A factory building surface rainwater collection apparatus

By installing filter components and raised components in the rainwater harvesting equipment on the factory building surface, the problem of debris blockage caused by exposed water inlets is solved, achieving efficient rainwater filtration and simplified maintenance, ensuring rainwater quality and usage efficiency.

CN224395664UActive Publication Date: 2026-06-23CHUANTIE BUILDING NEW MATERIALS (XUYONG) CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHUANTIE BUILDING NEW MATERIALS (XUYONG) CO LTD
Filing Date
2025-06-03
Publication Date
2026-06-23

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  • Figure CN224395664U_ABST
    Figure CN224395664U_ABST
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Abstract

The utility model discloses a factory building surface rainwater collection equipment, including rainwater collection box, main connecting sleeve, water inlet component, filter component, raise component, raise board and gasket, this rainwater collection box is located in the factory building for the storage collection rainwater, this main connecting sleeve sets up on rainwater collection box and is located the surface of factory building, the top of main connecting sleeve is connected with water inlet component, this filter component is inserted in the bottom of main connecting sleeve, the utility model not only has the filter component for filtering large particle impurity garbage in the main connecting sleeve, and sets up the raise component in the circumferential side of filter component, and the raise component will make the water that enters the main connecting sleeve to appear the slope difference when using, and the part between raise component and filter component will accumulate certain fine sand at this moment, and the probability of garbage appearing in the main connecting sleeve is further reduced.
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Description

Technical Field

[0001] This utility model relates to the field of rainwater harvesting technology, specifically to a rainwater harvesting device for factory building surfaces. Background Technology

[0002] Factory building surface rainwater harvesting equipment refers to devices that systematically collect, filter, store, and reuse natural precipitation through the exterior surfaces of buildings such as roofs, walls, and floors. The aim is to achieve sustainable equipment that can recycle water resources, reduce municipal drainage pressure, and lower factory water costs.

[0003] Currently available rainwater harvesting equipment for factory buildings stores collected rainwater in a rainwater collection tank via a main connecting sleeve and connecting conduit for subsequent distribution. However, since the inlet is exposed on the factory building surface during rainwater collection, large particles of debris can accumulate in the rainwater collection tank, causing blockages and siltation in the connecting conduit. Utility Model Content

[0004] The purpose of this utility model is to provide a rainwater collection device for factory building surfaces, in order to solve the problem mentioned in the background art that, because the inlet of the rainwater collection device is exposed on the factory building surface during rainwater collection, large particles of garbage will appear in the rainwater collection tank, causing blockage and sludge accumulation in the connecting pipe.

[0005] To achieve the above objectives, this utility model provides the following technical solution: a rainwater collection device for factory building surfaces, comprising a rainwater collection tank, a main connecting sleeve, a water inlet component, a filter component, a lifting component, a lifting plate, and a gasket; the rainwater collection tank is located inside the factory building for storing collected rainwater; the main connecting sleeve is disposed on the rainwater collection tank on the surface of the factory building, and the top of the main connecting sleeve is connected to the water inlet component; the filter component is inserted into the bottom of the main connecting sleeve, and the lifting component is connected to the periphery of the filter component located inside the main connecting sleeve; the lifting component includes a lifting plate connected to the periphery of the filter component, and a gasket is connected to the outer periphery of the top of the lifting plate, the gasket abuts against the water inlet component, the plane where the highest point of the lifting plate is located is coplanar with the plane where the highest point of the water inlet component is located, and a gap is formed between the gasket and the filter component for water to flow through.

[0006] Preferably, the water inlet component includes a flared opening connected to the top of the main connecting sleeve, and the plane where the highest point of the flared opening is located is coplanar with the plane where the highest point of the washer is located.

[0007] Preferably, a mounting plate is connected inside the horn opening, and the mounting plate and the filter component are detachably connected.

[0008] Preferably, the filter component includes a connecting plate detachably connected to the top of the mounting plate, the top of the connecting plate being connected to the bottom of the raised plate.

[0009] Preferably, the connecting plate is located at the top of the raised plate and is also connected to a side plate, and the top of the side plate is connected to a filter plate.

[0010] Preferably, the plane containing the highest point of the filter plate and the plane containing the highest point of the gasket are coplanar.

[0011] Preferably, the bottom of the main connecting sleeve is connected to a connecting conduit, and the other end of the connecting conduit is connected to the rainwater collection box, and the main connecting sleeve, the connecting conduit, and the rainwater collection box are connected in a continuous manner.

