CN221567316U - Energy-saving rainwater collecting and discharging mechanism for building - Google Patents

Abstract

The utility model relates to the technical field of rainwater collection, and discloses a building energy-saving rainwater collection and discharge mechanism. According to the utility model, structural components such as the discharging device, the diversion well, the interception net, the top cover, the connecting device, the fixing block, the waterproof block, the convex blocks and the like are arranged, and sand and particulate impurities in rainwater can be intercepted through the discharging device, so that the rainwater can be conveniently treated and utilized, the interception net can be fixed in the diversion well through the positioning assembly, and can be moved out of the diversion well through the moving assembly, so that the effect of conveniently fixing and taking out the interception net is achieved, the problems that the disassembling and assembling mode adopted by the interception net of the rainwater diversion well is complicated, the interception net cannot be conveniently and rapidly fixed and taken out are solved.

Description

Energy-saving rainwater collecting and discharging mechanism for building

Technical Field

The utility model belongs to the technical field of rainwater collection, and particularly relates to a rainwater collection and discharge mechanism with an energy-saving building function.

Background

With the development of the times, the living standard of people is continuously improved, the urban process of China is continuously accelerated, and the collection and utilization of rainwater are particularly important under the condition of insufficient fresh water resources of China.

In life, the use of water resource is too frequent, in order to can practice thrift the water resource, need collect the rainwater and handle the utilization, thereby can use the rainwater diversion well, the rainwater diversion well is excavated a degree of depth below the building or around, the container that the bottom has the hole, filter and purify after the rainwater flows into this container, then the rethread pipeline is carried to the place that needs water, thereby the water resource is saved, the rainwater diversion well filters the rainwater through the interception net of inside, in the process of using, often use rope or iron wire with the interception net fixed on the well mouth of pipe, in order to ensure that it can not remove or slide, it is too troublesome too, use for a long time, need take out the interception net, thereby clear up the debris of inside, and the fixation and the dismantlement of interception net are too loaded down with trivial details, not enough, the problem that above-mentioned technique exists: the interception net of rainwater diversion well adopts the too loaded down with trivial details dismouting mode, and is inconvenient inadequately, can not fix the interception net fast and take out the interception net.

Disclosure of utility model

The present utility model addresses the problems of the prior art by providing a rainwater harvesting and drainage mechanism with energy saving for buildings that overcomes or at least partially addresses the above-described problems.

The utility model is realized in such a way, the energy-saving rainwater collecting and discharging mechanism for the building comprises a discharging device and a connecting device, wherein the discharging device comprises a diversion well, an interception net and a top cover, the surface of the top cover is connected with the top of the inside of the diversion well in an inserting way, the interception net is positioned in the inside of the diversion well, the connecting device comprises two fixing blocks, two waterproof blocks and four protruding blocks, the two waterproof blocks are detachable, the tops of the two fixing blocks are fixedly connected with the top of the interception net, the bottoms of the two waterproof blocks are fixedly connected with the tops of the two fixing blocks, and one side, close to the diversion well, of the four protruding blocks is fixedly connected with the diversion well;

The drainage device is used for collecting rainwater and intercepting sand and particulate impurities in the rainwater;

The connecting device is used for fixing and separating the interception net in the inside of the diversion well.

In order to enable the interception net to be fixed in the inside of the diversion well and be capable of being taken out of the interception net, preferably, the surfaces of the four protruding blocks are all in plug connection with the inside of the two fixing blocks, the left side is provided with a cavity in the inside of the fixing blocks, the inside of the cavity is respectively provided with a positioning component and a moving component, the interception net can be fixed with the diversion well in the inside of the diversion well by arranging the positioning component, and the interception net can be taken out of the inside of the diversion well by arranging the moving component.

For two lugs are fixed after being connected with the fixed block in a plugging manner, preferably, the positioning assembly comprises two positioning blocks, a sliding block and an extrusion spring, the surfaces of the two positioning blocks and the sliding block are movably connected with the inside of the cavity, the right sides of the two positioning blocks are fixedly connected with the left side of the sliding block, the right sides of the extrusion spring are fixedly connected with the right sides of the inner wall of the cavity, the left sides of the extrusion spring are fixedly connected with the right sides of the sliding block, the positioning assembly is arranged, the left sides of the two positioning blocks can move to the inside of the two lugs, the extrusion spring plays a role in fixing and rebounding, and the use of the extrusion spring can enable the sliding block and the two positioning blocks to rebound to the original position automatically after moving.

