CN215406305U - Energy-saving secondary water supply system - Google Patents

Abstract

The utility model discloses an energy-saving secondary water supply system, which comprises a flowmeter body, a delivery pipe arranged on the side surface of the flowmeter body and a timing retention mechanism arranged on one side of the delivery pipe, wherein a first timing switch valve is provided with timing opening for three periods of time, the timing opening time of second timing switch valves respectively arranged on the first retention pipe, a second retention pipe and a third retention pipe is different from the opening time of the first timing switch valve, when water supply enters the delivery pipe through the flowmeter body, the time reaches a group of timing opening time set by the first timing switch valve, the water supply in the delivery pipe enters a disassembly pipe through a connecting pipe, and the water supply can flow into a group of the first retention pipe, the second retention pipe and the third retention pipe, wherein the second timing switch valve is opened, and the three groups of retention can be retained.

Description

Energy-saving secondary water supply system

Technical Field

The utility model relates to the technical field of secondary water supply, in particular to an energy-saving secondary water supply system.

Background

The secondary water supply is a form that a unit or an individual stores and pressurizes urban public water supply or self-built facility water supply, and supplies water to users or self-use through a pipeline. The secondary water supply is mainly established for compensating the pressure shortage of the municipal water supply pipeline and ensuring the water consumption of dwellings and livelihoods in high-rise people.

Traditional secondary water supply system does not set up the structure that is used for the retention to supply water, can not carry out the secondary and detect to ensure the quality of water quality of supplying water, under the condition that can not in time ensure the quality of supplying water, probably need consume bigger energy and solve the quality of water problem that appears.

In order to solve the problems, an energy-saving secondary water supply system is provided.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide an energy-saving secondary water supply system, which comprises a control module, a water supply module electrically connected with the control module, and a pressure module electrically connected with the water supply module, wherein the pressure module is electrically connected with a flow module, the control module is also electrically connected with a screen projection module, the flow module is also electrically connected with a first detection module and a second detection module, the flow module comprises a flowmeter body, a delivery pipe arranged on the side surface of the flowmeter body and a timing retention mechanism arranged on one side of the delivery pipe, and a structure for retaining water supply is arranged, so that the problems in the background art are solved.

In order to achieve the purpose, the utility model provides the following technical scheme: an energy-saving secondary water supply system comprises a control module, a water supply module and a pressure module, wherein the water supply module is electrically connected with the control module, the pressure module is electrically connected with the water supply module, the pressure module is electrically connected with a flow module, the control module is also electrically connected with a screen projection module, and the flow module is also electrically connected with a first detection module and a second detection module;

the flow module comprises a flowmeter body, a delivery pipe arranged on the side surface of the flowmeter body and a timing retention mechanism arranged on one side of the delivery pipe.

Preferably, the control module is preferably a constant-pressure water supply control cabinet, the water supply module is preferably a non-negative-pressure water supply device, the pressure module is preferably a pressure transmitter, the flow module is preferably an electromagnetic flowmeter, and the first detection module and the second detection module are preferably a water quality analyzer.

Preferably, the side surface of the conveying pipe is provided with a connecting pipe and a water tank arranged on one side of the conveying pipe, and the connecting pipe is communicated with the inside of the conveying pipe.

Preferably, the connection pipe includes a first timing switching valve provided at an upper end position of the connection pipe, and a built-in screw thread provided inside the connection pipe.

Preferably, the water tank comprises an L-shaped water cavity arranged inside the water tank and a filter membrane arranged on the inner wall of the upper end of the water tank, and the filter membrane is positioned on the inner wall of the conveying pipe.

Preferably, the timed retention mechanism comprises a disassembly pipe in threaded connection on one side of the connecting pipe, and a first retention pipe, a second retention pipe and a third retention pipe which are arranged on one side of the disassembly pipe.

Preferably, the second retention tube includes a second time switch valve disposed at an upper side of the second retention tube, and an elastic hose disposed at a middle position of the second retention tube and a twist valve disposed at an end position of the second retention tube, and the first retention tube, the second retention tube and the third retention tube are members made of the same construction.

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

1. according to the energy-saving secondary water supply system provided by the utility model, the control module controls the water supply module, data and instruction display controlled by the control module can be displayed on a mobile phone of a worker through the screen projection module, the pressure module controls the pressure of water supply, water sent out by the pressure module can be metered through the flow module, the flow module is provided with the timing retention mechanism, most of the water supply is detected by the first detection module through the flow module, and a small part of the water is detected by the second detection module through the flow module, so that secondary water quality detection is set.

