CN218206963U - Efficient energy-saving drainage mechanism - Google Patents

Abstract

The utility model discloses an energy-conserving drainage mechanism of efficient, including drainage body and gas charging component, wherein, the assembly crown plate is installed at drainage body both ends for be connected the installation with drainage body and drainage equipment's drainage structure, gas charging component sets up in the outside of drainage body, be used for supplying the pressure in the drainage body, gas charging component includes communicating pipe and gas tube, the slope cartridge of communicating pipe is in the outside of drainage body, the gas tube is connected with communicating pipe, the gas tube is used for connecting external air pump, and aerify to drainage body inside through communicating pipe. The utility model is suitable for a drainage device, this drainage mechanism link to each other gas tube and external air pump when using, and when the velocity of flow of drainage body was difficult to satisfy the demand of drainage, open the air pump, aerify to drainage body inside through gas tube and communicating pipe, guide the inside fluidic flow of supplementary drainage body to increase drainage speed and efficiency.

Description

Efficient energy-saving drainage mechanism

Technical Field

The utility model relates to a drainage equipment technical field, in particular to energy-conserving drainage mechanism of efficient.

Background

The drainage pipeline refers to a system consisting of a pipeline for collecting and discharging sewage, wastewater and rainwater and auxiliary facilities thereof, and comprises a main pipe, branch pipes and pipelines leading to a treatment plant, and the pipeline which is built on a street or any other place and has the function of drainage is used as drainage equipment;

most of drainage mechanisms used in drainage equipment are simple straight drainage pipes, namely, structures which do not have any auxiliary water flow are not provided, so that the speed of water flow is constant, the speed and the efficiency of drainage are general, and the requirement during drainage is difficult to meet.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome the defect among the prior art, provide an energy-conserving drainage mechanism of efficient.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model discloses an energy-conserving drainage mechanism of efficient, including drainage body and gas charging component, wherein, the assembly crown plate is installed at drainage body both ends for be connected the installation with drainage body and drainage equipment's drainage structure, gas charging component set up in the outside of drainage body, be used for to supply in the drainage body and press, gas charging component includes communicating pipe and gas tube, the slope cartridge of communicating pipe is in the outside of drainage body, the gas tube with communicating pipe connects, the gas tube is used for connecting external air pump to aerify to drainage body is inside through communicating pipe, structure setting makes this drainage mechanism when using, links to each other gas tube and external air pump like this, when the velocity of flow of drainage body is difficult to satisfy the demand of drainage, opens the air pump, aerifys to drainage body inside through gas tube and communicating pipe, and the flow of the inside fluid of supplementary drainage body of guide to increase drainage speed and efficiency.

Preferably, the communication pipe is inclined along the flowing direction of the fluid in the drainage pipe body, so that when the air pump inflates the drainage pipe body through the inflation pipe and the communication pipe, the flowing direction of the inflated air is consistent with that of the fluid, and the effect of assisting in guiding drainage is achieved.

Preferably, an included angle alpha is formed between the axial direction of the communicating pipe and the axial direction of the drainage pipe body, and the value range of the included angle alpha is more than or equal to 45 degrees and less than 60 degrees.

Preferably, the inflation assembly further comprises a circular pipe, the circular pipe surrounds the outside of the drainage pipe body, the plurality of communication pipes are arranged, one end of each of the plurality of communication pipes is inserted into the circular pipe, and the plurality of communication pipes are communicated with one another through the circular pipe.

Preferably, the number of the circular tubes is two, the two circular tubes are symmetrical to each other, the two circular tubes are connected through a conduction tube, and the inflation tube is inserted in the middle of the conduction tube.

Preferably, the two groups of the communicating pipes are arranged, each group is three, the three communicating pipes in the same group are distributed in an annular array by taking the axis of the drainage pipe body as the center, and the two groups of the communicating pipes are correspondingly distributed and connected to the two annular pipes.