In order to enable two lugs to be separated from the fixed block, preferably, the moving assembly comprises a moving block, an elastic spring, a rotating rod and a matching block, the surface of the moving block is movably connected with the inside of the cavity, the rear side of the moving block is fixedly connected with the front side of the elastic spring, one side, close to the inner wall of the cavity, of the elastic spring is fixedly connected with the cavity, the right side of the surface of the moving block is tightly contacted with the front side of the rotating rod, the rear side of the inner side of the rotating rod is movably connected with the top of the matching block, the bottom of the matching block is fixedly connected with the bottom of the inner wall of the cavity, the right side of the rotating rod is movably connected with the inner side of the sliding block and tightly contacted with the matching block, the two positioning blocks can be moved out from the inside of the two lugs through the arrangement of the moving assembly, the elastic spring plays a fixing and rebounding role, and the use of the elastic spring can enable the moving block and the rotating rod to rebound to be automatically to the original position after moving.

In order to enable the interception net to be fixed in the shunt well more firmly, preferably, the left sides of the two positioning blocks sequentially penetrate through the fixing block and the two convex blocks through the cavity and extend to the inner parts of the two convex blocks, and the surfaces of the two positioning blocks are in tight contact with the fixing block and the inner parts of the two convex blocks through the two positioning blocks.

In order to enable the sliding block and the two positioning blocks to move better in the cavity, preferably, both front and back sides in the sliding block are slidably connected with limiting rods, the right sides of the two limiting rods are fixedly connected with the right sides of the inner wall of the cavity, and the sliding block and the two positioning blocks can only move leftwards or rightwards in the cavity through the two limiting rods.

In order to enable the moving block to move better in the cavity, preferably, the left side of the moving block is slidingly connected with a trapezoid groove, the trapezoid groove is formed in the left side of the inner wall of the cavity, and the moving block can only move forwards or backwards in the cavity by arranging the trapezoid groove.

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

According to the utility model, structural components such as the discharging device, the diversion well, the interception net, the top cover, the connecting device, the fixing block, the waterproof block, the convex blocks and the like are arranged, sand and stones and particulate impurities in rainwater can be intercepted through the discharging device, so that the rainwater can be conveniently treated and utilized, the interception net can be fixed in the diversion well through the positioning assembly, and the interception net can be moved out of the diversion well through the moving assembly, so that the effects of conveniently fixing the interception net and taking out the interception net are achieved.

Drawings

FIG. 1 is a schematic perspective view of an embodiment of the present utility model;

FIG. 2 is a perspective view of an embodiment of the present utility model providing an interception net;

FIG. 3 is an enlarged view of FIG. 2A provided by an embodiment of the present utility model;

FIG. 4 is a perspective view of a diverter well according to an embodiment of the present utility model;

Fig. 5 is a top cross-sectional view of a securing block provided by an embodiment of the present utility model.

In the figure: 1. a discharge device; 1a, a shunt well; 1b, an interception net; 1c, a top cover; 2. a connecting device; 2a, a fixed block; 2b, waterproof blocks; 2c, a bump; 3. a cavity; 4. a positioning assembly; 401. a positioning block; 402. a slide block; 403. extruding a spring; 5. a moving assembly; 501. a moving block; 502. an elastic spring; 503. a rotating rod; 504. a mating block; 6. a limit rod; 7. a trapezoid groove.

Detailed Description

For a further understanding of the utility model, its features and advantages, reference is now made to the following examples, which are illustrated in the accompanying drawings.

The structure of the present utility model will be described in detail with reference to the accompanying drawings.

