CN221031188U - Antiseep waterscape daylighting well structure and building - Google Patents

Abstract

The utility model relates to an anti-leakage waterscape lighting well structure and a building, wherein the anti-leakage waterscape lighting well structure comprises a first transverse structural unit, a first longitudinal structural unit, a second transverse structural unit, a second longitudinal structural unit, a cavity unit, a supporting unit, a lighting unit, an opening unit, a liquid collecting unit and a sealing unit; the first transverse structural unit is horizontally arranged on the building roof; the first longitudinal structural unit is arranged on the inner side of the first transverse structural unit; the second transverse structural unit is arranged on the inner side of the first longitudinal structural unit; the second longitudinal structural unit is arranged on the inner side of the second transverse structural unit; the cavity unit is arranged between the first longitudinal structural unit and the second longitudinal structural unit; the supporting unit is arranged at the top of the second longitudinal structural unit; the lighting unit is arranged at the top of the supporting unit; the liquid collecting unit is arranged in the cavity unit. The air-conditioning device has the advantages that the liquid collecting unit is arranged in the cavity unit, so that the problems that the safety of indoor space is affected when the lighting well is subjected to water seepage are solved.

Description

Antiseep waterscape daylighting well structure and building

Technical Field

The utility model relates to the technical field of building skylights, in particular to an anti-seepage waterscape lighting well structure and a building.

Background

At present, public buildings of business, hotel and cultural art type adopt lighting courtyard for underground functions to meet lighting requirements of individual functions, and building lighting courtyard is arranged below a landscape pool to realize integrated design of waterscape and courtyard.

The traditional daylighting well top method is that the daylighting well top plate is sealed by weather-proof silicone adhesive after the toughened glass is installed, but the daylighting well top plate is waterproof, and the construction technology and the later maintenance of the sealant are required to be high.

However, as the lighting well is waterproof only by virtue of the rubber pad and the sealant, the phenomenon of glue opening and water seepage is unavoidable due to water pressure and long-time insolation, if the phenomenon of water leakage is existed, the indoor space safety cannot be ensured due to quicker diffusion; therefore, the toughened glass curtain wall needs to be regularly checked and re-glued, so that the maintenance cost is high.

At present, aiming at the problems that the daylighting well is waterproof only by a rubber pad and sealant in the related art, the indoor space safety is influenced by quicker diffusion when the water seepage phenomenon occurs, the maintenance cost of regular drainage and gluing is higher, and the like, no effective solution is proposed yet.

Disclosure of utility model

The utility model aims to overcome the defects in the prior art, and provides an anti-leakage waterscape daylighting well structure and a building, so as to solve the problems that the daylighting well is waterproof, only depends on a rubber pad and sealant, and is relatively fast in diffusion when water seepage occurs, and relatively high in maintenance cost due to the fact that regular drainage and gluing are needed.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

in a first aspect, a waterscape lighting well structure is provided, comprising:

The first transverse structural unit is horizontally arranged on the building roof and is used for setting a landscape water surface;

The first longitudinal structural unit is arranged on the inner side of the first transverse structural unit, and the top surface of the first longitudinal structural unit is higher than the top surface of the first transverse structural unit;

The second transverse structural unit is arranged on the inner side of the first longitudinal structural unit and is connected with the bottom of the first longitudinal structural unit;

The second longitudinal structural unit is arranged on the inner side of the second transverse structural unit and is connected with the second transverse structural unit, and the top surface of the second longitudinal structural unit is not lower than the top surface of the first longitudinal structural unit;

The cavity unit is arranged between the first longitudinal structural unit and the second longitudinal structural unit;

the support unit is arranged on the top of the second longitudinal structural unit;

The lighting unit is arranged at the top of the supporting unit, and the edge of the lighting unit at least covers the outer side of the first longitudinal structural unit;

The liquid collecting unit is arranged in the cavity unit, the bottom of the liquid collecting unit is connected with the second transverse structural unit, the top of the liquid collecting unit is abutted to the bottom of the lighting unit, and the first side of the liquid collecting unit is abutted to the inner side of the first longitudinal structural unit;

The sealing unit is arranged between the liquid collecting unit and the lighting unit, between the supporting unit and the lighting unit, and between the first longitudinal structural unit and the liquid collecting unit and used for sealing.

In some of these embodiments, the first transverse structural unit comprises:

The first transverse structural element is arranged on the building roof, and the inner side of the first transverse structural element is connected with the first longitudinal structural unit and is used for setting the landscape water surface.

