CN219183438U - Novel instant heating type mesa water dispenser - Google Patents

Abstract

The utility model relates to the technical field of instant heating type table-board water dispensers, in particular to an instant heating type water dispenser, wherein a front filter element is arranged on a raw water pipe in series, a raw water quality measuring instrument is arranged on the raw water pipe in series and is positioned at one side of an inlet end of the front filter element, a first booster pump is arranged on the raw water pipe in series and is positioned between the front filter element and a pressure barrel, a second booster pump is arranged on the raw water pipe in series and is positioned between the front filter element and the pressure barrel, a first wastewater electromagnetic valve is arranged on a wastewater pipe in series, and a second wastewater electromagnetic valve is arranged on the wastewater pipe in series; the double-group linkage booster pump is arranged, so that single-group water pump pressurization or double-group water pump pressurization is adopted when different water receiving flow rates are met, normal pressure in a pipeline of the water dispenser is kept, normal water outlet of the water dispenser is guaranteed, the double-group wastewater electromagnetic valve structure and the flushing valve structure are arranged on a wastewater pipeline of the water dispenser, normal discharge of wastewater of the water dispenser is guaranteed, and the wastewater pipeline can be flushed.

Description

Novel instant heating type mesa water dispenser

Technical Field

The utility model relates to the technical field of instant heating type water dispensers, in particular to a novel instant heating type table top water dispenser.

Background

In the prior art, the instant heating type water dispenser adopts a tail end heating module to heat water, and meanwhile, a filter element, a booster pump and other matched structures are arranged in the water dispenser, so that the raw water is filtered, and other works are realized, but a single booster pump structure is adopted in the water dispenser with the existing structure, and the flow rate of cold water is faster than that of hot water when the water dispenser works normally, so that the problem that the water pump is insufficient in water pressure when the water pump is adapted to the flow rate of hot water and the cold water is easy to occur when the water pump is adapted to the flow rate of hot water, and the water dispenser needs to be improved, so that the water dispenser can adapt to the pressure requirements of different working modes.

Disclosure of Invention

The utility model aims at overcoming the defects and shortcomings of the prior art, and provides a novel instant heating type table-board water dispenser, which is characterized in that a single-group water pump or a double-group water pump is adopted to pressurize when different water receiving flow rates are met by arranging double-group linked pressurizing pumps, so that the normal pressure in a water dispenser pipeline is kept, the normal water outlet of the water dispenser is ensured, and a double-group wastewater electromagnetic valve structure and a flushing valve structure are arranged for a wastewater pipeline of the water dispenser, so that the normal discharge of wastewater of the water dispenser is ensured, and the wastewater pipeline can be flushed.

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

the water dispenser water pump is arranged on the pure water pipe in series, the water dispenser water pump is arranged on one side of the rear filter element, which is away from the rear filter element, the electrodeless heating module is arranged on the pure water pipe in series, and the electrodeless heating module is arranged on one side of the water dispenser water pump, which is away from the rear filter element, and the electrodeless heating module is further arranged on the pure water pipe:

the front filter element is arranged on the raw water pipe in series;

the raw water quality measuring instrument is arranged on the raw water pipe in series and is positioned at one side of the inlet end of the front filter element;

the pure water quality measuring instrument is arranged on the pure water pipe in series and is positioned between the reverse osmosis filter element and the rear filter element;

the first booster pump is arranged on the raw water pipe in series and is positioned between the preposed filter element and the pressure barrel;

the second booster pump is arranged in series on the raw water pipe and positioned between the preposed filter element and the pressure barrel, and the first booster pump and the second booster pump are arranged in parallel;

the pressure sensor is arranged on the pure water pipe in series and is positioned between the pressure barrel and the active carbon filter element;

the flowmeter is arranged on the pure water pipe in series and is positioned between the pure water quality measuring instrument and the rear filter element;

the first waste water electromagnetic valve is arranged on the waste water pipe in series;

the second wastewater electromagnetic valve is arranged on the wastewater pipe in series;

the waste water cleaning valve is arranged on the waste water pipe in series, and the first waste water electromagnetic valve, the second waste water electromagnetic valve and the waste water cleaning valve are arranged in parallel;

the control valve is arranged on the pure water pipe in series and is positioned between the rear filter element and the water pump of the water dispenser;

the water level sensor is arranged on the pure water pipe in series and is positioned between the control valve and the water pump of the water dispenser.

Preferably, the outlet end of the first booster pump is provided with a first check valve in series, the outlet end of the second booster pump is provided with a second check valve in series, the first check valve and the second check valve are arranged in parallel, the pure water pipe is provided with a third check valve in series, and the third check valve is arranged between the flowmeter and the rear filter element.

