CN114409008A - Annular atomizing conduit and atomizing separator - Google Patents

Abstract

The invention discloses an annular atomizing guide pipe which comprises a first input device, a second input device, an annular pipe and an output device, wherein an inlet is arranged at the side part of the annular pipe, the first input device and the second input device are both communicated with the inlet in a sealing way, the first input device is used for introducing gas, the second input device is used for introducing raw water, the output device is arranged on the pipe wall of the annular pipe, the raw water and the gas are in the annular pipe and collide and mixed through the inner wall of the annular pipe to form atomized bubble water with fine bubbles, and the bubble water is guided by the output device and is output to the outside. The invention can slightly mix fine bubbles with raw water to form mist bubble water for separating collagen-like organisms, organic matters and large-particle impurities in the water.

Description

Annular atomizing conduit and atomizing separator

Technical Field

The invention relates to an atomization device, in particular to an annular atomization conduit and an atomization separation device.

Background

Atomizing devices are often used in environments where dust removal and humidification are required, where liquids such as water are dispersed into fine droplets by passing the liquids through nozzles or by high velocity gas flow. The small liquid drops are then diffused freely to the outside, and the atomization to the environment is completed. Generally speaking, the flow direction of the small liquid drops is not restricted, and the small liquid drops are scattered around by the original power of the atomization outlets. Therefore, the common atomization device only needs to consider the atomization outlet facing away from the atomization device body.

In addition, water purifiers are commonly used to filter domestic water (such as tap water and raw water), and the working principle of these water purifiers is as follows: the method uses a ceramic core, a pp cotton core, activated carbon or a quartz sand core, and adopts an interception filtration water purification treatment mode without a wastewater discharge port. In the actual use process, the water body smaller than the aperture of the filter membrane core in raw water is forced to pass through the membrane core by simply utilizing the water inlet pressure of the raw water, and large-particle impurities (such as silt, yellow muddy water, rust, collagen and the like) larger than the aperture of the filter membrane core are accumulated and adhered to the surface of the filter membrane core under strong water pressure for a long time. After long-term use, the filter membrane holes are blocked, the interception effect of the filter element is reduced, and the filter element becomes a hotbed for breeding bacteria and viruses, so that cross contamination among a plurality of filter elements is caused, and the hidden danger of safe and sanitary drinking water of families is formed.

Disclosure of Invention

In order to overcome the defects of the prior art, one of the objectives of the present invention is to provide an annular atomization conduit, which can lightly mix fine bubbles with raw water to form mist bubble water for separating collagen-like organisms, organic matters and large particle impurities in the water.

The invention also aims to provide an atomization separation device using the annular atomization conduit.

One of the purposes of the invention is realized by the following technical scheme:

the utility model provides an annular atomizing pipe, including first input device, the second input device, ring channel and output device, the ring channel lateral part disposes the entry, first input device and second input device all with the sealed intercommunication of entry, first input device is used for letting in gas, the second input device is used for letting in the raw water, the pipe wall of ring channel is located to output device, raw water and gas are in the ring channel, form the vaporific bubble water of the tiny bubble of area through the collision of ring channel inner wall, bubble water leads and exports the external world through output device.

Preferably, the output device is a plurality of spray holes formed in the wall of the annular pipe, and the diameter of each spray hole is smaller than the inner diameter of the annular pipe.

Preferably, the spray holes are arranged around the annular tube at equal intervals, and the spray holes are positioned at the side part of the annular tube.

Preferably, the spray holes are arranged in a plurality of rows at equal intervals around the annular tube, and the spray holes are positioned at the side, the top and the bottom of the annular tube.

Preferably, the outer wall of the annular tube is circular arc-shaped.

Preferably, the output device is a plurality of nozzles arranged on the wall of the annular pipe, and the nozzles are used for further atomizing the bubble water in the annular pipe.