In some of these embodiments, the first transverse structural unit further comprises:

A first flashing member arranged to cover an upper surface of the first transverse structural member.

In some of these embodiments, the first longitudinal structural unit comprises:

The first longitudinal structural element is arranged on the inner side of the first transverse structural unit, the top surface of the first longitudinal structural element is higher than the top surface of the first transverse structural unit, and the lighting unit and the sealing unit are arranged on the top of the first longitudinal structural element.

In some of these embodiments, the first longitudinal structural unit further comprises:

And a second waterproof element which is arranged to cover the outer side and the top of the first longitudinal structural element and is connected to the first transverse structural unit.

In some of these embodiments, the second transverse structural unit comprises:

A second transverse structural element arranged inside the first longitudinal structural unit and connected to the bottom of the first longitudinal structural unit, the inside of the second transverse structural element being connected to the second longitudinal structural unit;

And the connecting element penetrates through the second transverse structural element and is connected with the liquid collecting unit.

In some of these embodiments, the second longitudinal structural unit comprises:

the second longitudinal structural element is arranged on the inner side of the second transverse structural unit and is connected with the second transverse structural unit, the top surface of the second longitudinal structural element is not lower than the top surface of the first longitudinal structural unit, and the top of the second longitudinal structural element is provided with the supporting unit.

In some of these embodiments, the cavity unit includes:

The cavity element is arranged between the first longitudinal structural unit and the second longitudinal structural unit, and the liquid collecting unit is arranged in the cavity element.

In some of these embodiments, the support unit includes:

The support element is arranged at the top of the second longitudinal structural unit, and the lighting unit and the sealing unit are arranged at the top of the support element.

In some of these embodiments, the lighting unit comprises:

The daylighting element is arranged at the top of the supporting unit, the edge of the daylighting element at least covers the outer side of the first longitudinal structural unit, and the sealing unit is arranged at the bottom of the daylighting element.

In some of these embodiments, the liquid collection unit includes:

The liquid collecting element is arranged in the cavity unit, the top of the liquid collecting element is in contact with the bottom of the lighting unit, the outer side of the liquid collecting element is in contact with the inner side of the first longitudinal structural unit, and the sealing unit is arranged at the top and the side of the liquid collecting element;

The liquid draining element is arranged at the bottom of the liquid collecting element and communicated with the liquid collecting element, and the bottom of the liquid draining element is connected with the second transverse structural unit.

In some of these embodiments, the sealing unit comprises:

The first sealing element is arranged between the supporting unit and the lighting unit;

The second sealing element is arranged between the liquid collecting unit and the lighting unit;

And a third sealing element disposed between the liquid collection unit and the first longitudinal structural unit.

In a second aspect, there is provided a building comprising:

Building roof;

The waterscape lighting well structure of the first aspect, wherein the waterscape lighting well structure is arranged in the building roof.

Compared with the prior art, the utility model has the following technical effects:

According to the anti-leakage waterscape lighting well structure and building, the first longitudinal structural unit, the second transverse structural unit and the second longitudinal structural unit are arranged on the inner side of the first transverse structural unit and are combined into the U-shaped groove, so that the cavity unit is formed inside to be used for placing the liquid collecting unit, liquid can be discharged through the liquid collecting unit when water seepage occurs, or the liquid collecting amount inside the cavity unit can be detected and maintained in time, and meanwhile, the phenomenon that a suspended ceiling collapses due to rapid infiltration of water into a room can be avoided; under the long-time water collecting state of ground water scenery, thereby also accessible detects the liquid collection volume of the inside of cavity unit and knows the phenomenon of leaking in the very first time, has solved daylighting well waterproof just by rubber pad and sealant, and diffusion is faster when taking place the infiltration phenomenon influences indoor space safety, needs periodic drainage to beat the higher scheduling problem of gluing maintenance cost.

Drawings

FIG. 1 is a schematic diagram of a prior art waterscape lighting well structure;

FIG. 2 is a schematic diagram of a waterscape lighting well structure according to an embodiment of the present utility model;

FIG. 3 is a schematic view of a first transverse structural unit according to an embodiment of the present utility model;

FIG. 4 is a schematic view of a first longitudinal structural unit according to an embodiment of the present utility model;

FIG. 5 is a schematic illustration of a second transverse structural unit according to an embodiment of the present utility model;

FIG. 6 is a schematic view of a second longitudinal structural unit according to an embodiment of the present utility model;

FIG. 7 is a schematic diagram of a cavity unit according to an embodiment of the utility model;

fig. 8 is a schematic view of a supporting unit according to an embodiment of the present utility model;

FIG. 9 is a schematic view of a lighting unit according to an embodiment of the utility model;

fig. 10 is a schematic view of a liquid collection unit according to an embodiment of the utility model;

FIG. 11 is a schematic view of a sealing unit according to an embodiment of the utility model;

fig. 12 is a schematic view of a building according to an embodiment of the utility model.

