CN213143647U - Energy-saving building drainage system - Google Patents

Abstract

The utility model belongs to the technical field of drainage system and specifically relates to an energy-conserving building drainage system is related to, it is including setting up in the recess in escape canal department, the tank bottom of recess is provided with the outlet, the below intercommunication in outlet has the drain pipe, the top in outlet is provided with filtration, filtration include fixed connection in the support frame of outlet top, the support frame include with the stay tube that the outlet is linked together and set up in the stay tube is kept away from the bracing piece of outlet one end, it locates to rotate on the bracing piece to be connected with the cover the balloon structure of stay tube port department, the outside cover of balloon structure is equipped with the filter mantle, the filter mantle with balloon structure fixed connection. The drainage device has the effect of reducing the phenomenon of blockage in drainage.

Description

Energy-saving building drainage system

Technical Field

The application relates to the field of drainage systems, in particular to an energy-saving building drainage system.

Background

At present, most of house buildings need to be provided with a drainage system, the drainage system can dredge rainwater, accumulated water is prevented from being formed at the top of the building, and rainwater can be prevented from immersing into the internal corrosion wall of the building. Drainage system is through being provided with the escape canal at the top edge of building, and rivers are through escape canal drainage to the outlet, and the filter screen of filtering impurity is installed to the entrance of outlet, and the filter screen can prevent that impurity from getting into the drain pipe and causing the jam.

In view of the above-mentioned related technologies, the inventor believes that there is a defect that impurities are easily accumulated on the filter screen, which causes unsmooth water flow, and when much rainwater is collected in a low place, the filter screen cannot be dredged, which causes water leakage inside the house.

SUMMERY OF THE UTILITY MODEL

In order to reduce the phenomenon of blockage during drainage, the application provides an energy-saving building drainage system.

The application provides an energy-conserving building drainage system adopts following technical scheme:

the utility model provides an energy-conserving building drainage system, is including setting up in the recess of escape canal department, the tank bottom of recess is provided with the outlet, the below intercommunication in outlet has the drain pipe, the top in outlet is provided with filtration, filtration include fixed connection in the support frame of outlet top, the support frame include with the stay tube that the outlet is linked together and set up in the stay tube is kept away from the bracing piece of outlet one end, it locates to rotate to be connected with the cover on the bracing piece the balloon structure of stay tube port department, the outside cover of balloon structure is equipped with the filter mantle, the filter mantle with balloon structure fixed connection.

Through adopting above-mentioned technical scheme, during the rainfall, the rainwater assembles in the escape canal to come everywhere along the escape canal, when a large amount of rainwater flowed to the recess together, the rainwater impacted wind ball structure and discharged after through the filter mantle, and at this in-process, the rainwater promotes wind ball structure and rotates, and wind ball structure drives the filter mantle simultaneously and rotates together, so, impurity around the filter mantle can not always be in the same place with the filter mantle laminating along with the rotation of filter mantle, thereby the phenomenon that is blockked up takes place when reducing the drainage.

Preferably, the wind ball structure includes the ring plate and is located the connection plectane of ring plate top, connection plectane with wind between the ring plate the axis of ring plate is provided with a plurality of arc, the one end of every arc with the edge of connecting the plectane is connected, the other end of arc with the inside wall of ring plate is connected, connection plectane is close to the side of ring plate is followed the axis of ring plate is provided with the dwang, the dwang activity runs through the bracing piece and with the bracing piece rotates to be connected, be provided with the spacing ring on the dwang, work as the spacing ring with when the bracing piece is laminated mutually, the ring plate is kept away from the side of filter mantle with the bracing piece pipe is kept away from the terminal surface in outlet is close to each other.

Through adopting above-mentioned technical scheme, when rainwater strikes wind ball structure, the rainwater passes through the filter house after, discharges from the space between two adjacent arcs behind the arc of direct impact wind ball structure, and the rainwater is decomposable to the impact force of arc obtain with wind ball structure rotation center mutually perpendicular's effort to can promote wind ball structure and rotate, thereby drive the filter house and rotate together.

Preferably, the filter mantle is the hemisphere, the filter mantle with can dismantle the connection through joint structure between the ring board.

Through adopting above-mentioned technical scheme, detachable connection between filter mantle and the ring board is from convenient clearance and maintenance wind ball structure.

Preferably, the joint structure including set up in the plugboard of filter mantle open end, the side of plugboard is provided with first wedge, be provided with on the ring board and be used for pegging graft the mounting groove of plugboard, the mounting groove is close to be provided with the holding tank on the lateral wall of first wedge, the opening part of holding tank is provided with the joint board, the joint board is close to the side of first wedge be provided with the second wedge of first wedge looks butt, the joint board is close to the one end of mounting groove tank bottom articulate in the opening part of holding tank, the joint board is kept away from the side of second wedge with be provided with the spring between the tank bottom of holding tank, the spring is kept away from the hinged end of joint board.