Preferably, the conduction pipe is provided with two ball valves, the two ball valves are respectively arranged on two sides of the inflation pipe, and the structure is arranged so that when different ball valves are opened, one of the circular pipes is opened, so that when the drainage pipe body drains water in different directions, the inflation direction of the inflation assembly can be controlled through the ball valves (the inclined directions of the communication pipes corresponding to different circular pipes are different), therefore, when the drainage mechanism returns water, the drainage mechanism can also assist water return, and the water return efficiency is improved (generally, when the drainage pipeline is blocked, the blockage is removed through water return operation, namely, the blockage can be returned to the position capable of being cleaned through reverse flushing).

Preferably, the end part of the inflation tube adopts a thread structure, so that the inflation tube is conveniently connected with an air pump.

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

when the drainage mechanism is used, the inflation tube is connected with the external air pump, when the flow velocity of the drainage pipe body is difficult to meet the drainage requirement, the air pump is opened, the inflation tube and the communicating tube inflate the inside of the drainage pipe body to guide the flow of the fluid inside the auxiliary drainage pipe body, and therefore the drainage speed and the drainage efficiency are increased

Ring canal and ball valve all are provided with two, when opening different ball valves, have one of them ring canal and open for the drainage body is when the direction drainage to the difference, can aerify subassembly's the direction of aerifing through the ball valve control (the communicating pipe incline direction that the ring canal of difference corresponds is different), therefore this drainage mechanism also can assist the return water when carrying out the return water, promotes return water efficiency.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

fig. 2 is another schematic view of the structure of the present invention;

fig. 3 is a schematic sectional view of the present invention.

Reference numerals: 1. assembling a ring plate; 2. an inflation assembly; 201. a communicating pipe; 202. a ring pipe; 203. a ball valve; 204. an inflation tube; 205. a conduction pipe; 3. a drain pipe body.

Detailed Description

The following further describes a specific embodiment of an efficient energy-saving drainage mechanism according to the present invention with reference to fig. 1 to 3. The utility model relates to an energy-conserving drainage mechanism of efficient is not limited to the description of following embodiment.

Example 1:

this embodiment provides an efficient energy-saving drainage mechanism, as shown in fig. 1-3, including drainage pipe body 3 and inflation assembly 2, wherein, assembly ring board 1 is installed at two ends of drainage pipe body 3 for connecting drainage pipe body 3 with drainage structure of drainage equipment and installing, inflation assembly 2 sets up in the outside of drainage pipe body 3, is used for supplying pressure in drainage pipe body 3, inflation assembly 2 includes communicating pipe 201 and gas tube 204, communicating pipe 201 inclines to insert in the outside of drainage pipe body 3, gas tube 204 is connected with communicating pipe 201, gas tube 204 is used for connecting external air pump, and aerifys to drainage pipe body 3 inside through communicating pipe 201.

By adopting the technical scheme:

when the drainage mechanism is used, the air charging pipe 204 is connected with an external air pump, when the flow velocity of the drainage pipe body 3 is difficult to meet the drainage requirement, the air pump is started, the air charging pipe 204 and the communicating pipe 201 are used for charging air into the drainage pipe body 3, and the flow of fluid in the auxiliary drainage pipe body 3 is guided, so that the drainage speed and efficiency are increased.

Example 2

Based on embodiment 1, in this embodiment, the communication pipe 201 is inclined along the flow direction of the fluid inside the drainage pipe body 3, so that when the air pump inflates the interior of the drainage pipe body 3 through the inflation pipe 204 and the communication pipe 201, the inflated air and the fluid flow direction are the same, and the effect of assisting in guiding drainage is achieved.

An included angle alpha is arranged between the axial direction of the communicating pipe 201 and the axial direction of the drainage pipe body 3, and the value range of the included angle alpha is more than or equal to 45 degrees and less than 60 degrees.

The inflation assembly 2 further comprises a ring pipe 202, the ring pipe 202 surrounds the exterior of the drain pipe body 3, a plurality of communication pipes 201 are arranged, one end of each communication pipe 201 is inserted into the ring pipe 202, and the plurality of communication pipes 201 are communicated with each other through the ring pipe 202.

By adopting the technical scheme:

when the inflation assembly 2 inflates the inside of the drainage pipe body 3, gas can be inflated from multiple directions to the inside of the drainage pipe body 3, and the water flow speed inside the drainage pipe body 3 is improved.