Wherein the reference numerals are as follows: 100. building roof;

200. A water scenery lighting well structure;

210. A first transverse structural unit; 211. A first transverse structural element; 212. A first waterproof element;

220. a first longitudinal structural unit; 221. A first longitudinal structural element; 222. A second waterproof element;

230. A second transverse structural unit; 231. A second transverse structural element; 232. A connecting element;

240. a second longitudinal structural unit; 241. A second longitudinal structural element;

250. A cavity unit; 251. A cavity element;

260. a supporting unit; 261. A support element;

270. a lighting unit; 271. A lighting element;

280. A liquid collecting unit; 281. A liquid collecting element; 282. A liquid discharge element;

290. A sealing unit; 291. a first sealing element; 292. a second sealing element; 293. and a third sealing element.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

It should be noted that, without conflict, the embodiments of the present utility model and features of the embodiments may be combined with each other.

The utility model is further described below with reference to the drawings and specific examples, which are not intended to be limiting.

Example 1

The embodiment relates to a water scene lighting well structure.

An exemplary embodiment of the present utility model, as shown in fig. 2, a water scene lighting well structure 200 for preventing leakage, includes a first transverse structural unit 210, a first longitudinal structural unit 220, a second transverse structural unit 230, a second longitudinal structural unit 240, a cavity unit 250, a supporting unit 260, a lighting unit 270, a liquid collecting unit 280, and a sealing unit 290. Wherein, the first transverse structural unit 210 is horizontally arranged on the building roof and is used for setting the landscape water surface; the first longitudinal structural unit 220 is disposed inside the first transverse structural unit 210, and the top surface of the first longitudinal structural unit 220 is higher than the top surface of the first transverse structural unit 210; the second transverse structural unit 230 is disposed inside the first longitudinal structural unit 220 and connected to the bottom of the first longitudinal structural unit 220; the second longitudinal structural unit 240 is disposed inside the second transverse structural unit 230 and connected to the second transverse structural unit 230, and the top surface of the second longitudinal structural unit 240 is not lower than the top surface of the first longitudinal structural unit 220; the cavity unit 250 is disposed between the first and second longitudinal structural units 220 and 240; the support unit 260 is disposed on top of the second longitudinal structural unit 240; the lighting unit 270 is disposed at the top of the supporting unit 260, and the edge of the lighting unit 270 is disposed to cover at least the outer side of the first longitudinal structural unit 220; the liquid collecting unit 280 is arranged in the cavity unit 250, the bottom of the liquid collecting unit 280 is connected with the second transverse structural unit 230, the top of the liquid collecting unit 280 is abutted with the bottom of the lighting unit 270, and one side of the liquid collecting unit 280 is abutted with the inner side of the first longitudinal structural unit 220; the sealing unit 290 is disposed between the liquid collecting unit 280 and the lighting unit 270, between the supporting unit 260 and the lighting unit 270, and between the first longitudinal structural unit 220 and the liquid collecting unit 280, for sealing.

As shown in fig. 3, the first transverse structural unit 210 comprises a first transverse structural element 211. Wherein the first transverse structural element 211 is arranged on the building roof, the inner side of the first transverse structural element 211 is connected with the first longitudinal structural unit 220 for arranging the landscape water surface.

In some of these embodiments, the first transverse structural element 211 is attached to the building roof by means including, but not limited to, cast in place or the like.

The plane of the first transverse structural element 211 is annular.

In some of these embodiments, the first transverse structural element 211 comprises a first transverse structural member, a second transverse structural member, and a filler structural member. Wherein the inner side of the first transverse structural member is connected to the bottom of the first longitudinal structural unit 220; the second transverse structural member is located above the first transverse structural member and is connected to the middle of the first longitudinal structural unit 220; the filler member is located between the first and second transverse structural members.

In some of these embodiments, the outer contour shape of the first transverse structural element 211 includes, but is not limited to, a circle.

In some of these embodiments, the first transverse structural element 211 includes, but is not limited to, a reinforced concrete slab or the like.

