CN215829836U - Roof water leakage shunting device - Google Patents

Abstract

The roof leakage shunting device relates to the technical field of roof skylights and comprises a skylight structure and a rainwater shunting shed, wherein the skylight structure comprises a window frame and a window sash, the window frame is arranged on a roof in a protruding mode, the window sash is arranged in the window frame, one side of the window sash is hinged with the window frame, and the rainwater shunting shed is arranged on the roof; the rainwater shunting shed is used for shunting rainwater and preventing rainwater from flowing along the roof surface and passing through the fragile area of the window frame. The utility model provides a roof rain leakage shunting device, which avoids the erosion of rainwater on a skylight frame in a mode of arranging a shed for shunting rainwater on a skylight along the upstream direction of a roof surface, and avoids the phenomenon of roof rain leakage.

Description

Roof water leakage shunting device

Technical Field

The utility model relates to the technical field of roof skylights, in particular to a roof rain leakage shunting device.

Background

In the summer in south China, rainwater is abundant, the condition that houses leak rain often appears because roof structures are provided with problems, the mode of setting up a loft skylight is often selected to increase the aesthetic feeling of the whole room along with the householder living on the top layer of the full utilization of building area in high-rise residential buildings, and in industrial production's factory building, in order to conveniently discharge the harmful gas that factory building production produced, also can select to set up the skylight.

Structurally, the skylight is designed to increase the light transmission and air permeability of the area below, but the risk of rain leakage is increased from a certain angle, particularly, the upward inclined end surface of the skylight frame is bound by rainwater guided by the roof for a long time, and the skylight frame is bound by glass cement and other modes, so that the rainwater cannot penetrate into the room in a short time, but under the long-time sun exposure and the rain erosion, the glass cement can be separated, the indoor rain leakage is caused, and therefore, for a house type with the attic skylight or a factory with the skylight, the flow stroke of the rainwater flowing through the roof by shunting the roof is necessary to avoid the skylight frame as far as possible.

SUMMERY OF THE UTILITY MODEL

Aiming at the problems in the prior art, the utility model provides a roof rain leakage shunting device, which avoids the erosion of rainwater on a skylight frame by arranging a shed for shunting rainwater on a skylight along the upstream direction of a roof surface, and avoids the phenomenon of roof rain leakage.

The roof leakage shunting device comprises a skylight structure and a rainwater shunting shed, wherein the skylight structure comprises a window frame and a window sash, the window frame is arranged on a roof in a protruding mode, the window sash is arranged in the window frame, one side of the window sash is hinged to the window frame, and the rainwater shunting shed is arranged on the roof; the rainwater shunting shed is used for shunting rainwater and preventing rainwater from flowing along the roof surface and passing through the fragile area of the window frame.

Preferably, in the above technical solution, the rainwater diversion shed includes a soft shed having one end fixedly connected to the roof surface and the other end fixedly connected to the upper end surface of the window sash, and the soft shed can be folded or unfolded between the two end portions.

Preferably, as for the above technical solution, a pushing structure is disposed between the rainwater diversion shed and the roof surface, one end of the pushing structure is fixedly connected to the upper end surface of the sash, the other end of the pushing structure is connected to a control circuit, the control circuit is used for pushing the pushing structure, and the pushing structure pushes the sash window under the driving of the control circuit, so that the skylight structure is changed from an open state to a closed state.

The open state of the technical scheme refers to the state that the window sash rotates upwards relative to the window frame, and the closed state refers to the state that the window sash is completely positioned in the middle accommodating area of the window frame.

Preferably, in the above technical solution, the rainwater diversion shed further includes a fixing portion horizontally disposed, the soft shed is fixedly connected to the roof surface through the fixing portion, the fixing portion is provided with a rainwater tank, the rainwater tank is provided with a first contact and a second contact, and the rainwater tank is connected in series to the control circuit through the first contact and the second contact.

In the above-described technical solution, the rain gutter corresponds to a node at which the entire circuit is disconnected, but after rain water is contained in the rain gutter, the disconnected node is connected by the rain water, and the rain gutter can be regarded as a switch controlled by the rain water.

