixth, in the present invention, when frost or rainwater flows into the upper part of the upper flange, it can be easily discharged downward from the drainage groove.

It is a perspective view which shows the state by which the roof tile by a prior art was supported by the crosspiece of the frame. It is sectional drawing which showed the state which constructed the roof tile by the prior art to the frame. It is the side view which showed what looked at FIG. 1 from the K direction. It is the perspective view which showed the roof tile which can prevent a backflow by this invention. It is the perspective view which showed the lower part of the roof tile which can prevent a backflow by this invention. It is sectional drawing by the C-C 'line of FIG. It is the perspective view which showed the state by which the roof tile which can prevent backflow by this invention was supported by the framework. FIG. 8 is a cross-sectional view taken along line F-F ′ in FIG. 7. It is a perspective view which shows the state by which the principal part of this invention was assembled.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily implement the present invention. However, the present invention may be embodied in various different forms and is not limited to the embodiments described herein.

In the drawings, in order to clearly describe the present invention, parts not related to the description are omitted, and like parts in the whole specification are given like reference numerals.

Throughout the specification, when a part includes a component, this means that the component does not control other components and may include other components unless otherwise specified. To do.

FIG. 4 is a perspective view illustrating a roof tile capable of preventing backflow according to the present invention, FIG. 5 is a perspective view illustrating a lower portion of the roof tile capable of preventing backflow according to the present invention, and FIG. FIG. 7 is a perspective view showing a state in which a backflow preventable roof tile according to the present invention is supported by a frame, and FIG. 8 is a cross-sectional view taken along the line FF ′ of FIG. 9 will be described together with a perspective view showing a state in which the main parts of the present invention are assembled.

First, as shown in FIG. 9, the roof tile 1 of the present invention is placed on a wooden framework F in which a cross T and a vertical tree V are constructed in a lattice shape on the upper part of a building, and then placed sideways. Between the tiles 10 adjacent to each other, the round tile 2 is covered and finished.

The roof tile 1 placed on the framework F is a square plate shape, and includes a round main body 110 whose left and right sides are raised. However, when viewed in cross section, the roof tile 1 has an arc shape.

In addition, an upper flange 119 is formed on the surface 111 of the main body 110 and protrudes to prevent backflow of rainwater.

Further, an upper end flange 122 and a side end flange 123 projecting upward are formed at the upper and left and right end portions of the main body 110, respectively.

Here, a contact groove 124 is formed on the lower surface 113 of the main body 110, opened to the left and right sides and downward, and placed on the upper flange 119 of another roof tile 1.

A band-shaped lower flange 115 protruding from the lower end of the contact groove 124 is formed.

On the other hand, in order to discharge frost, the back surface of the main body 110 is disposed in a lower portion of the attachment surface 131 and is a belt-like shape that protrudes on the back surface in opposition to the left and right sides. An inclined guide protrusion 133 is formed.

Further, the drainage surface 135 is disposed between the guide protrusion 133 and the close contact groove 124, is connected to the close contact groove 124, and is formed flat on the back surface 113, so that frost is formed along the guide protrusion 133. And configured to flow in the center of the back surface 117.

Here, a band-shaped auxiliary protrusion 137 disposed between the drainage surface 135 and the lower flange 115 is formed, and the lower flange 115 is formed to rise obliquely as the back surface 117 goes upward.

Further, the frost flowing into the drainage surface 135 is guided by the protruding auxiliary protrusion 137 so as to flow to the side surface and fall to the main body 110 located below.

On the other hand, the drainage channel 125 is formed to have an upper, lower, and narrower width and has a maximum drainage distance from the upper flange 110 to the lower flange 115 of the main body 110, and has a maximum surface area on both sides. In addition, since the reverse flow of rainwater is blocked, the water leakage phenomenon can be prevented.

Hereinafter, the configuration of the present invention having such a configuration will be described in detail.

First, as shown in FIG. 4, on the surface 111 of the main body 110, the groove is disposed at the lower part of the upper flange 119 and opened downward so that rainwater is drained, and the width becomes narrower as it goes downward. The drainage channel 125 is configured to improve the drainage speed of rainwater.

Also, as shown in FIG. 4, a nail hole 127 that is disposed between the upper flange 119 and the upper end flange 122 and penetrates the main body 110 is formed.

Further, as shown in FIG. 5, a nail hole 127 is formed on the back surface 113 of the main body 110, and as shown in FIG. 5, the nail hole 127 is arranged on the back surface 113 of the main body 110 and above the nail hole 127. Locking protrusions 129 that protrude so as to be locked to T are formed.

Here, the nail hole 127 formed in the back surface 113 is formed flat and includes an attachment surface 131 that is in close contact with the crosspiece T.

That is, the locking protrusion 129 temporarily prevents the body 110 from sliding down due to gravity, and the nail 128 is inserted into the nail hole 127 and driven into the crosspiece T, thus preventing a secondary descending phenomenon. It is the structure which can do.

Further, in order to efficiently drain the frost formed on the back surface 113 of the main body 110, as shown in FIG. 5, it is disposed at the lower part of the attachment surface 131, and protrudes from the back surface 113 to face the left and right sides. The guide projection 133 is formed so that the left and right sides are V-shaped.