Preferably, the front filter element is of a PP cotton filter element structure.

Preferably, the rear filter element is an active carbon filter element structure.

Preferably, the water level sensor is a floating ball type liquid level device structure.

Compared with the prior art, the utility model has the beneficial effects that: according to the novel instant heating type table-board water dispenser, the double-group linked booster pumps are arranged, so that the single-group water pump pressurization or the double-group water pump pressurization is adopted when different water receiving flow rates are met, normal pressure in a water dispenser pipeline is kept, normal water outlet of the water dispenser is guaranteed, the double-group wastewater electromagnetic valve structure and the flushing valve structure are arranged aiming at a wastewater pipeline of the water dispenser, normal discharge of wastewater of the water dispenser is guaranteed, and the wastewater pipeline can be flushed.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Reference numerals illustrate:

raw water pipe 1, pure water pipe 2, waste water pipe 3, front filter element 4, raw water quality measuring instrument 5, first booster pump 6, first check valve 7, second booster pump 8, second check valve 9, pressure barrel 10, pressure sensor 11, active carbon filter element 12, reverse osmosis filter element 13, pure water quality measuring instrument 14, flowmeter 15, third check valve 16, rear filter element 17, first waste water solenoid valve 18, second waste water solenoid valve 19, waste water cleaning valve 20, control valve 21, water level sensor 22, electrodeless heating module 23, water dispenser water pump 24.

Detailed Description

The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings, in which preferred embodiments in the description are given by way of example only, and all other embodiments obtained by those skilled in the art without making any inventive effort are within the scope of protection of the present utility model.

Example 1:

as shown in fig. 1, this embodiment includes a raw water pipe 1, a pure water pipe 2, a waste water pipe 3, a pressure barrel 10, an activated carbon filter core 12, a reverse osmosis filter core 13, a post-filter core 17, an electrodeless heating module 23, and a water dispenser water pump 24, wherein the raw water pipe 1 is connected and disposed on an inlet end of the pressure barrel 10, an outlet end of the pressure barrel 10 is connected and disposed with an inlet end of the activated carbon filter core 12 through a pipeline, an outlet end of the activated carbon filter core 12 is connected and disposed with an inlet end of the reverse osmosis filter core 13 through a pipeline, the pure water pipe 2 is connected and disposed on a pure water port of the reverse osmosis filter core 13, the waste water pipe 3 is connected and disposed on a waste water port of the reverse osmosis filter core 13, the post-filter core 17 is disposed on the pure water pipe 2 in series, the post-filter core 17 is an activated carbon filter core, the water dispenser water pump 24 is disposed on one side of the post-filter core 17 facing away from the reverse osmosis filter core 13 in series, the electrodeless heating module 23 is disposed on the pure water pipe 2, and the electrodeless heating module 23 is disposed on one side of the water dispenser water pump 24 facing away from the post-filter core 17, and further comprises:

the front filter element 4 is arranged on the raw water pipe 1 in series, and the front filter element 4 is a PP cotton filter element;

the raw water quality measuring instrument 5 is arranged on the raw water pipe 1 in series and is positioned at one side of the inlet end of the front filter element 4;

the pure water quality measuring instrument 14 is arranged on the pure water pipe 2 in series and is positioned between the reverse osmosis filter element 13 and the rear filter element 17;

the first booster pump 6 is arranged on the raw water pipe 1 in series and is positioned between the preposed filter element 4 and the pressure barrel 10;

the second booster pump 8 is arranged on the raw water pipe 1 in series and is positioned between the preposed filter element 4 and the pressure barrel 10, and the first booster pump 6 and the second booster pump 8 are arranged in parallel;

the pressure sensor 11 is arranged on the pure water pipe 2 in series and is positioned between the pressure barrel 10 and the activated carbon filter element 12;

the flowmeter 15 is arranged on the pure water pipe 2 in series and is positioned between the pure water quality measuring instrument 14 and the rear filter element 17;

a first waste water electromagnetic valve 18, wherein the first waste water electromagnetic valve 18 is arranged on the waste water pipe 3 in series;

the second wastewater electromagnetic valve 19 is arranged on the wastewater pipe 3 in series with the second wastewater electromagnetic valve 19;

the waste water cleaning valve 20 is arranged on the waste water pipe 3 in series, and the first waste water electromagnetic valve 18, the second waste water electromagnetic valve 19 and the waste water cleaning valve 20 are arranged in parallel;

the control valve 21 is arranged on the pure water pipe 2 in series and is positioned between the rear filter element 17 and the water pump 24 of the water dispenser;