Preferably, the skylight is further provided with a first switch connected with the control circuit in series, the first switch is connected with the circuit when the skylight is in an open state, and the first switch is disconnected with the circuit when the skylight is in a closed state.

Preferably, the side surface of the rain gutter is provided with a water discharge hole.

Preferably, the upper end surface of the rainwater diversion shed is two symmetrically arranged curved surfaces.

Preferably, the curved surface is curved toward a roof surface.

Preferably, the rainwater diversion shed comprises a soft membrane and a plurality of supporting frameworks for supporting the soft membrane to ensure that the cross-sectional shape of the soft membrane is kept unchanged.

In summary, the utility model has the following advantages:

1. the rainwater which slides down along the roof can be shunted in advance, and the hidden danger of rainwater leakage caused by that the rainwater continuously scours the obliquely upward end face of the skylight structure is prevented;

2. furthermore, one end of the rainwater diversion shed which is of a foldable structure is connected with the window sash, the coverage range of the rainwater diversion shed can be changed along with the state change of the skylight structure, and the rainwater diversion shed is further waterproof;

3. further, under the state that skylight structure opened in this application, if unmanned initiative closed skylight structure in rainy day, two contact structures on the rainwater groove just can communicate the circuit and force rainwater reposition of redundant personnel canopy to expand and close skylight structure.

Drawings

FIG. 1 is a schematic diagram of the structure of the present application;

FIG. 2 is a cross-sectional view of the rainwater diversion shed of the present application;

FIG. 3 is a schematic diagram of the present application showing the structure and control circuit;

FIG. 4 is a schematic diagram of a first switch of the present application;

fig. 5 is a schematic view of the pushing device of the present application.

Detailed Description

The terms of orientation of up, down, left, right, front, back, top, bottom, and the like as referred to or as may be referred to in this specification are defined with respect to the configuration shown in the drawings, and the terms "inner" and "outer" refer to directions toward and away from the geometric center of a particular component and are relative terms, and thus may be changed accordingly depending on the position and the state of use of the particular component. Therefore, these and other directional terms should not be construed as limiting terms.

The utility model is further illustrated by the following examples:

example (b):

the roof rain leakage shunting device, please refer to fig. 1, includes a skylight structure 1 and a rain diversion shed 2, which are arranged on a roof, wherein the skylight structure 1 includes a window frame 11 and a sash 12, the sash 12 is tempered glass with a frame, the sash 12 is arranged inside the window frame 11, and one end of the sash 12, which is located on the upper side, is hinged to the window frame 11, the rain diversion shed 2 is a foldable soft shed, and includes a soft film 21 and a plurality of supporting frameworks 22 for supporting the soft film 21 to keep the cross-sectional shape of the soft film 21 unchanged, the upper end surface of the rain diversion shed 2 is two symmetrically arranged curved surface structures, the curved surface of each curved surface structure is bent towards the direction close to the roof, as shown in fig. 2, and the cross-sectional shape of the rain diversion shed 2 is supported by the supporting frameworks 22; one end of the rainwater shunting shed 2 is fixedly connected with a roof surface, the other end of the rainwater shunting shed is fixed with the upper end surface of the window sash 12 to form a shed covering area where rainwater cannot enter, the soft film 21 is provided with a section of fixing part v, the fixing part v is horizontally arranged and cannot be folded, one end of the fixing part v is fixedly connected with the other end of the roof surface and is connected with the foldable part of the soft shed, the window sash 12 drives the rainwater shunting shed 2 to change the unfolding state or the folding state of the rainwater shunting shed, the covering range of the rainwater shunting shed 2 is ensured to be adaptively changed, and rainwater flowing along the roof surface cannot wash the fragile area (namely the obliquely upward end surface of the window frame 11) of the window frame 11 to form rainwater accumulation, so that the water leakage condition is caused.

In another embodiment, the curved surface of the curved structure of the rainwater diversion shed 2 is curved away from the roof surface, and the curved shed with the shape is more easily purchased in the market, but the diversion effect is relatively lower than that of the curved surface which is curved close to the roof surface.