Here, since each guide protrusion 133 is formed to be inclined downward and downward, the corresponding guide protrusions 133 on both sides have a mutual V-shape.

Further, as shown in FIG. 5, a drainage surface 135 is formed between the guide protrusion 133 and the contact groove 124 and is connected to the contact groove 124 and is formed flat on the back surface 113.

Here, a belt-like auxiliary projection 137 is formed between the drainage surface 135 and the lower flange 115, and the length of the auxiliary projection 137 and the lower flange 115 is the side end flange 123 of the main body 110 on the relative side. It will be inserted in between.

On the other hand, as shown in FIG. 6, the lower flange 115 is formed so as to rise obliquely as the back surface 117 goes upward, so that the backflow of the raindrops S is prevented.

In addition, a drainage groove 121 is formed in the upper flange so as to penetrate upward and downward so that when rainwater flows into the upper portion of the upper flange 119, the drainage is quickly drained.

Here, since the drainage groove 121 is formed in a recessed portion of the main body 110, the drainage function can be easily performed.

Moreover, as shown in FIG. 7, since the lower end width V2 of the main body 110 is formed to be smaller than the upper end width V1, the water drained at the lower end can easily fall to the central portion of the roof tile 100 disposed below. Therefore, the water is drained between the roof tiles 100 so that a water leakage phenomenon does not occur.

Hereinafter, the construction example and drainage process of this invention by such a structure are demonstrated.

As shown in FIGS. 7, 8, and 9, in the state where the vertical bar V is constructed and the horizontal bar T is fixed to the surface of the vertical tree V, the backflow can be prevented by the present invention on the horizontal bar T positioned below. The locking projection 129 of the roof tile 100 is locked.

At this time, since the main body 110 does not descend, the nail 128 can be inserted into the nail hole 127 and can be easily driven into the crosspiece T.

Here, it goes without saying that the cross T is also supported at the bottom of the present invention.

In addition, since the surface of the adhering surface 131 that is in contact with the crosspiece T is larger than that of the background art, the main body 110 rotates when the operator is stepping on the work, and the phenomenon of falling to the ground and causing injury is reduced. There is an advantage that it can be firmly supported by the crosspiece T.

In this state, another main body 110 is overlaid on the main body 110 fixed to the crosspiece T. The lower flange 115 and the auxiliary protrusion 137 of the other main body 110 are disposed below the upper flange 119 of the main body 110 and the drainage. It arrange | positions between the paths 125.

Here, the lower flange 115 is formed thicker than the auxiliary protrusion 137 and is supported by the surface 111 of the other main body 110 located below.

Further, since the upper end flange 122 and the side end flange 123 of the other main body 110 are accommodated in the close contact groove 124, the lower portion of the main body 110 located at the upper portion is lifted, and the phenomenon that rainwater flows backward is prevented. .

At this time, the locking protrusion 129 of the main body 110 that overlaps with the upper portion is locked with the crosspiece T, and the nail 128 is driven through the nail hole 127 of the main body 110 located above, so that the main body 110 positioned at the upper portion is fixed to the crosspiece. Fixed to T.

In this manner, the present invention is superimposed on the upper side.

Such constructions are arranged side by side, and the main body 110 is arranged side by side on the left and right sides.

Here, the round tile 2 is covered and finished on the upper part of the main body 110 corresponding to the side as shown in FIG.

Therefore, according to the present invention, the main body 110 is supported by the crosspiece T by the locking projection 129 and fixed to the crosspiece T by the nail 128, so that the present invention can prevent the phenomenon of sliding down due to gravity.

On the other hand, when it rains in such a construction state, as shown in FIGS. 7, 8, and 9, the main body 110 has a curved shape and is inclined downward. The rainwater that has fallen on 111 gathers in the drainage channel 125 and is discharged downward together with the rainwater that has fallen in the drainage channel 125.

At this time, the drainage channel 125 is configured to be wide and narrow, and has a maximum drainage distance from the upper flange 119 to the lower flange 115 of the main body 110 and a maximum surface area on both sides. .

Therefore, since the pressure at the outlet 126 is lower than that of the wide upper portion, a pressure difference is generated, and rainwater flows more rapidly than when there is no difference in the vertical width.

That is, as shown in FIG. 7, the drainage distance of the rainwater drained from the outlet 126 becomes long, and the rainwater is sufficiently sent to the drainage channel 125 of the main body 110 located at the lower part.

Here, since the width of the outlet 126 is narrower than the width of the upper portion of the drainage channel 125, the channel area becomes narrower as it goes downward.

According to the law of conservation of mass, the flow rate through each channel area is the same in the same time.

That is, since S ₁ V ₁ = S ₂ V ₂ (S ₁ , S ₂ ; area of each point of the drainage furnace, V ₁ , V ₂ ; area of each point of the drainage channel), the water is drained from the outlet 126. The rainwater speed increases, the rainwater drainage distance becomes longer, and the rainwater drainage distance 125 of the main body 110 located at the lower part is sufficiently sent out.