2. The utility model provides an energy-saving secondary water supply system, wherein a first timing switch valve is set to be opened at three periods of time in a timing manner, the timing opening time of a second timing switch valve arranged on a first retention pipe, a second retention pipe and a third retention pipe respectively is different groups of time in the opening time of the first timing switch valve, when water supply enters a conveying pipe through a flowmeter body, the time reaches the group of timing opening time set by the first timing switch valve, the water supply in the conveying pipe enters a disassembly pipe through a connecting pipe, the water supply flows into one group of the first retention pipe, the second retention pipe and the third retention pipe, the second timing switch valve is opened, the three groups of water can be retained, a twist valve is opened to carry out secondary detection on retained water, when water flows through the conveying pipe, the water can permeate a little through a filter membrane to enter an L-shaped water cavity, and the water can be slowly accumulated in the L-shaped water cavity within one day, and detecting the water quality of the water supply all day long.

Drawings

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

FIG. 2 is a schematic diagram of the flowmeter body, the delivery tube, and the timing retention mechanism of the present invention;

FIG. 3 is a schematic view of a transfer tube configuration of the present invention;

FIG. 4 is a schematic view of the plan structure of the water tank of the present invention;

fig. 5 is a schematic diagram of the timing retention mechanism of the present invention.

In the figure: 1. a flowmeter body; 2. a delivery pipe; 21. a connecting pipe; 211. a first timing switching valve; 212. internally arranging a thread; 22. a water tank; 221. an L-shaped water cavity; 222. filtering the membrane; 3. a timed retention mechanism; 31. disassembling the pipe; 32. a first retention tube; 33. a second retention tube; 331. a second timing switching valve; 332. an elastic hose; 333. screwing the valve; 34. a third retention tube; 4. a flow module; 5. a first detection module; 6. a second detection module; 7. a screen projection module; 8. a control module; 9. a water supply module; 10. and a pressure module.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, an energy-saving secondary water supply system includes a control module 8, a water supply module 9 electrically connected to the control module 8, and a pressure module 10 electrically connected to the water supply module 9, the pressure module 10 is electrically connected to a flow module 4, the control module 8 is further electrically connected to a screen projection module 7, the flow module 4 is further electrically connected to a first detection module 5 and a second detection module 6, the control module 8 is preferably a constant-pressure water supply control cabinet, the water supply module 9 is preferably a non-negative-pressure water supply device, the pressure module 10 is preferably a pressure transmitter, the flow module 4 is preferably an electromagnetic flowmeter, and the first detection module 5 and the second detection module 6 are preferably water quality analyzers.

Referring to fig. 2-5, an energy-saving secondary water supply system, a flow module 4 includes a flowmeter body 1, a delivery pipe 2 disposed at a side of the flowmeter body 1, and a timing retention mechanism 3 disposed at one side of the delivery pipe 2, a control module 8 controls a water supply module 9, data and instruction display controlled by the control module 8 is displayed on a mobile phone of a worker through a screen projection module 7, a pressure module 10 controls pressure of supplied water, water sent from the pressure module 10 is measured through the flow module 4, the flow module 4 is provided with the timing retention mechanism 3, most of supplied water is detected by a first detection module 5 through the flow module 4, less of supplied water is detected by a second detection module 6 through the flow module 4, secondary water quality detection is provided, a connection pipe 21 includes a first timing switch valve 211 disposed at an upper end of the connection pipe 21, and a built-in screw 212 arranged in the connecting pipe 21, the water tank 22 comprises an L-shaped water cavity 221 arranged in the water tank 22 and a filter membrane 222 arranged on the inner wall of the upper end position of the water tank 22, the filter membrane 222 is positioned on the inner wall of the delivery pipe 2, the timing retaining mechanism 3 comprises a disassembly pipe 31 which is connected with one side of the connecting pipe 21 in a threaded manner, a first retaining pipe 32, a second retaining pipe 33 and a third retaining pipe 34 which are arranged on one side of the disassembly pipe 31, the second retaining pipe 33 comprises a second timing switch valve 331 arranged on the upper side surface of the second retaining pipe 33, an elastic hose 332 arranged in the middle of the second retaining pipe 33 and a screwing valve 333 arranged at one end position of the second retaining pipe 33, the first retaining pipe 32, the second retaining pipe 33 and the third retaining pipe 34 are members made of the same structure, the first timing switch 211 is provided with timing opening of three periods, the first retaining pipe 32, the second retaining pipe 33 and the third retaining pipe 34 are members made of the same structure, and the timing opening of the first timing switch 211 is provided with timing opening of three periods, The timing opening time of the second timing switch valve 331 respectively arranged in the second retention pipe 33 and the third retention pipe 34 is different time groups in the opening time of the first timing switch valve 211, when water enters the delivery pipe 2 through the flowmeter body 1, the time reaches the time group of the timing opening time of the first timing switch valve 211, the water in the delivery pipe 2 enters the interior of the dismounting pipe 31 through the connecting pipe 21, the water can flow into the first retention pipe 32, the second retention pipe 33 and the third retention pipe 34, the second timing switch valve 331 is opened, the water can be retained in three groups, the retained water is secondarily detected by opening the screwing valve 333, when the water flows through the delivery pipe 2, the water can permeate a little and enter the interior of the L-shaped water cavity 221 through the filter membrane 222, the time of a day can be slowly accumulated in the interior of the L-shaped water cavity 221, and the water quality of the whole day can be detected.