Whole roofing leaks rain diverging device still includes thrust unit 3, thrust unit 3 sets up in the canopy coverage area, the fixed other end of the up end of thrust unit 3 one end and casement 12 is connected by a motor c, motor c is used for driving thrust unit 3 motion, make thrust unit 3 possess the power that promotes casement 12 motion, thrust unit 3 promotes casement 12 and makes whole skylight structure 1 change towards the closed condition by the open mode, and because the one end of rainwater reposition of redundant personnel canopy 2 is fixed with casement 12 up end, so casement 12 can drive rainwater reposition of redundant personnel canopy 2 and move in the motion process, increase self coverage. Referring to fig. 5, the pushing device 3 includes a pushing rod 31 and a hinged disc 32, wherein the hinged disc 32 is fixedly connected to the upper end surface of the window 12, the rear end of the pushing rod 31 is connected to a motor c, the motor c is an electric push rod, the head end of the pushing rod 31 is hinged to the hinged disc 32, based on this, the motor c pushes the pushing rod 31, the pushing rod 31 moves along the linear direction thereof, the hinged disc 32 rotates relative to the pushing rod 31 and drives the window 12 to rotate, so that the whole skylight structure 1 is changed from the open state to the closed state. The window sash structure 12 rotates to enable the whole soft film 21 to be changed from a folded state to an unfolded state, a driving power supply is further arranged in the covered area of the shed by combining the circuit shown in fig. 3, a first switch b is further arranged on the window sash 12, a rainwater tank a is further arranged on the upper end face of the fixing part v of the rainwater shunting shed 2, and two contacts, namely a first contact a-1 and a second contact a-2, are included in the rainwater tank a; the driving power supply, the first switch b, the rain gutter a and the motor c are mutually connected in series to form a control circuit, the driving power supply is direct current, the series connection of the whole circuit and the rain gutter a means that the first contact a-1 is connected in series with one pole of the driving power supply, the second contact a-2 is connected in series with the other pole of the driving power supply, the rain gutter a can be regarded as a switch theoretically, rainwater falls into the rain gutter a and forms a certain amount of accumulation to be communicated with the first contact a-1 and the second contact a-2, namely the rain gutter a can be automatically communicated with the circuit under the condition of raining, the first switch b in the application is manually opened or closed by people, please refer to fig. 4, the first switch b comprises a rotating arm b-1 and a fixing arm b-2 which are connected with the window sash 12, the rotating arm b-1 and the fixing arm b-2 are of a copper sheet structure capable of being electrified, and the rotating arm b-1 and the fixed arm b-2 are arranged in a staggered manner in space as shown in fig. 4, the rotating arm b-1 and the fixed arm b-2 are not in contact when the rotating arm b-1 and the fixed arm b-2 are in a vertical state (namely, the skylight structure 1 is in a closed state), and once the rotating arm b-1 rotates, two adjacent side surfaces of the rotating arm b-1 and the fixed arm b-2 are in contact to connect a circuit, so that the first switch b is in a closed state to connect the circuit when the skylight is in an open state, and the first switch b is in an open state when the skylight is in a closed state, and the whole circuit is in an open state no matter how.

The whole structure of the application is specifically used as follows: according to the operating environment, an operator can manually open or close the skylight, when the skylight structure 1 is in an open state, if the weather is changed into rainy days and the operator forgets to close the skylight, the skylight structure 1 is in the open state at the moment, the first switch b is communicated, rainwater covers the rainwater groove a gradually to enable the first contact a-1 to be communicated with the second contact a-2, at the moment, the whole circuit is communicated, the motor c starts to push the flexible film 21 to enable the whole rainwater shunting shed 2 to be changed into an unfolded state from a folded state, the window sash 12 is pushed to enable the whole structure 1 to be closed at the same time, at the moment when the whole skylight structure 1 is closed, the first switch b is disconnected, the whole circuit is disconnected, and the motor c does not push the rainwater shunting shed 2 any more.