As shown in fig. 1 to 5, the energy-saving rainwater collecting and draining mechanism for building provided by the embodiment of the utility model comprises a draining device 1 and a connecting device 2, wherein the draining device 1 comprises a diversion well 1a, an interception net 1b and a top cover 1c, the surface of the top cover 1c is connected with the top of the inside of the diversion well 1a in a plugging manner, the interception net 1b is positioned in the inside of the diversion well 1a, the connecting device 2 comprises two fixed blocks 2a, two waterproof blocks 2b and four protruding blocks 2c, the two waterproof blocks 2b are detachable, the tops of the two fixed blocks 2a are fixedly connected with the top of the interception net 1b, the bottoms of the two waterproof blocks 2b are fixedly connected with the tops of the two fixed blocks 2a, One side of each of the four protruding blocks 2c, which is close to the shunt well 1a, is fixedly connected with the shunt well 1 a; the drainage device 1 is used for collecting rainwater and intercepting sand and particulate impurities in the rainwater; The connecting device 2 is used for fixing and separating the interception net 1b inside the diversion well 1a, in order to fix the interception net 1b inside the diversion well 1a and take out the interception net 1b, preferably, the surfaces of four lugs 2c are all connected with the interiors of two fixing blocks 2a in a plugging manner, a cavity 3 is formed in the left side fixing block 2a, a positioning component 4 and a moving component 5 are respectively arranged in the cavity 3, the interception net 1b inside the diversion well 1a can be fixed with the diversion well 1a by arranging the positioning component 4, the interception net 1b can be taken out from the inside the diversion well 1a by arranging the moving component 5, the two lugs 2c are connected with the fixing blocks 2a in a plugging manner and then fixed, Preferably, the positioning assembly 4 comprises two positioning blocks 401, a sliding block 402 and an extrusion spring 403, the surfaces of the two positioning blocks 401 and the sliding block 402 are movably connected with the inside of the cavity 3, the right sides of the two positioning blocks 401 are fixedly connected with the left side of the sliding block 402, the right side of the extrusion spring 403 is fixedly connected with the right side of the inner wall of the cavity 3, the left side of the extrusion spring 403 is fixedly connected with the right side of the sliding block 402, by arranging the positioning assembly 4, the left sides of the two positioning blocks 401 can move into the inside of the two convex blocks 2c, the extrusion spring 403 plays a role of fixing and rebounding, the use of the extrusion spring 403 can enable the sliding block 402 and the two positioning blocks 401 to rebound to the original position automatically after moving, In order to enable the two protruding blocks 2c to be separated from the fixed block 2a, preferably, the moving assembly 5 comprises a moving block 501, an elastic spring 502, a rotating rod 503 and a matching block 504, the surface of the moving block 501 is movably connected with the inside of the cavity 3, the rear side of the moving block 501 is fixedly connected with the front side of the elastic spring 502, one side of the elastic spring 502 close to the inner wall of the cavity 3 is fixedly connected with the cavity 3, the right side of the surface of the moving block 501 is tightly contacted with the front side of the rotating rod 503, the rear side of the inside of the rotating rod 503 is movably connected with the top of the matching block 504, the bottom of the matching block 504 is fixedly connected with the bottom of the inner wall of the cavity 3, The right side of the rotating rod 503 is movably connected with the inside of the sliding block 402 and closely contacts with the same, through the arrangement of the moving component 5, the two positioning blocks 401 can be moved out from the inside of the two protruding blocks 2c, the elastic spring 502 plays a role in fixing and rebounding, the use of the elastic spring 502 can enable the moving block 501 and the rotating rod 503 to rebound to the original position automatically after moving, in order to enable the fixing of the interception net 1b in the inside of the diversion well 1a to be firmer, preferably, the left sides of the two positioning blocks 401 sequentially penetrate through the fixing block 2a and the two protruding blocks 2c through the cavity 3 and extend to the inside of the two protruding blocks 2c, through the arrangement of the two positioning blocks 401, The surfaces of the two positioning blocks 401 are tightly contacted with the interiors of the fixed block 2a and the two protruding blocks 2c, and in order to better move the sliding block 402 and the two positioning blocks 401 in the cavity 3, preferably, the front side and the rear side of the interior of the sliding block 402 are both in sliding connection with the limiting rods 6, the right sides of the two limiting rods 6 are fixedly connected with the right side of the inner wall of the cavity 3, by arranging the two limiting rods 6, the sliding block 402 and the two positioning blocks 401 can only move in the left direction or the right direction in the cavity 3, in order to better move the moving block 501 in the cavity 3, preferably, the left side of the moving block 501 is in sliding connection with the trapezoid groove 7, The trapezoid groove 7 is formed on the left side of the inner wall of the cavity 3, and the trapezoid groove 7 is formed, so that the moving block 501 can only move in the forward or backward direction in the cavity 3.

The working principle of the utility model is as follows:

When the rainwater collecting device is used, rainwater enters the inside of the diversion well 1a through the top cover 1c, sand and particle impurities in the rainwater can be intercepted by the interception net 1b, so that the rainwater can be discharged through the water outlet of the diversion well 1a, when the inside of the interception net 1b needs to be cleaned, the top cover 1c is moved out firstly, then the waterproof block 2b is removed, the waterproof block 501 is pushed to move backwards through manpower, the rotating rod 503 is enabled to rotate through extrusion in the moving process of the waterproof block 501, the right side of the rotating rod 503 takes the matching block 504 as the center of a circle, the counterclockwise rotation is carried out, the sliding block 402 is enabled to drive the two positioning blocks 401 to move rightwards, and is enabled to move out from the inside of the two protruding blocks 2c, the interception net 1b can be enabled to move upwards and move out from the inside of the diversion well 1a, the elastic spring 502 can be enabled to deform in the moving process, after the moving block 501 is released, the moving block 501 is enabled to rebound to the original position, the pressing spring 403 can be enabled to deform in the moving rightwards under the elastic action of the moving block 501, the moving process of the sliding block 402 is enabled to enable the positioning blocks to be enabled to move outwards, and the two protruding blocks 401 are enabled to be enabled to move inside the two protruding blocks 2c to be enabled to be fixed inside the inside of the diversion net 2a, and the inside of the two protruding blocks 2c are enabled to be fixed to be 2a, and the inside of the diversion net 2b is prevented to be fixed.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The present utility model is not limited to the preferred embodiments, but is not limited to the preferred embodiments described above, and any person skilled in the art will appreciate that the present utility model is not limited to the embodiments described above.