Further, the first transverse structural unit 210 further comprises a first waterproofing element 212. Wherein a first flashing element 212 is arranged covering the upper surface of the first transverse structural element 211.

The dimensions of the first flashing element 212 match the dimensions of the first transverse structural element 211. Generally, the radial dimension of the first flashing element 212 is equal to the radial dimension of the first transverse structural element 211.

In some of these embodiments, the first waterproofing element 212 includes, but is not limited to, a waterproofing mortar, a waterproofing roll, and the like.

As shown in fig. 4, the first longitudinal structural unit 220 comprises a first longitudinal structural element 221. The first longitudinal structural element 221 is disposed on the inner side of the first transverse structural unit 210, the top surface of the first longitudinal structural element 221 is higher than the top surface of the first transverse structural unit 210, and the top of the first longitudinal structural element 221 is provided with an opening unit, a lighting unit 270, and a sealing unit 290.

Specifically, the first longitudinal structural element 221 is arranged inside the first transverse structural element 211, the top surface of the first longitudinal structural element 221 being arranged higher than the top surface of the first transverse structural element 211.

In some of these embodiments, the first longitudinal structural element 221 is connected to the first transverse structural element 211 by a means including, but not limited to, cast in place, and the like.

The plane of the first longitudinal structural element 221 is annular.

The dimensions of the first longitudinal structural element 221 match those of the first transverse structural element 211. Generally, the radial dimension of the outer contour of the first longitudinal structural element 221 is equal to the radial dimension of the inner contour of the first transverse structural element 211, the height of the first longitudinal structural element 221 being greater than the thickness of the first transverse structural element 211.

In some of these embodiments, the first longitudinal structural element 221 includes, but is not limited to, a reinforced concrete beam.

Further, the first longitudinal structural unit 220 further comprises a second waterproof element 222. Wherein a second flashing member 222 is arranged covering the outer side and the top of the first longitudinal structural element 221 and is connected to the first transverse structural unit 210.

Specifically, the second waterproof element 222 is connected to the first waterproof element 212.

In some of these embodiments, the second flashing member 222 is integrally formed with the first flashing member 212.

The second flashing member 222 is dimensioned to match the dimensions of the first longitudinal structural member 221. In general, the height of the second flashing member 222 is equal to the distance from the top surface of the first longitudinal structural member 221 to the top surface of the first transverse structural member 211.

The second flashing member 222 is sized to match the size of the first flashing member 212. Generally, the thickness of the second flashing member 222 is equal to the thickness of the first flashing member 212.

In some of these embodiments, the second waterproof element 222 includes, but is not limited to, waterproof mortar, waterproof roll, and the like.

As shown in fig. 5, the second transverse structural unit 230 comprises a second transverse structural element 231 and a connecting element 232. Wherein the second transverse structural element 231 is arranged inside the first longitudinal structural unit 220 and is connected to the bottom of the first longitudinal structural unit 220, the inside of the second transverse structural element 231 being connected to the second longitudinal structural unit 240; the connection element 232 is arranged at the second transverse structural element 231 and is connected to the liquid collecting unit 280.

In particular, the second transverse structural element 231 is arranged inside the first longitudinal structural element 221 and is connected to the bottom of the first longitudinal structural element 221.

The outer end of the second transverse structural element 231 is connected to the bottom of the inner end of the first longitudinal structural element 221. I.e. the bottom of the second transverse structural element 231 is coplanar with the bottom of the first longitudinal structural element 221.

In some of these embodiments, the second transverse structural member 231 is connected to the first longitudinal structural member 221 by a means including, but not limited to, cast in place, and the like.

The planar shape of the second transverse structural element 231 is annular.

The dimensions of the second transverse structural element 231 match those of the first longitudinal structural element 221. Generally, the thickness of the second transverse structural element 231 is smaller than the height of the first longitudinal structural element 221, the radial dimension of the outer contour of the second transverse structural element 231 being equal to the radial dimension of the inner contour of the first longitudinal structural element 221.

In some of these embodiments, the second transverse structural element 231 includes, but is not limited to, a reinforced concrete slab.

The connection element 232 is arranged through the upper and lower surfaces of the second transverse structural element 231.

In some of these embodiments, the number of connecting elements 232 is a number. A plurality of connecting elements 232 are spaced apart along the length of the second transverse structural element 231.

The dimensions of the connecting element 232 are matched to the dimensions of the second transverse structural element 231. Generally, the radial dimension of the connecting element 232 is smaller than the width of the second transverse structural element 231.