The working principle is as follows: the control module 8 controls the water supply module 9, data and instruction display controlled on the control module 8 can be displayed on a mobile phone of a worker through the screen projection module 7, the pressure module 10 controls the pressure of water supply, water sent by the pressure module 10 can be metered through the flow module 4, the flow module 4 is provided with the timing retention mechanism 3, most of the water supply is detected by the first detection module 5 through the flow module 4, less of the water is detected by the second detection module 6 through the flow module 4, the first timing switch valve 211 is provided with timing opening of three periods of time, the timing opening time of the second timing switch valve 331 respectively arranged on the first retention pipe 32, the second retention pipe 33 and the third retention pipe 34 is different groups of the opening time of the first timing switch valve 211, when the water supply enters the conveying pipe 2 through the flow meter body 1, the time reaches a set of timing opening time that first timing switch valve 211 set up, inside the delivery pipe 2 supplies water through connecting pipe 21 entering dismantlement pipe 31, this water supply can flow into first pipe 32 of remaining, the second remains a set of that second timing switch valve 331 was opened in pipe 33 and the third pipe 34 of remaining, but three groups remain, open and twist valve 333 and carry out the secondary detection with the water that remains, rivers are when delivery pipe 2, can permeate a bit and get into inside L type water cavity 221 through filter membrane 222, the time of day, can slowly accumulate inside L type water cavity 221, detect the water quality of supplying water of whole day.

It is noted that, herein, relational terms such as first and second, and the like may be 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. Also, 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.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an energy-saving secondary water supply system, includes control module (8) and water supply module (9) with control module (8) electric connection to and with water supply module (9) electric connection's pressure module (10), pressure module (10) electric connection has flow module (4), its characterized in that: the control module (8) is also electrically connected with a screen projection module (7), and the flow module (4) is also electrically connected with the first detection module (5) and the second detection module (6);

the flow module (4) comprises a flowmeter body (1), a delivery pipe (2) arranged on the side surface of the flowmeter body (1) and a timing retention mechanism (3) arranged on one side of the delivery pipe (2).

2. The energy-saving secondary water supply system according to claim 1, wherein: the control module (8) is preferably a constant-pressure water supply control cabinet, the water supply module (9) is preferably a non-negative-pressure water supply device, the pressure module (10) is preferably a pressure transmitter, the flow module (4) is preferably an electromagnetic flowmeter, and the first detection module (5) and the second detection module (6) are preferably water quality analyzers.

3. The energy-saving secondary water supply system according to claim 1, wherein: the side surface of the conveying pipe (2) is provided with a connecting pipe (21) and a water tank (22) arranged on one side of the conveying pipe (2), and the connecting pipe (21) is communicated with the inside of the conveying pipe (2).

4. An energy-saving secondary water supply system according to claim 3, characterized in that: the connecting pipe (21) comprises a first timing switch valve (211) arranged at the upper end of the connecting pipe (21) and a built-in thread (212) arranged inside the connecting pipe (21).

5. An energy-saving secondary water supply system according to claim 3, characterized in that: the water tank (22) comprises an L-shaped water cavity (221) arranged inside the water tank (22) and a filter membrane (222) arranged on the inner wall of the upper end of the water tank (22), and the filter membrane (222) is positioned on the inner wall of the conveying pipe (2).

6. The energy-saving secondary water supply system according to claim 1, wherein: the timing retention mechanism (3) comprises a disassembly pipe (31) which is in threaded connection with one side of the connecting pipe (21), and a first retention pipe (32), a second retention pipe (33) and a third retention pipe (34) which are arranged on one side of the disassembly pipe (31).

7. The energy-saving secondary water supply system according to claim 6, wherein: the second retention pipe (33) comprises a second timing switch valve (331) arranged on the upper side of the second retention pipe (33), an elastic hose (332) arranged in the middle of the second retention pipe (33) and a screwing valve (333) arranged at one end of the second retention pipe (33), and the first retention pipe (32), the second retention pipe (33) and the third retention pipe (34) are members made of the same structure.

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