Therefore, it is possible to reduce the phenomenon that rainwater collects in the upper flange 115 and flows backward through the back surface 113 of the main body 110 in the reverse direction.

On the other hand, when the rain stops, as shown in FIG. 6, when wind blows from the outside in the state where the raindrops S accumulate on the lower flange 115, the air flows back along the back surface 113 of the main body 110.

However, in the present invention, since the back surface 117 of the lower flange 115 is inclined upward, it is difficult to back flow, and it is even easier if the back surface 117 is parallel to the back surface 113 of the main body 110. The problem of backflow will occur.

However, if there is rainwater that flows backward beyond the lower flange 115, the auxiliary protrusion 137 blocks the rainwater again.

Further, in winter, when the air containing steam comes into contact with the back surface 113 of the main body 110 cooled by the outside air, frost is formed, and this flows to the center of the back surface 113 along the guide protrusion 133 as shown in FIG.

Here, after flowing into the drainage surface 135 along the back surface 113, if the cylindrical projection on the front surface 111 constituting the nail hole 127 is in contact with the close contact groove 124 on the back surface, the bottom is transferred along the projection. Although it may be induced to fall to the main body 110 located at the position, it is not necessarily an essential requirement .

At this time, a gap is formed between the groove-shaped drainage surface 135 and the upper end flange 122 of the main body 110 disposed below, so that frost passes and falls downward.

As shown in FIG. 4, the frost thus dropped is discharged from the drain groove 121 formed in the upper flange 119 to the drain channel 125.

Here, if the guide protrusion 133 and the drainage surface 135 are not present, frost is formed on the upper end K of the contact groove 124 and then falls downward, the nail 128 corrodes quickly, and the nail 128 and the nail hole 127 A phenomenon occurs in which water leaks in between and corrodes the crosspiece T supported below.

However, the present invention has an advantage that such problems can be solved.

The above description of the present invention is for illustrative purposes only, and those having ordinary knowledge in the technical field to which the present invention pertains do not change the technical idea or essential features of the present invention. It will be understood that it can be easily changed to a specific form.

Therefore, it should be understood that the above-described embodiments are illustrative in all aspects and not limiting. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as being distributed may be implemented in a combined form.

The scope of the present invention is defined by the following claims rather than the detailed description, and all modifications or variations derived from the meaning and scope of the claims and equivalent concepts thereof are within the scope of the present invention. Should be construed as included in

100 roof 110 main body 111 front surface 113 back surface 115 lower flange 117 back surface 119 upper flange 121 drainage groove 122 upper end flange 123 side end flange 124 contact groove 125 drainage channel 126 outlet 127 nail hole 128 nail 129 locking projection 131 adhesion surface 133 guide projection 135 Drainage surface 137 Auxiliary protrusion

Claims (3)

An upper flange 119 having a drainage groove 121 and a drainage channel 125 through which rainwater is drained are formed on the surface 111 of the main body 110.
The roof tile 100 is formed with a lower flange 115 having a guide projection 133 for discharging frost, a back surface 117 for preventing raindrops S from flowing backward, and an auxiliary projection 137 on the back surface 113 of the main body 110. Configure
The upper flange 119 of the surface 111 of the main body 110 is formed with a drain groove 121 penetrating upward and downward, and is disposed below the upper flange 119 so that rainwater is drained. A drainage channel 125 having an open shape is formed,
In order to discharge frost formed on the back surface 113 of the main body 110, the left and right sides are arranged in a V-shape as the belt-like one that is disposed below the attachment surface 131 and protrudes from the back surface 113 to face the left and right sides. An inclined guide protrusion 133 is formed,
The guide projection 133 is formed between the upper end flange 122 of the main body 110 located below the back surface and the close contact groove 124 contacting the upper flange 119, and is connected to the close contact groove 124. After the flat drainage surface 135 is formed,
The frost is configured to flow into the center of the back surface 113 and the drainage surface 135 along the guide protrusion 133 and fall to the main body 110 located below,
The back surface 117 of the lower flange 115 is formed in an upwardly inclined state so that the rainwater S does not flow backward when wind blows,
The raindrops S that flow backward beyond the lower flange 115 are blocked again by the auxiliary protrusions 137, and the roof tile is capable of preventing backflow. A drainage surface 135 is disposed between the guide protrusion 133 and the close contact groove 124 and connected to the close contact groove 124 and formed flat on the back surface 113, and frost is formed along the guide protrusion 133 in the center of the back surface 117. Formed to flow into
Between the drainage surface 135 and the lower flange 115, a band-shaped auxiliary protrusion 137 is disposed, and the lower flange 115 is formed to be inclined upward as the back surface 117 goes upward,
2. The roof tile capable of preventing backflow according to claim 1, wherein the frost flowing into the drainage surface 135 is guided by the protruding auxiliary protrusions 137 to flow to the side surface and fall to the main body 110 positioned below. . The drainage channel 125 is formed to be wide and narrow, and has a maximum drainage distance from the upper flange 119 to the lower flange 115 of the main body 110 and has a maximum surface area on both sides. The roof tile capable of preventing backflow according to claim 1.