By adopting the technical scheme, when the filter cover is to be taken down, the filter cover is lifted upwards in the direction away from the bottom of the mounting groove, and in the process, the first wedge block abuts against the second wedge block, so that the clamping plate rotates and retracts in the direction of the bottom of the mounting groove until the first wedge block and the second wedge block rub against the shoulder, and the spring pushes the clamping plate to reset; during the installation, directly press the filter mantle for the tank bottom downstream of grafting board type mounting groove, until first wedge second wedge once more rub the shoulder and cross the back, the joint board passes through the spring and resets, thereby forms limiting displacement to the grafting board, thereby locks the filter mantle.

Preferably, the clamping structure is provided with a plurality of groups, and the clamping structure winds the even interval distribution of axis of ring plate.

Through adopting above-mentioned technical scheme, a plurality of group's joint structure makes the connection of filter mantle more stable around the even interval distribution's of axis of ring plate setting up, and intensity is stronger.

Preferably, an extension rod is further arranged on the side face, close to the filter cover, of the connecting circular plate, and one end, far away from the connecting circular plate, of the extension rod is abutted to the filter cover.

Through adopting above-mentioned technical scheme, the setting of extension rod can support the filter mantle, simultaneously for overall structure is more stable.

Preferably, still be provided with the stiffener on the inside wall of ring board, the dwang runs through the stiffener and with stiffener fixed connection.

Through adopting above-mentioned technical scheme, the setting up of stiffener makes the dwang more stable.

Preferably, the height of the support tube is at least half of the height of the filter housing.

Through adopting above-mentioned technical scheme, guarantee all to have longer one end distance between the filter mantle on the support frame and the lowest of recess tank bottom, after the rain stops, some impurity in the rain can fall near the support frame, and can not shield the filter mantle, avoids the staff to come too late the clearance and influence the filter mantle next time the filter effect of end rainwater.

In summary, the present application includes at least one of the following beneficial technical effects:

1. during rainfall, rainwater is gathered in the drainage ditch and comes everywhere along the drainage ditch, when a large amount of rainwater flows into the groove together, the rainwater impacts the wind ball structure and is discharged after passing through the filter cover, in the process, the rainwater pushes the wind ball structure to rotate, and the wind ball structure simultaneously drives the filter cover to rotate together, so that impurities around the filter cover cannot be attached to the filter cover along with the rotation of the filter cover, and the phenomenon of blockage during drainage is reduced;

2. when rainwater impacts the wind ball structure, the rainwater directly impacts the arc plates of the wind ball structure and then is discharged from a gap between two adjacent arc plates after passing through the filter cover, and the impact force of the rainwater on the arc plates can be decomposed to obtain an acting force which is perpendicular to the rotation center of the wind ball structure, so that the wind ball structure can be pushed to rotate, and the filter cover is driven to rotate together;

3. when the filter cover is to be taken down, the filter cover is lifted upwards in the direction far away from the bottom of the mounting groove, in the process, the first wedge block abuts against the second wedge block, so that the clamping plate rotates and retracts in the direction of the bottom of the mounting groove until the first wedge block and the second wedge block rub against the shoulder, and the spring pushes the clamping plate to reset; during the installation, directly press the filter mantle for the tank bottom downstream of grafting board type mounting groove, until first wedge second wedge once more rub the shoulder and cross the back, the joint board passes through the spring and resets, thereby forms limiting displacement to the grafting board, thereby locks the filter mantle.

Drawings

Fig. 1 is a schematic overall structure diagram of an embodiment of the drainage system of an energy-saving building.

Fig. 2 is an exploded view of an embodiment of the drainage system of an energy-saving building according to the present application.

Fig. 3 is a schematic structural diagram of a wind ball structure in an embodiment of the drainage system of the energy-saving building.

Fig. 4 is an enlarged schematic view of a portion a of fig. 2.

Fig. 5 is an enlarged schematic view of a portion B of fig. 2.

Description of reference numerals: 1. a drainage ditch; 11. a groove; 111. a water outlet; 2. a drain pipe; 3. a support frame; 31. supporting a tube; 311. a water through hole; 32. a support bar; 4. a wind ball structure; 41. a circular ring plate; 411. mounting grooves; 412. accommodating grooves; 413. a clamping and connecting plate; 414. a second wedge block; 415. a spring; 42. connecting the circular plate; 43. an arc-shaped plate; 44. rotating the rod; 441. a limiting ring; 442. a nut; 45. a reinforcing bar; 46. an extension pole; 5. a filter housing; 51. a handle; 52. a plugboard; 521. a first wedge block.