[0012] Preferably, a side connecting sleeve is connected to one side of the main connecting sleeve, and a sealing sleeve is fitted onto the end of the side connecting sleeve away from the main connecting sleeve.

[0013] Compared with the prior art, the beneficial effects of this utility model are: This kind of rainwater collection equipment for factory building surfaces not only has a filter component for filtering large particles of impurities and garbage installed in the main connecting sleeve, but also has a lifting component installed around the filter component. When in use, the lifting component will create a slope difference for the water entering the main connecting sleeve. At this time, a certain amount of fine sand will accumulate between the lifting component and the filter component, further reducing the probability of garbage in the main connecting sleeve. Attached Figure Description

[0014] Figure 1 This is a schematic diagram of the main structure of this utility model;

[0015] Figure 2 This is a schematic diagram of a partial explosion structure of the present invention;

[0016] Figure 3 This is a schematic diagram of the filter component structure of this utility model;

[0017] Figure 4 This is a schematic diagram of the lifting component structure of this utility model;

[0018] Figure 5 This is a schematic diagram of the system framework structure of this utility model.

[0019] In the picture:

[0020] 1. Rainwater collection tank; 11. Connecting conduit; 12. Side connecting sleeve; 2. Main connecting sleeve; 3. Water inlet component; 31. Mounting plate; 32. Flared mouth; 4. Filter component; 41. Connecting plate; 42. Filter plate; 43. Side plate; 5. Lifting component; 51. Lifting plate; 52. Washer. Detailed Implementation

[0021] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0022] Example 1

[0023] like Figure 1-5 As shown, a rainwater harvesting device for factory building surfaces includes a rainwater collection tank 1, a connecting conduit 11, a main connecting sleeve 2, a water inlet component 3, a filter component 4, a lifting component 5, a lifting plate 51, and a gasket 52. The rainwater collection tank 1 is located inside the factory building and is used to store collected rainwater. During use, the rainwater collection tank 1 is installed inside the factory building to store rainwater collected on the factory building surface. To prevent the rainwater collection tank 1 from being corroded by rainwater, a non-toxic waterproof coating should be applied inside the rainwater collection tank 1 to reduce the phenomenon of secondary pollution of rainwater. At the same time, the rainwater collection tank 1 also has a multi-stage filtration device for filtering rainwater to ensure that the rainwater meets the standards for subsequent use. The main connecting sleeve 2 is set on the rainwater collection tank 1 and is located on the surface of the factory building. The main connecting sleeve 2 is set on the top of the factory building to receive rainwater, and the top of the main connecting sleeve 2 is connected to the water inlet component 3.

[0024] In order to perform primary filtration of rainwater entering the main connecting sleeve 2 and the water inlet component 3 and reduce the probability of blockage and siltation in the connecting conduit 11, a filter component 4 is inserted into the bottom of the main connecting sleeve 2. A lifting component 5 is connected to the periphery of the filter component 4 inside the main connecting sleeve 2. There is a gap between the lifting component 5 and the filter component 4, so that there is a slope difference when the rainwater passes through the filter component 4. The slope difference will cause the rainwater entering the filter component 4 to accumulate fine sand at the position of the lifting component 5, further reducing the sand content of the rainwater in the connecting conduit 11. The fine sand refers to the fine sand mixed when flowing on the building surface.

[0025] The lifting component 5 includes a lifting plate 51 and a washer 52. Specifically, the lifting plate 51 is connected to the periphery of the filter component 4. In use, the lifting plate 51 is as follows: Figure 2 and Figure 4As shown, the conical design increases the water inlet. A washer 52 is connected to the outer periphery of the top of the raised plate 51. The washer 52 abuts against the water inlet component 3, reducing the probability of gaps between the washer 52 and the water inlet component 3, and reducing the phenomenon of rainwater directly entering the connecting pipe 11 through the water inlet component 3. The plane where the highest point of the raised plate 51 is located is coplanar with the plane where the highest point of the water inlet component 3 is located, which facilitates rainwater entering the gap between the filter component 4 and the raised component 5. A gap is formed between the washer 52 and the filter component 4 through which water flows.

[0026] The water inlet component 3 includes a flared mouth 32 and a mounting plate 31. The flared mouth 32 is connected to the top of the main connecting sleeve 2. Both the flared mouth 32 and the washer 52 are tapered to increase the water inlet of the main connecting sleeve 2. The plane where the highest point of the flared mouth 32 is located is coplanar with the plane where the highest point of the washer 52 is located, which facilitates rainwater to enter the connecting pipe 11 through the lifting component 5 and the filter component 4, and to be filtered and stored at the location of the rainwater collection box 1.