In some of these embodiments, the cross-sectional shape of the connecting element 232 is circular.

In some of these embodiments, the connection element 232 is a mounting hole.

As shown in fig. 6, the second longitudinal structural unit 240 comprises a second longitudinal structural element 241. The second longitudinal structural element 241 is disposed inside the second transverse structural unit 230 and is connected to the second transverse structural unit 230, the top surface of the second longitudinal structural element 241 is not lower than the top surface of the first longitudinal structural unit 220, and the top of the second longitudinal structural element 241 is provided with a supporting unit 260.

Specifically, the second longitudinal structural element 241 is disposed inside the second transverse structural element 231 and is connected to the second transverse structural element 231, and the top surface of the second longitudinal structural element 241 is disposed not lower than the top surface of the first longitudinal structural element 221.

The bottom of the outboard end of the second longitudinal structural element 241 is connected to the inboard end of the second transverse structural element 231. I.e. the bottom of the second longitudinal structural element 241 is coplanar with the bottom of the second transverse structural element 231.

In some of these embodiments, the second longitudinal structural element 241 is connected to the second transverse structural element 231 by means including, but not limited to, cast in place, and the like.

The plane of the second longitudinal structural element 241 is annular.

The dimensions of the second longitudinal structural element 241 match those of the second transverse structural element 231. Generally, the radial dimension of the outer contour of the second longitudinal structural element 241 is equal to the radial dimension of the inner contour of the second transverse structural element 231.

The dimensions of the second longitudinal structural element 241 match those of the first longitudinal structural element 221. Generally, the height of the second longitudinal structural element 241 is not less than the height of the first longitudinal structural element 221.

In some of these embodiments, the second longitudinal structural element 241 includes, but is not limited to, a reinforced concrete beam.

As shown in fig. 7, the cavity unit 250 includes a cavity member 251. Wherein, the cavity member 251 is disposed between the first longitudinal structural unit 220 and the second longitudinal structural unit 240, and the liquid collecting unit 280 is disposed inside the cavity member 251.

Specifically, the cavity element 251 is disposed between the first longitudinal structural element 221 and the second longitudinal structural element 241.

The dimensions of the cavity element 251 match those of the second transverse structural element 231. Generally, the width of the cavity member 251 is equal to the width of the second transverse structural member 231.

The dimensions of the cavity element 251 match those of the second longitudinal structural element 241. Generally, the height of the cavity element 251 is equal to the height of the second longitudinal structural element 241.

In some of these embodiments, the cavity element 251 is a sump.

As shown in fig. 8, the support unit 260 includes a support member 261. The supporting element 261 is disposed on top of the second longitudinal structural unit 240, and a lighting unit 270 and a sealing unit 290 are disposed on top of the supporting element 261.

In particular, the support element 261 is arranged on top of the second longitudinal structural element 241.

In some of these embodiments, the support element 261 is connected with the second longitudinal structural element 241 by a metal embedment.

The plane of the support element 261 is annular.

The dimensions of the support element 261 match those of the second longitudinal structural element 241. Generally, the radial dimension of the outer contour of the support element 261 is not greater than the radial dimension of the outer contour of the second longitudinal structural element 241, and the radial dimension of the inner contour of the support element 261 is not less than the radial dimension of the inner contour of the second longitudinal structural element 241.

In some of these embodiments, the support element 261 includes, but is not limited to, a metal square.

As shown in fig. 9, the lighting unit 270 includes a lighting element 271. Wherein, the lighting element 271 is disposed at the top of the supporting unit 260, the edge of the lighting element 271 is disposed at least covering the outer side of the first longitudinal structural unit 220, and the bottom of the lighting element 271 is provided with the sealing unit 290.

Specifically, the lighting element 271 is disposed on top of the support element 261, and an edge of the lighting element 271 is disposed to cover at least an outer side of the first longitudinal structural element 221.

The plane of the lighting element 271 is plate-shaped.

The inner edge of the lighting element 271 protrudes inside the second longitudinal structural element 241.

The size of the lighting element 271 matches the size of the first longitudinal structural element 221. Generally, the radial dimension of the lighting element 271 is not smaller than the radial dimension of the outer contour of the first longitudinal structural element 221.

In some of these embodiments, the planar shape of the light element 271 includes, but is not limited to, a circle.

In some of these embodiments, the lighting element 271 includes, but is not limited to, tempered glass or the like.