Detailed Description

The present application is described in further detail below with reference to figures 1-5.

The embodiment of the application discloses energy-saving building drainage system. Referring to fig. 1 and 2, the energy-saving building drainage system comprises a groove 11 arranged at a drainage ditch 1, the groove 11 is hemispherical, a drainage outlet 111 is arranged at the middle position of the bottom of the groove 11, a drainage pipe 2 is communicated below the drainage outlet 111, the drainage pipe 2 is vertically arranged, a filtering structure is arranged above the drainage outlet 111, the filtering structure comprises a supporting frame 3 fixedly connected above the drainage outlet 111, and the supporting frame 3 comprises a supporting pipe 31 communicated with the drainage outlet 111 and a supporting rod 32 arranged at one end of the supporting pipe 31 far away from the drainage outlet 111. The support pipe 31 is vertically arranged, the support pipe 31 and the water outlet 111 are coaxially arranged, the lower end of the support pipe 31 is fixedly connected with the bottom of the groove 11, and the side wall of the support pipe 31 is provided with a plurality of water through holes 311, so that residual rainwater can flow into the drain pipe 2 through the water through holes 311 without accumulating between the groove 11 and the support pipe 31; the support rod 32 is horizontally arranged, the support rod 32 is in a cross shape, and the end part of the support rod 32 is fixedly connected with the inner side wall of the support pipe 31.

Referring to fig. 2 and 3, the supporting rod 32 is rotatably connected with a wind ball structure 4 covering the port of the supporting tube 31, the outer side of the wind ball structure 4 is covered with a filter cover 5, and the filter cover 5 is fixedly connected with the wind ball structure 4. Specifically, the wind ball structure 4 includes a ring plate 41 horizontally disposed and a connection circular plate 42 located above the ring plate 41, a plurality of arc plates 43 are disposed between the connection circular plate 42 and the ring plate 41 around the central axis of the ring plate 41, one end of each arc plate 43 is connected to the edge of the connection circular plate 42, the other end of each arc plate 43 is connected to the inner side wall of the ring plate 41, a rotation rod 44 is disposed on the side surface of the connection circular plate 42 close to the ring plate 41 along the central axis of the ring plate 41, the rotation rod 44 movably penetrates through the support rod 32 and is rotatably connected to the support rod 32, a limit ring 441 is disposed on the rotation rod 44, and when the limit ring 441 is attached to the support rod 32, the side surface of the ring plate 41 far from the filter housing 5 and the end surface of the support rod 32 far from the water outlet 111. Meanwhile, the rotating rod 44 is further connected with a nut 442 in a threaded manner, and the nut 442 is located below the supporting rod 32 and attached to the supporting rod 32; a reinforcing rod 45 is horizontally arranged on the inner side wall of the circular ring plate 41, and the rotating rod 44 penetrates through the reinforcing rod 45 and is fixedly connected with the reinforcing rod 45.

Referring to fig. 2 and 3, the filter cover 5 is reversely buckled on the circular ring plate 41 of the wind ball structure 4 in a hemispherical shape, a handle 51 is arranged above the outer side of the filter cover 5, and the handle 51 is fixedly connected with the filter cover 5; an extension rod 46 is further arranged on the side face, close to the filter hood 5, of the connecting circular plate 42, the extension rod 46 and the rotating rod 44 are coaxially arranged, and one end, far away from the connecting circular plate 42, of the extension rod 46 is abutted to the filter hood 5; and the height of stay tube 31 is half of the height of filter mantle 5 at least, so, guarantee that all there is longer one end distance between filter mantle 5 on the support frame 3 and the 11 tank bottoms of recess, after the rain stops, some impurity in the rain can fall near support frame 3, and can not shield filter mantle 5, avoid the staff to come too late the clearance and influence the filter effect of filter mantle 5 next time end rainwater.

Referring to fig. 4 and 5, the filter housing 5 is detachably connected to the circular ring plate 41 through a clamping structure. Specifically, the clamping structure comprises a vertically arranged plug board 52 arranged at the opening end of the filter housing 5, a first wedge block 521 is arranged on the side surface of the plug board 52, and a mounting groove 411 for plugging the plug board 52 is arranged on the circular ring plate 41. Be provided with holding tank 412 on the lateral wall that mounting groove 411 is close to first wedge 521, the vertical joint board 413 that is provided with in opening part of holding tank 412, the side that joint board 413 is close to first wedge 521 is provided with the second wedge 414 with first wedge 521 looks butt, the one end that joint board 413 is close to the mounting groove 411 tank bottom articulates in the opening part of holding tank 412, be provided with spring 415 between the side that second wedge 414 is kept away from to joint board 413 and the tank bottom of holding tank 412, the hinged end of joint board 413 is kept away from to spring 415, the one end of spring 415 and the tank bottom fixed connection of holding tank 412, the other end and the joint board 413 fixed connection of spring 415. In this embodiment, the clamping structures are provided with a plurality of groups, and the plurality of groups of clamping structures are uniformly distributed around the central axis of the circular ring plate 41 at intervals.