[0027] An installation plate 31 is welded inside the flared mouth 32. The installation plate 31 and the filter component 4 are detachably connected, which facilitates the installation of the water inlet component 3 and the filter component 4, and performs filtration of rainwater entering the connecting pipe 11.

[0028] The filter component 4 includes a connecting plate 41, a filter plate 42, and a side plate 43. Specifically, the connecting plate 41 is detachably connected to the top of the mounting plate 31 by bolts. The top of the connecting plate 41 is connected to the bottom of the raised plate 51 to fix the position of the connecting plate 41 for primary filtration of rainwater.

[0029] The connecting plate 41 is located inside the raised plate 51 and is welded to the top of the side plate 43. The side plate 43 and the connecting plate 41 are integrally molded. The top of the side plate 43 is connected to the filter plate 42. The filter plate 42 and the side plate 43 are integrally welded. The filter plate 42 has holes for rainwater filtration.

[0030] The plane where the highest point of the filter plate 42 is located is coplanar with the plane where the highest point of the gasket 52 is located. During use, rainwater will first enter the gap between the lifting plate 51 and the filter plate 42 along the lifting plate 51, and then slowly accumulate through the filter plate 42 into the main connecting sleeve 2. At this time, some of the fine sand in the rainwater will accumulate in the gap between the lifting plate 51 and the filter plate 42, reducing the content of fine sand in the rainwater collection box 1. At the same time, the detachable filter component 4 and water inlet component 3 also facilitate the later cleaning of fine sand.

[0031] The overall effect of this embodiment is that, during use, the rainwater collection box 1 is installed inside the factory building to store rainwater collected from the surface of the factory building. In order to prevent the rainwater collection box 1 from being eroded by rainwater, a non-toxic waterproof coating should be applied to the inside of the rainwater collection box 1 to reduce the phenomenon of secondary pollution of rainwater. At the same time, the rainwater collection box 1 also has a multi-stage filtration device for rainwater filtration to ensure that the rainwater meets the subsequent use standards. When it rains, the rainwater will first enter the gap between the raised plate 51 and the filter plate 42 along the raised plate 51, and then slowly accumulate through the filter plate 42 into the main connecting sleeve 2. At this time, some fine sand in the rainwater will accumulate in the gap between the raised plate 51 and the filter plate 42, reducing the fine sand content in the rainwater collection box 1. At the same time, the detachable filter component 4 and water inlet component 3 also facilitate the later cleaning of fine sand, which refers to the fine sand mixed when flowing on the building surface.

[0032] Example 2

[0033] like Figure 1-5 As shown, a rainwater collection device for factory building surfaces includes a connecting conduit 11 connected to the bottom of the main connecting sleeve 2. The connecting conduit 11 is connected to the main connecting sleeve 2 and the rainwater collection box 1 via flanges, bolts, sealing bandages, etc. During use, rainwater passes through the main connecting sleeve 2 and the connecting conduit 11 to reach the rainwater collection box 1. The other end of the connecting conduit 11 is connected to the rainwater collection box 1, and the main connecting sleeve 2, the connecting conduit 11, and the rainwater collection box 1 are in communication.

[0034] A side connecting sleeve 12 is connected to one side of the main connecting sleeve 2. When in use, the side connecting sleeve 12 is set to one side of the main connecting sleeve 2. If a blockage occurs, a preliminary inspection can be carried out at the position of the side connecting sleeve 12 to reduce the difficulty of maintenance. A sealing sleeve is fitted to the end of the side connecting sleeve 12 away from the main connecting sleeve 2. When not in use, the side connecting sleeve 12 is sealed to reduce the waste of rainwater during collection.

[0035] The effect achieved by the entire second embodiment is that, when in use, the side connecting sleeve 12 is set on one side of the main connecting sleeve 2. When blockage occurs, a preliminary inspection can be carried out at the position of the side connecting sleeve 12, reducing the difficulty of maintenance. When not in use, the side connecting sleeve 12 can be sealed to reduce the waste of rain during collection.