the water level sensor 22 is arranged on the pure water pipe 2 in series between the control valve 21 and the water pump 24 of the water dispenser, the water level sensor 22 is of a floating ball type liquid level device structure, and a water tank for storing water is arranged at the position corresponding to the water level sensor 22, the section from the pressure barrel 10 to the control valve 21 on the pure water pipe 2 is in a pressure maintaining state, the control valve 21 is opened, water in the pure water pipe is pressurized and sent into the water tank, and the liquid level height is detected through the water level sensor;

the outlet end of the first booster pump 6 is provided with a first check valve 7 in series, the outlet end of the second booster pump 8 is provided with a second check valve 9 in series, the first check valve 7 and the second check valve 9 are arranged in parallel, the pure water pipe 2 is provided with a third check valve 16 in series, and the third check valve 16 is arranged between the flowmeter 15 and the rear filter element 17.

After the technical scheme disclosed by the utility model is adopted, the following steps of:

when using this device, be connected former water pipe 1 with the water supply pipe network, waste pipe 3 is connected with the waste water pipe network, and pure water pipe 2 is connected with the water receiving mouth of water dispenser, and then when using water:

the method comprises the steps of firstly, preliminarily filtering raw water connected to a water supply network through a pre-filter element 4, detecting the raw water before filtering through a raw water quality measuring instrument 5, and feeding back data;

secondly, pressurizing water output by the front filter element 4 through a first booster pump 6 and delivering the water into the pure water pipe 2, wherein the pressure is stored in the pressure barrel 10, and the pipeline between the pressure barrel 10 and the control valve 21 in the pure water pipe 2 is in a high-pressure maintaining state;

thirdly, the pressurized water passing through the first booster pump 6 enters the pressure barrel 10, the water output by the pressure barrel 10 enters the activated carbon filter element 12 for primary filtration, the water filtered by the activated carbon filter element 12 is sent out to enter the reverse osmosis filter element 13 for separation to form pure water and concentrated wastewater, the wastewater sent out by the reverse osmosis filter element 13 enters the wastewater pipe 3, and the pure water sent out by the reverse osmosis filter element 13 enters the subsequent pipeline of the pure water pipe 2;

fourthly, the pure water sent out by the reverse osmosis filter element 13 is detected by the pure water quality measuring instrument 14 and then sent into the rear filter element 17 for filtering, the pure water quality measuring instrument 14 feeds back the monitoring data, and the pure water filtered by the rear filter element 17 is reserved in a subsequent pipeline of the pure water pipe 2;

fifthly, pure water in the pure water pipe 2 is sent into a water tank of the water dispenser, the liquid level in the water tank is controlled through the water level sensor 22, the water pump 24 of the water dispenser is turned on to pump water in the water tank when water is received, and then after the water level sensor 22 detects that the liquid level in the water tank is lowered, a signal is sent to the control valve 21 to open the control valve 21, and then the water in the pure water pipe 2 is pushed to flow through the pressure provided by the pressure barrel 10 to supplement the water in the water tank;

when receiving water, the electrodeless heating module 23 is opened to heat the water, at the moment, the water dispenser water pump 24 pumps water to the electrodeless preheating module 23 with low power, at the moment, the state of low flow rate in the pure water pipe 2 is detected by the flowmeter 15, and when receiving cold water, the water dispenser water pump 24 pumps water with full power, at the moment, the state of high flow rate in the pure water pipe 2 is detected by the flowmeter 15;

the low flow speed state in the pure water pipe 2 is detected by the flow rate meter 15, the flow rate meter 15 feeds back signals and controls the first waste water electromagnetic valve 18 to be opened, and waste water in the waste water pipe 3 is discharged; the high flow rate state in the pure water pipe 2 is detected by the flow rate meter 15, the flow rate meter 15 feeds back signals and controls the first waste water electromagnetic valve 18 and the second waste water electromagnetic valve 19 to be opened simultaneously, and then waste water in the waste water pipe 3 is discharged;

step six, when the water tank is filled with water so that the pressure in the pure water pipe 2 is insufficient, the pressure sensor 11 is used for detecting the pressure in the pure water pipe 2 and controlling the first booster pump 6 to be opened for pressurization, or simultaneously opening the first booster pump 6 and the second booster pump 8 to simultaneously pressurize the pure water pipe 2;

and seventh, the waste water cleaning valve 20 is controlled to be opened periodically, at this time, the pure water pipe 2 is in a closed state, the waste water pipe 3 is in an open state, the pressure barrel 10 is used for pressing and delivering water to the reverse osmosis filter element 13, the reverse osmosis filter element 13 is used for delivering all the delivered water into the waste water pipe 3, flushing is carried out in the waste water pipe 3, and the waste water after flushing is discharged to a waste water pipe network.