As shown in fig. 10, the liquid collecting unit 280 includes a liquid collecting element 281 and a liquid discharging element 282. Wherein, the liquid collecting element 281 is arranged in the cavity unit 250, the top of the liquid collecting element 281 is abutted with the bottom of the lighting unit 270, the inner side of the liquid collecting element 281 is abutted with the inner side of the first longitudinal structural unit 220, and the top and the side of the liquid collecting element 281 are provided with the sealing unit 290; the drain member 282 is provided at the bottom of the liquid collecting member 281 and communicates with the liquid collecting member 281, and the bottom of the drain member 282 is connected to the second lateral structure unit 230.

Specifically, the liquid collecting element 281 is disposed inside the cavity element 251, the top of the liquid collecting element 281 is in contact with the bottom of the lighting element 271, and one side of the liquid collecting element 281 is in contact with the inner side of the first longitudinal structural element 221; the bottom of the drain member 282 is connected to the connecting member 232.

In some of these embodiments, the plenum 281 is attached to the outside of the second longitudinal structural element 241 by screws.

The liquid collecting element 281 has a ring shape in its plane.

The size of the plenum 281 matches the size of the first longitudinal structural element 221. Generally, the radial dimension of the outer contour of the plenum 281 is equal to the radial dimension of the inner contour of the first longitudinal structural element 221.

The size of the plenum 281 matches the size of the second longitudinal structural element 241. Generally, the radial dimension of the inner contour of the plenum 281 is equal to the radial dimension of the outer contour of the second longitudinal structural element 241.

Generally, the height of the plenum 281 is greater than the difference between the height of the second longitudinal structural element 241 and the height of the first longitudinal structural element 221 (i.e., the difference in height of the second longitudinal structural element 241 and the first longitudinal structural element 221).

In some of these embodiments, the liquid collection element 281 is U-shaped in cross-section. Specifically, the open end of the liquid collecting element 281 abuts against the bottom of the lighting element 271, and the closed end of the liquid collecting element 281 is provided inside the cavity element 251.

In some of these embodiments, the liquid collection element 281 includes, but is not limited to, a metallic water sump, a PVC water sump, and the like.

In some of these embodiments, the drain member 282 is coupled to the plenum member 281 by, but not limited to, welding, etc.

In some of these embodiments, the liquid discharge element 282 is a plurality. The plurality of drainage members 282 are spaced along the length of the plenum 281.

The number of drainage elements 282 matches the number of connection elements 232. Generally, the number of the liquid discharging elements 282 is equal to the number of the connecting elements 232, i.e., the liquid discharging elements 282 are in one-to-one correspondence with the connecting elements 232.

The drain member 282 is sized to match the size of the connecting member 232. Generally, the radial dimension of the drain member 282 is equal to the radial dimension of the connecting member 232.

The drain member 282 is sized to mate with the first longitudinal structural member 221. Generally, the length of the drainage member 282 is greater than the height of the first longitudinal structural member 221.

In some of these embodiments, the drain member 282 includes, but is not limited to, a metal drain, a PVC drain, and the like.

As shown in fig. 11, the sealing unit 290 includes a first sealing element 291, a second sealing element 292, and a third sealing element 293. Wherein the first sealing element 291 is disposed between the support unit 260 and the lighting unit 270; the second sealing member 292 is disposed between the liquid collecting unit 280 and the lighting unit 270; the third sealing member 293 is disposed between the liquid collecting unit 280 and the first longitudinal structural unit 220.

Specifically, the first sealing element 291 is disposed between the support element 261 and the lighting element 271; the second sealing member 292 is disposed between the liquid collecting member 281 and the lighting member 271; the third sealing element 293 is arranged between the plenum 281 and the first longitudinal structural element 221.

In some of these embodiments, the first sealing element 291 is adhesively bonded to the support element 261 and the lighting element 271 by its own material.

The plane of the first sealing element 291 is annular.

The size of the first sealing element 291 matches the size of the supporting element 261. Generally, the radial dimension of the first sealing element 291 is equal to the radial dimension of the support element 261, and the cross-sectional width of the first sealing element 291 is equal to the cross-sectional width of the support element 261.

In some of these embodiments, the first sealing element 291 includes, but is not limited to, a silicone structural weatherable adhesive.

In some of these embodiments, the second sealing element 292 is adhesively bonded to the liquid collection element 281 and the light collection element 271 by its own material.

The plane of the second sealing member 292 is annular.

The second seal member 292 is sized to match the size of the plenum member 281. Generally, the radial dimension of the second sealing element 292 is equal to the radial dimension of the outer contour of the plenum element 281.

