CN216130235U - Piston type cavity-separated energy-saving pressure-stabilizing water supply device - Google Patents

Abstract

The utility model discloses a piston type cavity-divided energy-saving pressure-stabilizing water supply device, which comprises a water storage chamber, wherein a non-negative pressure water storage tank is arranged inside the water storage chamber, a first energy storage pump is arranged on one side of the non-negative pressure water storage tank and positioned inside the water storage chamber, a water pipe is arranged between the non-negative pressure water storage tank and the first energy storage pump, a high pressure water storage tank is arranged at the bottom of the first energy storage pump and positioned inside the water storage chamber, an ultrahigh pressure water storage tank is arranged on one side of the high pressure water storage tank and positioned inside the water storage chamber, a second energy storage pump is arranged at the top of the ultrahigh pressure water storage tank, and a flow controller is arranged on the top of the non-negative pressure water storage tank and positioned inside the water storage chamber; this energy-conserving steady voltage water supply installation of piston chambeies through setting up no negative pressure water storage box, first energy storage pump, high-pressure water storage box, superhigh pressure water storage box, second energy storage pump, flow controller, when can reaching the water peak period, rivers are normal, and the water speed is stable, can not appear cutting off the water supply, the phenomenon of cutting off the water supply.

Description

Piston type cavity-separated energy-saving pressure-stabilizing water supply device

Technical Field

The utility model relates to the technical field of pressure-stabilized water supply, in particular to a piston type cavity-separated energy-saving pressure-stabilized water supply device.

Background

At present, domestic district water supply system adopts no negative pressure water supply or water tank pressure boost water supply mode mostly, and wherein, no negative pressure water supply is that one kind can be directly connected with the running water pipe network, directly stacks on municipal pipe network pressure's basis and supplies water to the energy saving can detect running water pipe pressure, guarantees that it when water supply peak official website water yield water pressure can't satisfy the settlement pressure, promotes its water pressure, uses normally in order to guarantee the user. The water tank pressurization mode water tank water is generally supplied by a tap water pipe network, so that pressurized water becomes zero after entering the water tank, and energy waste is caused.

The prior art has the following defects or problems:

1. urban residents all adopt tap water pipe networks to supply water in a centralized manner, the tap water pipe networks supply water in a centralized manner, the tap water belongs to municipal engineering, the tap water is used in three stages, namely a peak period, a peak leveling period and a valley period, the water pressure of the tap water pipe networks is basically kept unchanged in the three stages, the water quantity entering users is reduced in the peak period of water consumption, and particularly, the phenomena of water cut-off and water cut-off can occur to the users living in high-rise;

2. the existing water supply device generally adopts an energy storage pressurization mode so as to supply water to high floors, but the pressurized water is supplied to residents of the whole building, so that some bottom users use the pressurized water under the condition of not needing the pressurized water supply, and energy waste is caused.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a piston type cavity-divided energy-saving pressure-stabilizing water supply device aiming at the defects in the prior art so as to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a piston energy-conserving steady voltage water supply installation in chamber that divides, includes the water storage chamber, the inside of water storage chamber is provided with no negative pressure water storage box, one side of no negative pressure water storage box and the inside that is located the water storage chamber are provided with first energy storage pump, be provided with the water pipe between no negative pressure water storage box and the first energy storage pump, the bottom of first energy storage pump and the inside that is located the water storage chamber are provided with high-pressure water storage box, one side of high-pressure water storage box and the inside that is located the water storage chamber are provided with super high pressure water storage box, super high pressure water storage box's top is provided with the second energy storage pump, be provided with the water pipe between second energy storage pump and the high pressure water storage box, the top of no negative pressure water storage box and the inside that is located the water storage chamber are provided with flow controller, be provided with the water pipe between flow controller and the no negative pressure water storage box.

As a preferable technical scheme, the top of the water storage chamber is provided with a filter, the filter is fixedly connected with the flow controller through a water pipe, one side of the filter is provided with a water valve, the water valve is fixedly connected with the filter through the water pipe, and the other end of the water valve is fixedly connected with the water pipe.

As a preferred technical scheme, the bottom of the water storage chamber is provided with a pressure stabilizing chamber, the pressure stabilizing chamber is fixedly connected with the water storage chamber, a pressure stabilizer is arranged in the pressure stabilizing chamber, and the pressure stabilizer is fixedly connected with the pressure stabilizing chamber.