Example 3

On the basis of embodiment 1, in this embodiment, there are two loops 202, two loops 202 are symmetrical to each other, the two loops 202 are connected by a conducting tube 205, and an inflation tube 204 is inserted in the middle of the conducting tube 205.

The communicating pipes 201 are provided with two groups, each group is provided with three communicating pipes 201, the three communicating pipes 201 of the same group are distributed in an annular array by taking the axis of the drainage pipe body 3 as the center, and the two groups of communicating pipes 201 are correspondingly distributed and connected on the two ring pipes 202.

Two ball valves 203 are installed on the conduction pipe 205, and the two ball valves 203 are respectively installed at two sides of the gas charging pipe 204.

The end of the inflation tube 204 is threaded for easy connection to an air pump.

By adopting the technical scheme:

when different ball valves 203 are opened, one of the circular pipes 202 is opened, so that the drainage pipe body 3 can control the inflation direction of the inflation assembly 2 through the ball valve 203 when drainage is performed in different directions (the inclined directions of the communicating pipes 201 corresponding to different circular pipes 202 are different), therefore, the drainage mechanism can assist water return when water return is performed, and the water return efficiency is improved (generally, when a drainage pipeline is blocked, blockage is removed through water return operation, namely, the blockage can be returned to the position capable of being cleaned through reverse flushing).

The foregoing shows and describes the basic principles and principal features of the invention, together with the advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (8)

1. The utility model provides an energy-conserving drainage mechanism of efficient which characterized in that: the method comprises the following steps:

the drainage pipe body (3) is provided with assembling ring plates (1) at two ends and is used for connecting and installing the drainage pipe body (3) and a drainage structure of drainage equipment;

an inflation unit (2) which is provided outside the drain pipe body (3) and supplies pressure into the drain pipe body (3);

the inflation assembly (2) comprises a communicating pipe (201) and an inflation pipe (204), the communicating pipe (201) is obliquely inserted outside the drainage pipe body (3), the inflation pipe (204) is connected with the communicating pipe (201), and the inflation pipe (204) is used for being connected with an external air pump and inflating the interior of the drainage pipe body (3) through the communicating pipe (201).

2. An efficient energy-saving drainage mechanism according to claim 1, wherein: the communicating pipe (201) inclines along the flowing direction of the fluid in the drainage pipe body (3).

3. An efficient energy-saving drainage mechanism according to claim 2, wherein: an included angle alpha is arranged between the axial direction of the communicating pipe (201) and the axial direction of the drainage pipe body (3), and the value range of the included angle alpha is more than or equal to 45 degrees and less than 60 degrees.

4. A high efficiency energy saving water drain mechanism as claimed in claim 1, wherein: the inflation assembly (2) further comprises a ring pipe (202), the ring pipe (202) surrounds the exterior of the drainage pipe body (3), the number of the communication pipes (201) is multiple, one end of each of the plurality of communication pipes (201) is inserted into the ring pipe (202), and the plurality of communication pipes (201) are communicated with one another through the ring pipe (202).

5. An efficient energy-saving drainage mechanism according to claim 4, wherein: the number of the ring pipes (202) is two, the two ring pipes (202) are symmetrical to each other, the two ring pipes (202) are connected through a conducting pipe (205), and the inflating pipe (204) is inserted in the middle of the conducting pipe (205).

6. An efficient energy-saving drainage mechanism according to claim 5, wherein: the two groups of the communication pipes (201) are arranged, each group is provided with three communication pipes, the three communication pipes (201) in the same group are distributed in an annular array by taking the axis of the drainage pipe body (3) as the center, and the two groups of the communication pipes (201) are correspondingly connected to the two annular pipes (202) in a distributed manner.

7. An efficient energy-saving drainage mechanism according to claim 6, wherein: two ball valves (203) are installed on the conduction pipe (205), and the two ball valves (203) are respectively installed on two sides of the inflation pipe (204).

8. An efficient energy-saving drainage mechanism according to claim 1, wherein: the end part of the inflation tube (204) adopts a thread structure.

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