In some of these embodiments, the second sealing element 292 includes, but is not limited to, a silicone structural weatherable adhesive.

In some of these embodiments, the third seal member 293 is adhesively bonded to the plenum member 281 and the first longitudinal structural member 221 by its own material.

The plane of the third seal member 293 is annular.

The dimensions of the third sealing element 293 match those of the first longitudinal structural element 221. Generally, the radial dimension of the third seal element 293 is equal to the radial dimension of the inner profile of the first longitudinal structural element 221.

In some of these embodiments, the third sealing element 293 includes, but is not limited to, a silicone structural weatherable adhesive.

The construction method of the utility model comprises the following steps:

Sequentially pouring a first transverse structural element 211, a first longitudinal structural element 221, a second transverse structural element 231 and a second longitudinal structural element 241 on the building roof, and respectively covering the upper surface of the first transverse structural element 211 and the outer surface of the first longitudinal structural element 221 with a first waterproof element 212 and a second waterproof element 222;

Mounting a support element 261 to the top of the second longitudinal structural element 241;

Placing the drain member 282 inside the cavity member 251 and in connection with the connecting member 232, and then placing the plenum member 281 inside the cavity member 251 and in fixed connection with the side portion of the second longitudinal structural member 241 while in communication with the drain member 282, the top of the plenum member 281 being disposed flush with the top of the support member 261;

After the first sealing element 291 is smeared on the top of the supporting element 261, the lighting element 271 is placed on the top of the supporting element 261, the bottom of the lighting element 271 is respectively propped against the supporting element 261 and the liquid collecting element 281, and the outer edge of the lighting element 271 covers the outer edge of the first longitudinal structural element 221;

The second sealing element 292 is filled at the junction of the liquid collecting element 281 and the lighting element 271, and the third sealing element 293 is filled at the junction of the liquid collecting element 281 and the first longitudinal structural element 221;

finally, water is injected into the waterscape lighting well structure 200 until the water surface is over the top surface of the lighting element 271.

The application method of the utility model is as follows:

1) As the second seal member 292 ages, water seeps:

the leaked water enters the liquid collecting element 281 and is discharged into the collecting facility in the basement through the liquid discharging element 282;

2) When the third seal member 293 ages to cause water penetration:

The leaked water enters the cavity member 251 to timely detect the liquid collection amount inside the cavity member 251, so that the third sealing member 293 can be timely repaired.

The utility model has the advantages that: the inner side of the first transverse structural unit is provided with the first longitudinal structural unit, the second transverse structural unit and the second longitudinal structural unit, the first longitudinal structural unit, the second transverse structural unit and the second longitudinal structural unit are combined into the U-shaped groove, so that the cavity unit is formed inside to be used for accommodating the liquid collecting unit, liquid can be discharged through the liquid collecting unit when water seepage occurs, or the liquid collecting amount inside the cavity unit can be detected and timely maintained, the first longitudinal structural unit, the second transverse structural unit and the second longitudinal structural unit are arranged on the inner side of the first transverse structural unit, the U-shaped groove is combined into the U-shaped groove, so that the cavity unit is formed inside to be used for accommodating the liquid collecting unit, the liquid can be discharged through the liquid collecting unit when water seepage occurs, or the liquid collecting amount inside the cavity unit can be detected and timely maintained, and meanwhile suspended ceiling collapse caused by rapid water seepage into a room can be avoided; under the long-time water collecting state of ground water scenery, thereby also accessible detects the liquid collection volume of the inside of cavity unit and knows the phenomenon of leaking in the very first time, has solved daylighting well waterproof just by rubber pad and sealant, and diffusion is faster when taking place the infiltration phenomenon influences indoor space safety, needs periodic drainage to beat the higher scheduling problem of gluing maintenance cost.

Example 2

This embodiment relates to a building of the present utility model.

As shown in fig. 12, a building includes a building roof and a waterscape lighting well structure 200 as described in example 1. Wherein the waterscape lighting well structure 200 is disposed inside the architectural roof 100.

The foregoing description is only illustrative of the preferred embodiments of the present utility model and is not to be construed as limiting the scope of the utility model, and it will be appreciated by those skilled in the art that equivalent substitutions and obvious variations may be made using the description and illustrations of the present utility model, and are intended to be included within the scope of the present utility model.