As a preferred technical scheme of the utility model, the number of the voltage stabilizers is three, the three voltage stabilizers are respectively and fixedly connected with the non-negative pressure water storage tank, the high pressure water storage tank and the ultrahigh pressure water storage tank through water pipes, and one ends of the three voltage stabilizers extending to the outside of the voltage stabilization chamber are respectively and fixedly connected with the water pipes.

As a preferred technical scheme, one side of the water storage chamber is provided with a controller, the controller is fixedly connected with the water storage chamber, a water pressure gauge is arranged inside the controller, the bottom of the water pressure gauge is provided with a water pressure control knob, and the top of the water pressure gauge is provided with a switch control button.

As a preferred technical solution of the present invention, the controller is electrically connected to the water valve, the controller is electrically connected to the flow controller, the controller is electrically connected to the first energy storage pump, the controller is electrically connected to the second energy storage pump, and the controller is electrically connected to the pressure stabilizer.

As a preferred technical scheme of the utility model, the water storage chamber is fixedly connected with a non-negative pressure water storage tank, a high pressure water storage tank and an ultrahigh pressure water storage tank respectively, the first energy storage pump is fixedly connected with the high pressure water storage tank, and the second energy storage pump is fixedly connected with the ultrahigh pressure water storage tank.

Compared with the prior art, the utility model provides a piston type cavity-divided energy-saving pressure-stabilizing water supply device, which has the following beneficial effects:

1. the piston type cavity-divided energy-saving pressure-stabilizing water supply device is provided with a non-negative-pressure water storage tank, a first energy storage pump, a high-pressure water storage tank, an ultrahigh-pressure water storage tank, a second energy storage pump and a flow controller, wherein the flow controller is used for controlling the water pressure of water flowing into the non-negative-pressure water storage tank from a tap water pipe network, then the water of the non-negative-pressure water storage tank is sucked into the high-pressure water storage tank through the first energy storage pump and subjected to first energy storage pressurization, then the water is sucked into the ultrahigh-pressure water storage tank through the second energy storage pump and subjected to second pressurization, and then the three water storage tanks with sequentially increasing pressure grades are sequentially connected to low-level users, medium-level users and high-level users, so that the situation that the water flow of the high-level is slow or the water is cut off and the water supply cannot occur at the high-level water peak time because the water pressure of the high-level is higher, the medium-level and the low-level is subjected to the second pressurization;

2. this energy-conserving steady voltage water supply installation in piston chambeies, through setting up no negative pressure water storage box, first energy storage pump, high pressure water storage box, superhigh pressure water storage box, the second energy storage pump, flow controller, the water pressure that gets into no negative pressure water storage box through flow controller control supplies water to the low-rise user, water in will not having the negative pressure water storage box through first energy storage pump inhales high pressure water storage box and pressurizes to middle-rise user water supply behind the energy storage, water that inhales high pressure water storage box through the second energy storage pump carries out the secondary pressurization back to high-rise user, carry out different energy storage pressurizations to different users, need not come the user to whole building with high-rise highest energy storage pressurization mode, can the energy saving.

Drawings

FIG. 1 is a schematic view of the overall structure of a piston type cavity-divided energy-saving pressure-stabilizing water supply device of the utility model;

FIG. 2 is a left side view schematic diagram of a piston type cavity-divided energy-saving pressure-stabilizing water supply device of the utility model;

FIG. 3 is a schematic view of a top view of a piston-type chambered energy-saving pressure-stabilizing water supply apparatus according to the present invention;

fig. 4 is a schematic diagram of the internal structure of a piston type cavity-divided energy-saving pressure-stabilizing water supply device controller.

In the figure: 1. a reservoir chamber; 2. a water storage tank without negative pressure; 3. a water pipe; 4. a first accumulator pump; 5. a high pressure water storage tank; 6. an ultra-high pressure water storage tank; 7. a second accumulator pump; 8. a flow controller; 9. a filter; 10. a water valve; 11. a plenum; 12. a voltage regulator; 13. a controller; 14. a water pressure gauge; 15. a water pressure control knob; 16. the switch controls the button.