In another embodiment, the side surface of the rain gutter a is further provided with a water discharge hole a-3, the water discharge hole a-3 can not only discharge water quickly after the rain stops to keep the rain gutter a dry, but also can select whether to close the skylight structure 1 according to the rainfall speed in the rain process, when the accumulation speed of the rainwater in the rain gutter a is obviously higher than the discharge speed of the water discharge hole a-3, the situation that the rainfall is very large at the moment is indicated, the skylight needs to be closed, and when the rainwater cannot be accumulated in the rain gutter a and is discharged from the water discharge hole a-3, the situation that the rainfall is very small at the moment is indicated, the maintenance of proper ventilation is more important, certainly, the arrangement of the water discharge hole a-3 is designed according to the actual situation, and some working environments or residential environments do not expect any rainwater to enter the room.

While preferred embodiments of the present invention have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. Therefore, it is intended that the appended claims be interpreted as including preferred embodiments and all such alterations and modifications as fall within the scope of the utility model.

It will be apparent to those skilled in the art that various changes and modifications may be made in the present invention without departing from the spirit and scope of the utility model. Thus, if such modifications and variations of the present invention fall within the scope of the claims of the present invention and their equivalents, the present invention is also intended to include such modifications and variations.

Claims (9)

1. The roof leakage shunting device is characterized by comprising a skylight structure (1) and a rainwater shunting shed (2), wherein the skylight structure (1) comprises a window frame (11) and a window sash (12), the window frame (11) is arranged on a roof in a protruding mode, the window sash (12) is arranged in the window frame (11), one side of the window sash (12) is hinged to the window frame (11), and the rainwater shunting shed (2) is arranged on the roof; the rainwater shunting shed (2) is used for shunting rainwater and preventing rainwater from flowing along the roof surface and passing through the fragile area of the window frame (11).

2. The roof leakage shunting device of claim 1, wherein: the rainwater diversion shed (2) comprises a soft shed, one end of the soft shed is fixedly connected with the roof surface, the other end of the soft shed is fixedly connected with the upper end surface of the window sash (12), and the soft shed can be folded or unfolded between the two end parts.

3. The roof leakage shunting device of claim 2, wherein: a pushing structure (3) is arranged between the rainwater diversion shed (2) and the roof surface, one end of the pushing structure (3) is fixedly connected with the upper end face of the window sash (12), the other end of the pushing structure (3) is connected with a control circuit, the control circuit is used for pushing the pushing structure (3), and the pushing structure (3) pushes the window sash (12) under the driving of the control circuit, so that the skylight structure (1) is changed from an open state to a closed state.

4. The roof leakage shunting device of claim 3, wherein: the rainwater diversion shed (2) further comprises a fixing part (v) which is horizontally arranged, the soft shed is fixedly connected with the roof surface through the fixing part (v), a rainwater tank (a) is arranged on the fixing part (v), a first contact (a-1) and a second contact (a-2) are arranged in the rainwater tank (a), and the rainwater tank (a) is connected with the control circuit in series through the first contact (a-1) and the second contact (a-2).

5. The roof leakage shunting device of claim 4, wherein: the skylight (12) is also provided with a first switch (b) which is connected with the control circuit in series, the first switch (b) is communicated with the circuit when the skylight (12) is in an open state, and the first switch (b) is disconnected with the circuit when the skylight is in a closed state.

6. The roof leakage shunting device of claim 4, wherein: the side surface of the rain gutter (a) is provided with a water discharging hole (a-3).

7. The roof leakage shunting device of claim 1, wherein: the upper end surface of the rainwater shunting shed (2) is two symmetrically arranged curved surfaces.

8. The roof leakage shunting device of claim 7, wherein: the curved surface is curved towards the roof surface.

9. The roof leakage shunting device of any one of claims 1-8, wherein: the rainwater shunting shed (2) comprises a soft film (21) and a plurality of supporting frameworks (22) which are used for supporting the soft film (21) and ensuring that the cross section shape of the soft film (21) is kept unchanged.

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