[0036] Working principle: When using the rainwater collection equipment on the building surface of this factory, firstly, the rainwater will enter the gap between the raised plate 51 and the filter plate 42 along the raised plate 51, and then slowly accumulate through the filter plate 42 into the main connecting sleeve 2. At this time, some of the fine sand in the rainwater will accumulate in the gap between the raised plate 51 and the filter plate 42, reducing the content of fine sand in the rainwater collection box 1. At the same time, the detachable filter component 4 and water inlet component 3 also facilitate the later cleaning of fine sand, which refers to the fine sand mixed when flowing on the building surface.

[0037] Secondly, during use, the rainwater collection box 1 will be installed inside the factory building to store the rainwater collected from the surface of the factory building. In order to prevent the rainwater collection box 1 from being corroded by rainwater, a non-toxic waterproof coating should be applied inside the rainwater collection box 1 to reduce the phenomenon of secondary pollution of rainwater. At the same time, the rainwater collection box 1 will also have a multi-stage filtration device for rainwater filtration to ensure that the rainwater meets the standards for subsequent use.

[0038] Finally, when in use, the side connecting sleeve 12 is set on one side of the main connecting sleeve 2. If a blockage occurs, a preliminary inspection can be carried out at the location of the side connecting sleeve 12 to reduce the difficulty of maintenance. When not in use, the side connecting sleeve 12 can be sealed to reduce the waste of rainwater during collection, and finally complete the work of rainwater collection on the surface of the factory building.

[0039] In the description of this utility model, it should be noted that, unless otherwise explicitly specified and limited, the terms "installed," "equipped with," "connected," etc., should be interpreted broadly. For example, "connection" can be a fixed connection, a detachable connection, or an integral connection; it can be a mechanical connection or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium; it can be a connection within two components. For those skilled in the art, the specific meaning of the above terms in this utility model can be understood according to the specific circumstances.

[0040] It will be apparent to those skilled in the art that this invention is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or essential characteristics of this invention. Therefore, the embodiments should be considered illustrative and non-limiting in all respects, and the scope of this invention is defined by the appended claims rather than the foregoing description. Thus, it is intended that all variations falling within the meaning and scope of equivalents of the claims be included within this invention. No reference numerals in the claims should be construed as limiting the scope of the claims.

Claims

1. A rainwater harvesting device for factory building surfaces, characterized in that, include: Rainwater collection tank, located inside the factory building, is used to store collected rainwater; A main connecting sleeve is installed on the surface of the factory building on the rainwater collection tank, and a water inlet component is connected to the top of the main connecting sleeve; A filter component is inserted into the bottom of the main connecting sleeve, and a lifting component is connected to the periphery of the filter component located inside the main connecting sleeve. The lifting component includes a lifting plate connected to the periphery of the filter component. A gasket is connected to the outer periphery of the top of the lifting plate. The gasket abuts against the water inlet component. The plane where the highest point of the lifting plate is located is coplanar with the plane where the highest point of the water inlet component is located. A gap is formed between the gasket and the filter component through which water flows.

2. The rainwater harvesting device for factory building surfaces according to claim 1, characterized in that: The water inlet component includes a flared opening connected to the top of the main connecting sleeve, and the plane where the highest point of the flared opening is located is coplanar with the plane where the highest point of the washer is located.

3. The rainwater harvesting device for factory building surfaces according to claim 2, characterized in that: An installation plate is connected inside the horn opening, and the installation plate and the filter component are detachably connected.

4. A rainwater harvesting device for factory building surfaces according to claim 3, characterized in that: The filter component includes a connecting plate detachably connected to the top of the mounting plate, the top of the connecting plate being connected to the bottom of the raised plate.

5. A rainwater harvesting device for factory building surfaces according to claim 4, characterized in that: The connecting plate is located at the top of the raised plate and is also connected to a side plate, and a filter plate is connected to the top of the side plate.

6. A rainwater harvesting device for factory building surfaces according to claim 5, characterized in that: The plane containing the highest point of the filter plate and the plane containing the highest point of the gasket are coplanar.

7. A rainwater harvesting device for factory building surfaces according to claim 1, characterized in that: The bottom of the main connecting sleeve is connected to a connecting conduit, and the other end of the connecting conduit is connected to the rainwater collection box. The main connecting sleeve, the connecting conduit, and the rainwater collection box are connected in a continuous manner.

8. A rainwater harvesting device for factory building surfaces according to claim 7, characterized in that: A side connecting sleeve is connected to one side of the main connecting sleeve, and a sealing sleeve is fitted onto the end of the side connecting sleeve away from the main connecting sleeve.