Claims (10)

1. An antiseep waterscape daylighting well structure, characterized by comprising:

The first transverse structural unit is horizontally arranged on the building roof and is used for setting a landscape water surface;

The first longitudinal structural unit is arranged on the inner side of the first transverse structural unit, and the top surface of the first longitudinal structural unit is higher than the top surface of the first transverse structural unit;

The second transverse structural unit is arranged on the inner side of the first longitudinal structural unit and is connected with the bottom of the first longitudinal structural unit;

The second longitudinal structural unit is arranged on the inner side of the second transverse structural unit and is connected with the second transverse structural unit, and the top surface of the second longitudinal structural unit is not lower than the top surface of the first longitudinal structural unit;

The cavity unit is arranged between the first longitudinal structural unit and the second longitudinal structural unit;

the support unit is arranged on the top of the second longitudinal structural unit;

The lighting unit is arranged at the top of the supporting unit, and the edge of the lighting unit at least covers the outer side of the first longitudinal structural unit;

The liquid collecting unit is arranged in the cavity unit, the bottom of the liquid collecting unit is connected with the second transverse structural unit, the top of the liquid collecting unit is abutted to the bottom of the lighting unit, and the first side of the liquid collecting unit is abutted to the inner side of the first longitudinal structural unit;

The sealing unit is arranged between the liquid collecting unit and the lighting unit, between the supporting unit and the lighting unit, and between the first longitudinal structural unit and the liquid collecting unit and used for sealing.

2. The waterscape lighting well structure of claim 1, wherein the first transverse structural unit comprises:

A first transverse structural element, the first transverse structural element being arranged on the building roof, the inner side of the first transverse structural element being connected to the first longitudinal structural unit for arranging the landscape water surface; and/or

The first longitudinal structural unit comprises:

The first longitudinal structural element is arranged on the inner side of the first transverse structural unit, the top surface of the first longitudinal structural element is higher than the top surface of the first transverse structural unit, and the lighting unit and the sealing unit are arranged on the top of the first longitudinal structural element.

3. The waterscape lighting well structure of claim 2, wherein the first transverse structural unit further comprises:

A first flashing member arranged to cover an upper surface of the first transverse structural member; and/or

The first longitudinal structural unit further comprises:

And a second waterproof element which is arranged to cover the outer side and the top of the first longitudinal structural element and is connected to the first transverse structural unit.

4. The waterscape lighting well structure of claim 1, wherein the second transverse structural unit comprises:

A second transverse structural element arranged inside the first longitudinal structural unit and connected to the bottom of the first longitudinal structural unit, the inside of the second transverse structural element being connected to the second longitudinal structural unit;

a connecting element extending through the second transverse structural element and connected to the liquid collection unit; and/or

The second longitudinal structural unit comprises:

the second longitudinal structural element is arranged on the inner side of the second transverse structural unit and is connected with the second transverse structural unit, the top surface of the second longitudinal structural element is not lower than the top surface of the first longitudinal structural unit, and the top of the second longitudinal structural element is provided with the supporting unit.

5. The waterscape lighting well structure of claim 1, wherein the cavity unit comprises:

The cavity element is arranged between the first longitudinal structural unit and the second longitudinal structural unit, and the liquid collecting unit is arranged in the cavity element.

6. The waterscape lighting well structure of claim 1, wherein the supporting unit comprises:

The support element is arranged at the top of the second longitudinal structural unit, and the lighting unit and the sealing unit are arranged at the top of the support element.

7. The waterscape lighting well structure of claim 1, wherein the lighting unit comprises:

The daylighting element is arranged at the top of the supporting unit, the edge of the daylighting element at least covers the outer side of the first longitudinal structural unit, and the sealing unit is arranged at the bottom of the daylighting element.

8. The waterscape lighting well structure of claim 1, wherein the liquid collecting unit comprises:

The liquid collecting element is arranged in the cavity unit, the top of the liquid collecting element is in contact with the bottom of the lighting unit, the outer side of the liquid collecting element is in contact with the inner side of the first longitudinal structural unit, and the sealing unit is arranged at the top and the side of the liquid collecting element;

The liquid draining element is arranged at the bottom of the liquid collecting element and communicated with the liquid collecting element, and the bottom of the liquid draining element is connected with the second transverse structural unit.

9. The waterscape lighting well structure of claim 1, wherein the sealing unit comprises:

The first sealing element is arranged between the supporting unit and the lighting unit;

The second sealing element is arranged between the liquid collecting unit and the lighting unit;

And a third sealing element disposed between the liquid collection unit and the first longitudinal structural unit.

10. A building, comprising:

Building roof;

The waterscape lighting well structure of any one of claims 1 to 9, which is disposed inside the building roof.