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. 1-4, in this embodiment: a piston type cavity-divided energy-saving pressure-stabilizing water supply device comprises a water storage chamber 1, a non-negative pressure water storage tank 2 is arranged inside the water storage chamber 1, a first energy storage pump 4 is arranged on one side of the non-negative pressure water storage tank 2 and located inside the water storage chamber 1, a water pipe 3 is arranged between the non-negative pressure water storage tank 2 and the first energy storage pump 4, a high-pressure water storage tank 5 is arranged at the bottom of the first energy storage pump 4 and located inside the water storage chamber 1, an ultrahigh pressure water storage tank 6 is arranged on one side of the high-pressure water storage tank 5 and located inside the water storage chamber 1, a second energy storage pump 7 is arranged at the top of the ultrahigh pressure water storage tank 6, a water pipe 3 is arranged between the second energy storage pump 7 and the high-pressure water storage tank 5, a flow controller 8(EPC-4) is arranged at the top of the non-negative pressure water storage tank 2 and located inside the water storage chamber 1, and the water pipe 3 is arranged between the flow controller 8 and the non-negative pressure water storage tank 2.

In the embodiment, the top of the water storage chamber 1 is provided with a filter 9, the filter 9 is fixedly connected with the flow controller 8 through the water pipe 3, one side of the filter 9 is provided with a water valve 10(D941X-16), the water valve 10 is fixedly connected with the filter 9 through the water pipe 3, the other end of the water valve 10 is fixedly connected with the water pipe 3, the water valve 10 controls the water flow to enter and exit, and impurities in the water are filtered through the filter 9; a pressure stabilizing chamber 11 is arranged at the bottom of the water storage chamber 1, the pressure stabilizing chamber 11 is fixedly connected with the water storage chamber 1, a voltage stabilizer 12(200X) is arranged in the pressure stabilizing chamber 11, and the voltage stabilizer 12 is fixedly connected with the pressure stabilizing chamber 11; the number of the voltage stabilizers 12 is three, the three voltage stabilizers 12 are respectively and fixedly connected with the non-negative pressure water storage tank 2, the high pressure water storage tank 5 and the ultrahigh pressure water storage tank 6 through water pipes 3, one ends of the three voltage stabilizers 12 extending to the outside of the voltage stabilization chamber 11 are respectively and fixedly connected with the water pipes 3, and the flow speed of water flow is stabilized through the voltage stabilizers 12; a controller 13(QBN) is arranged on one side of the water storage chamber 1, the controller 13 is fixedly connected with the water storage chamber 1, a water pressure gauge 14 is arranged inside the controller 13, a water pressure control knob 15 is arranged at the bottom of the water pressure gauge 14, a switch control button 16 is arranged at the top of the water pressure gauge 14, the water pressure can be watched through the water pressure gauge 14, the water pressure can be adjusted through the water pressure control knob 15, and various connected electrical appliance power switches can be controlled through the switch control button 16; the controller 13 is electrically connected with the water valve 10, the controller 13 is electrically connected with the flow controller 8, the controller 13 is electrically connected with the first energy storage pump 4, the controller 13 is electrically connected with the second energy storage pump 7, the controller 13 is electrically connected with the voltage stabilizer 12, and various electric appliances can be controlled through the controller 13. The water storage chamber 1 is respectively fixedly connected with the non-negative-pressure water storage tank 2, the high-pressure water storage tank 5 and the ultrahigh-pressure water storage tank 6, the first energy storage pump 4 is fixedly connected with the high-pressure water storage tank 5, the second energy storage pump 7 is fixedly connected with the ultrahigh-pressure water storage tank 6, and the high-pressure water storage tank 5 and the ultrahigh-pressure water storage tank 6 can be subjected to energy storage pressurization through the first energy storage pump 4 and the second energy storage pump 7.