The implementation principle of the energy-saving building drainage system in the embodiment of the application is as follows: during rainfall, rainwater is collected in the drainage ditch 1 and is distributed along the drainage ditch 1. When the rainwater is less, the rainwater is discharged through the water through hole 311 at the support rod 32; when a large amount of rainwater flow to in the recess 11 together, the rainwater strikes behind the arc 43 of wind ball structure 4 behind the filter mantle 5 and is discharged from the space between two adjacent arcs 43, and at this in-process, the rainwater promotes wind ball structure 4 and rotates, and wind ball structure 4 drives filter mantle 5 simultaneously and rotates together, so, impurity on every side of filter mantle 5 can not be in the same place with filter mantle 5 laminating along with the rotation of filter mantle 5 always to the phenomenon that is blockked up takes place during the reduction drainage.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. An energy-conserving building drainage system which characterized in that: including setting up in recess (11) of escape canal (1) department, the tank bottom of recess (11) is provided with outlet (111), the below intercommunication of outlet (111) has drain pipe (2), the top of outlet (111) is provided with filtration, filtration include fixed connection in support frame (3) of outlet (111) top, support frame (3) include with stay tube (31) that outlet (111) are linked together and set up in stay tube (31) are kept away from bracing piece (32) of outlet (111) one end, it locates to rotate to be connected with the cover on bracing piece (32) the balloon structure (4) of stay tube (31) port department, the outside cover of balloon structure (4) is equipped with filter mantle (5), filter mantle (5) with balloon structure (4) fixed connection.

2. The energy saving building drainage system of claim 1, wherein: wind ball structure (4) include ring plate (41) and are located connect plectane (42) of ring plate (41) top, connect plectane (42) with wind between ring plate (41) the axis of ring plate (41) is provided with a plurality of arc (43), the one end of every arc (43) with the edge of connecting plectane (42) is connected, the other end of arc (43) with the inside wall of ring plate (41) is connected, it is close to connect plectane (42) the side of ring plate (41) is followed the axis of ring plate (41) is provided with dwang (44), dwang (44) activity is run through bracing piece (32) and with bracing piece (32) rotate to be connected, be provided with spacing ring (441) on dwang (44), work as spacing ring (441) with bracing piece (32) are when laminating, the side surface of the circular ring plate (41) far away from the filter cover (5) is close to the end surface of the support rod (32) pipe far away from the water outlet (111).

3. The energy saving building drainage system of claim 2, wherein: the filtering cover (5) is hemispherical, and the filtering cover (5) is detachably connected with the circular ring plate (41) through a clamping structure.

4. The energy saving building drainage system of claim 3, wherein: the clamping structure comprises an insertion plate (52) arranged at the opening end of the filter cover (5), a first wedge block (521) is arranged on the side surface of the insertion plate (52), a mounting groove (411) used for inserting the insertion plate (52) is arranged on the circular ring plate (41), a receiving groove (412) is arranged on the side wall of the mounting groove (411) close to the first wedge block (521), a clamping plate (413) is arranged at the opening of the receiving groove (412), a second wedge block (414) abutted to the first wedge block (521) is arranged on the side surface of the clamping plate (413) close to the first wedge block (521), one end of the clamping plate (413) close to the groove bottom of the mounting groove (411) is hinged at the opening of the receiving groove (412), a spring (415) is arranged between the side surface of the clamping plate (413) far away from the second wedge block (414) and the groove bottom of the receiving groove (412), the spring (415) is distal from the hinged end of the snap plate (413).

5. The energy saving building drainage system of claim 4, wherein: the clamping structure is provided with a plurality of groups, and the clamping structures are distributed around the central axis of the circular ring plate (41) at even intervals.

6. The energy saving building drainage system of claim 2, wherein: the side face, close to the filter cover (5), of the connecting circular plate (42) is further provided with an extension rod (46), and one end, far away from the connecting circular plate (42), of the extension rod (46) is abutted to the filter cover (5).

7. The energy saving building drainage system of claim 2, wherein: still be provided with stiffener (45) on the inside wall of ring board (41), dwang (44) run through stiffener (45) and with stiffener (45) fixed connection.

8. The energy saving building drainage system of claim 1, wherein: the height of the support tube (31) is at least half of the height of the filter housing (5).

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