Claims (7)

1. The utility model provides a have energy-conserving rainwater collection drainage mechanism of building, includes discharging equipment (1) and connecting device (2), its characterized in that: the discharging device (1) comprises a diversion well (1 a), an interception net (1 b) and a top cover (1 c), wherein the surface of the top cover (1 c) is connected with the top of the inside of the diversion well (1 a) in an inserting mode, the interception net (1 b) is positioned in the inside of the diversion well (1 a), the connecting device (2) comprises two fixing blocks (2 a), two waterproof blocks (2 b) and four protruding blocks (2 c), the two waterproof blocks (2 b) are detachable, the tops of the two fixing blocks (2 a) are fixedly connected with the top of the interception net (1 b), the bottoms of the two waterproof blocks (2 b) are fixedly connected with the tops of the two fixing blocks (2 a), and one side, close to the diversion well (1 a), of the four protruding blocks (2 c) is fixedly connected with the diversion well (1 a);

The drainage device (1) is used for collecting rainwater and intercepting sand and stones and particulate impurities in the rainwater;

the connecting device (2) is used for fixing and separating the interception net (1 b) inside the diversion well (1 a).

2. A stormwater collecting and draining mechanism with building energy conservation as claimed in claim 1, wherein: the surfaces of the four protruding blocks (2 c) are connected with the interiors of the two fixed blocks (2 a) in a plug-in mode, a cavity (3) is formed in the left side of the fixed block (2 a), and a positioning assembly (4) and a moving assembly (5) are respectively arranged in the cavity (3).

3. A stormwater collecting and draining mechanism with building energy conservation as claimed in claim 2, wherein: the positioning assembly (4) comprises two positioning blocks (401), a sliding block (402) and an extrusion spring (403), wherein the surfaces of the two positioning blocks (401) and the sliding block (402) are movably connected with the inside of the cavity (3), the right sides of the two positioning blocks (401) are fixedly connected with the left side of the sliding block (402), the right side of the extrusion spring (403) is fixedly connected with the right side of the inner wall of the cavity (3), and the left side of the extrusion spring (403) is fixedly connected with the right side of the sliding block (402).

4. A stormwater collecting and draining mechanism with building energy conservation as claimed in claim 3, wherein: the movable assembly (5) comprises a movable block (501), an elastic spring (502), a rotating rod (503) and a matching block (504), wherein the surface of the movable block (501) is movably connected with the inside of the cavity (3), the rear side of the movable block (501) is fixedly connected with the front side of the elastic spring (502), one side, close to the inner wall of the cavity (3), of the elastic spring (502) is fixedly connected with the cavity (3), the right side of the surface of the movable block (501) is tightly contacted with the front side of the rotating rod (503), the rear side of the inner side of the rotating rod (503) is movably connected with the top of the matching block (504), the bottom of the matching block (504) is fixedly connected with the bottom of the inner wall of the cavity (3), and the right side of the rotating rod (503) is movably connected with the inside of the sliding block (402) and is tightly contacted with the inner side of the sliding block (402).

5. A stormwater collecting and draining mechanism with building energy conservation as claimed in claim 3, wherein: the left sides of the two positioning blocks (401) sequentially penetrate through the fixed block (2 a) and the two convex blocks (2 c) through the cavity (3) and extend into the two convex blocks (2 c).

6. A stormwater collecting and draining mechanism with building energy conservation as claimed in claim 3, wherein: both sides all sliding connection has gag lever post (6) around slider (402) inside, the right side of two gag lever posts (6) all with the right side fixed connection of cavity (3) inner wall.

7. A stormwater collecting and draining mechanism with building energy conservation as claimed in claim 4, wherein: the left side sliding of the moving block (501) is connected with a trapezoid groove (7), and the trapezoid groove (7) is arranged on the left side of the inner wall of the cavity (3).