The working principle and the using process of the utility model are as follows: a piston type energy-saving pressure-stabilizing water supply device with separated cavities is characterized in that when the device is used, a switch control button 16 in a controller 13 controls a water valve 10 to enable water to flow into a non-negative pressure water storage tank 2 through a filter 9 and a flow controller 8, then a water pressure gauge 14 and a water pressure control knob 15 in the controller 13 control the water pressure of tap water in a tap water network to flow into the non-negative pressure water storage tank 2, then a water pressure gauge 14 and a water pressure control knob 15 in the controller 13 control a first energy storage pump 4 to suck water in the non-negative pressure water storage tank 2 into a high pressure water storage tank 5 and carry out first energy storage pressurization, then a water pressure gauge 14 and a water pressure control knob 15 in the controller 13 control a second energy storage pump 7 to suck water into an ultrahigh pressure water storage tank 6 for second pressurization, and then the three water storage tanks with sequentially increasing pressure levels are connected to low-level users and medium-level users through a pressure stabilizer 12 in turn, and (4) high-level users.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that changes may be made in the embodiments and/or equivalents thereof without departing from the spirit and scope of the utility model. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. The utility model provides a piston energy-conserving steady voltage water supply installation in minute chamber which characterized in that: comprises a water storage chamber (1), a non-negative pressure water storage tank (2) is arranged in the water storage chamber (1), a first energy storage pump (4) is arranged on one side of the non-negative pressure water storage tank (2) and positioned in the water storage chamber (1), a water pipe (3) is arranged between the non-negative pressure water storage tank (2) and the first energy storage pump (4), a high pressure water storage tank (5) is arranged at the bottom of the first energy storage pump (4) and positioned in the water storage chamber (1), an ultrahigh pressure water storage tank (6) is arranged on one side of the high pressure water storage tank (5) and positioned in the water storage chamber (1), a second energy storage pump (7) is arranged at the top of the ultrahigh pressure water storage tank (6), a water pipe (3) is arranged between the second energy storage pump (7) and the high pressure water storage tank (5), a flow controller (8) is arranged at the top of the non-negative pressure water storage tank (2) and positioned in the water storage chamber (1), and a water pipe (3) is arranged between the flow controller (8) and the non-negative-pressure water storage tank (2).

2. The piston type cavity-divided energy-saving pressure-stabilizing water supply device according to claim 1, characterized in that: the water storage device is characterized in that a filter (9) is arranged at the top of the water storage chamber (1), the filter (9) is fixedly connected with the flow controller (8) through a water pipe (3), a water valve (10) is arranged on one side of the filter (9), the water valve (10) is fixedly connected with the filter (9) through the water pipe (3), and the other end of the water valve (10) is fixedly connected with the water pipe (3).

3. The piston type cavity-divided energy-saving pressure-stabilizing water supply device according to claim 1, characterized in that: the water storage device is characterized in that a pressure stabilizing chamber (11) is arranged at the bottom of the water storage chamber (1), the pressure stabilizing chamber (11) is fixedly connected with the water storage chamber (1), a voltage stabilizer (12) is arranged in the pressure stabilizing chamber (11), and the voltage stabilizer (12) is fixedly connected with the pressure stabilizing chamber (11).

4. The piston type chamber-divided energy-saving pressure-stabilizing water supply device according to claim 3, characterized in that: the figure of stabiliser (12) is three groups, and three group stabiliser (12) pass through water pipe (3) fixed connection with no negative pressure water storage box (2), high pressure water storage box (5), superhigh pressure water storage box (6) respectively, three group stabiliser (12) extend to stabilivolt room (11) outside one end respectively fixedly connected with water pipe (3).

5. The piston type cavity-divided energy-saving pressure-stabilizing water supply device according to claim 1, characterized in that: the water storage device is characterized in that a controller (13) is arranged on one side of the water storage chamber (1), the controller (13) is fixedly connected with the water storage chamber (1), a water pressure gauge (14) is arranged inside the controller (13), a water pressure control knob (15) is arranged at the bottom of the water pressure gauge (14), and a switch control button (16) is arranged at the top of the water pressure gauge (14).

6. The piston type chamber-divided energy-saving pressure-stabilizing water supply device according to claim 5, characterized in that: the controller (13) is electrically connected with the water valve (10), the controller (13) is electrically connected with the flow controller (8), the controller (13) is electrically connected with the first energy storage pump (4), the controller (13) is electrically connected with the second energy storage pump (7), and the controller (13) is electrically connected with the voltage stabilizer (12).

7. The piston type cavity-divided energy-saving pressure-stabilizing water supply device according to claim 1, characterized in that: the water storage chamber (1) is fixedly connected with the non-negative-pressure water storage tank (2), the high-pressure water storage tank (5) and the ultrahigh-pressure water storage tank (6) respectively, the first energy storage pump (4) is fixedly connected with the high-pressure water storage tank (5), and the second energy storage pump (7) is fixedly connected with the ultrahigh-pressure water storage tank (6).

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