By adopting the technical scheme, the technical advantages can be achieved as follows:

the front filter element is arranged on the raw water pipe in series, and the raw water quality detector is arranged, so that the quality of raw water is conveniently detected, and the safety of the raw water is further ensured;

two groups of pressure pump structures are arranged, and the two groups of pressure pumps are arranged in parallel, so that when different water yield requirements are met, the pressure is supplied by adopting different numbers of pressure pump works, and the water supply requirement is met;

the waste water pipe is provided with two groups of waste water electromagnetic valves in parallel, so that when the waste water treated by the reverse osmosis filter element is discharged, the waste water electromagnetic valves with different numbers can be controlled to be opened according to the change of water yield, and the normal discharge of the waste water is further ensured.

It should be understood that those skilled in the art can make modifications to the technical solutions described in the foregoing embodiments and equivalent substitutions of some technical features, and any modifications, equivalent substitutions, improvements, etc. within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (5)

1. The utility model provides a novel instant heating type mesa water dispenser, it contains former water pipe (1), pure water pipe (2), waste pipe (3), pressure vat (10), active carbon filter core (12), reverse osmosis filter core (13), rearmounted filter core (17), electrodeless heating module (23), water dispenser water pump (24), wherein former water pipe (1) connect and set up on the entrance point of pressure vat (10), the exit end of pressure vat (10) passes through the pipe connection setting with the entrance point of active carbon filter core (12), the exit end of active carbon filter core (12) passes through the pipe connection setting with the entrance point of reverse osmosis filter core (13), pure water pipe (2) connect and set up on the pure water port of reverse osmosis filter core (13), waste pipe (3) connect and set up on the waste water port of reverse osmosis filter core (13), rearmounted filter core (17) are established ties and are set up on pure water pipe (2), and water dispenser water pump (24) are established ties and are set up on the entrance point of rearmounted filter core (17), the electrodeless heating module (23) are set up on the water dispenser water pump (17) and are set up on one side of the rear filter core (17); characterized in that it further comprises:

the pre-filter element (4) is arranged on the raw water pipe (1) in series;

the raw water quality measuring instrument (5), the raw water quality measuring instrument (5) is arranged on the raw water pipe (1) in series and is positioned at one side of the inlet end of the front filter element (4);

the pure water quality measuring instrument (14), the pure water quality measuring instrument (14) is arranged on the pure water pipe (2) in series and is positioned between the reverse osmosis filter element (13) and the rear filter element (17);

the first booster pump (6) is arranged on the raw water pipe (1) in series and is positioned between the pre-filter element (4) and the pressure barrel (10);

the second booster pump (8) is arranged on the raw water pipe (1) in series and is positioned between the pre-filter element (4) and the pressure barrel (10), and the first booster pump (6) and the second booster pump (8) are arranged in parallel;

the pressure sensor (11) is arranged on the pure water pipe (2) in series and is positioned between the pressure barrel (10) and the activated carbon filter element (12);

the flowmeter (15) is arranged on the pure water pipe (2) in series and is positioned between the pure water quality measuring instrument (14) and the rear filter element (17);

the first waste water electromagnetic valve (18), the first waste water electromagnetic valve (18) is arranged on the waste water pipe (3) in series;

the second wastewater electromagnetic valve (19), the second wastewater electromagnetic valve (19) is arranged on the wastewater pipe (3) in series;

the waste water cleaning valve (20), the waste water cleaning valve (20) is arranged on the waste water pipe (3) in series, and the first waste water electromagnetic valve (18), the second waste water electromagnetic valve (19) and the waste water cleaning valve (20) are arranged in parallel;

the control valve (21) is arranged on the pure water pipe (2) in series and is positioned between the rear filter element (17) and the water pump (24) of the water dispenser;

the water level sensor (22) is arranged on the pure water pipe (2) in series and is positioned between the control valve (21) and the water pump (24) of the water dispenser.

2. The novel instant heating type table top water dispenser according to claim 1, wherein: the outlet end of the first booster pump (6) is provided with a first check valve (7) in series, the outlet end of the second booster pump (8) is provided with a second check valve (9) in series, the first check valve (7) and the second check valve (9) are arranged in parallel, the pure water pipe (2) is provided with a third check valve (16) in series, and the third check valve (16) is arranged between the flowmeter (15) and the rear filter element (17).

3. The novel instant heating type table top water dispenser according to claim 1, wherein: the front filter element (4) is of a PP cotton filter element structure.

4. The novel instant heating type table top water dispenser according to claim 1, wherein: the rear filter element (17) is of an active carbon filter element structure.

5. The novel instant heating type table top water dispenser according to claim 1, wherein: the water level sensor (22) is of a floating ball type liquid level device structure.

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