Preferably, the second inlet device has a water passage for introducing raw water to the inlet, and the first inlet device is connected to the water passage and communicates with the water passage.

Preferably, the first input device is a first input pipe, the second input device is a second input pipe, the second input pipe is in butt joint with the inlet and communicated with the inlet, and the first input pipe is connected to the second input pipe in a bypassing mode.

Preferably, the first input pipe and the second input pipe are respectively provided with a valve body.

The second purpose of the invention is realized by the following technical scheme:

the atomizing separator includes one sealed container and one annular atomizing duct, and the annular duct extends into the sealed container and has at least one output unit opposite to the inner wall of the sealed container.

Compared with the prior art, the invention has the following beneficial effects:

according to the invention, through the communicated configuration of the first input device and the second input device with the inlet and the annular pipe, when raw water is introduced into the second input device, negative pressure is formed at the annular pipe and the inlet, so that gas can be automatically sucked into the annular pipe, the device is particularly suitable for daily use, the gas is outside air, no additional equipment such as an air pump is needed, raw water can be simply changed into mixed fine bubbles to form atomized bubble water, the atomized bubble water can be sent out along the preset direction of the output device to be separated by subsequently forming water flow, and the mode of the atomized bubble water can be used for separating raw water in a layered manner. The atomization separation device leads and collects the mist bubble water output by the output device, a pressure area is naturally formed above the closed container, the mist bubble water continuously flows into the pressure area, the output mist bubble water guided by the annular pipe forms turbulence in the closed container, under the separation action of the turbulence, water buoyancy and impurity gravity, the mist bubble water is separated into an upper section interface layer, a middle section interface layer and a lower section interface layer with different weight, the upper section water body is generally collagen-shaped organisms and organic matters lighter than water, the middle section is gasification fine bubble water, the lower section is sludge heavier than the water body, iron rust, yellow water and other large-particle impurities, so that the separation of raw water can be realized without using materials such as a filter screen, the gasification fine bubble water in the middle section can be utilized, the condition of cross contamination caused by using the filter element and the filter screen is avoided, and the water purification cost is greatly reduced.

Drawings

FIG. 1 is a schematic view of the construction of an annular atomizing conduit according to the present invention;

FIG. 2 is a schematic structural view of the annular tube of the present invention;

FIG. 3 is a schematic structural diagram of an atomization separation device of the present invention;

FIG. 4 is a schematic view of the inside of the atomization separation apparatus of the present invention.

In the figure: 1. a first input device; 2. a second input device; 3. an output device; 4. an annular tube; 5. an inlet; 6. spraying a hole; 7. a valve body; 8. and (4) sealing the container.

Detailed Description

The invention is described in further detail below with reference to the figures and the specific embodiments. In the present specification, the terms "upper", "inner", "middle", "left", "right" and "one" are used for clarity of description only, and are not used to limit the scope of the present invention, and the relative relationship between the terms and the modifications may be regarded as the scope of the present invention without substantial technical changes.

An annular atomizing conduit as shown in fig. 1-2 comprises a first input device 1, a second input device 2, an annular tube 4 and an output device 3, wherein an inlet 5 is configured at the side of the annular tube 4, the first input device 1 and the second input device 2 are both communicated with the inlet 5 in a sealing manner, the first input device 1 is used for introducing gas, the second input device 2 is used for introducing raw water, the output device 3 is arranged on the tube wall of the annular tube 4, the raw water and the gas are mixed in the annular tube 4 through collision of the inner wall of the annular tube 4 to form atomized bubble water with fine bubbles, and the bubble water is guided by the output device 3 and is output to the outside.

Through the first input device 1, the second input device 2 and the intercommunication configuration of entry 5, ring pipe 4, when can making the second input device 2 let in raw water, will be at least at ring pipe 4 the 5 departments of entry form the negative pressure, so, gaseous can be inhaled ring pipe 4 automatically, so can be particularly suitable for daily use, gaseous then is the outside air, need not additionally to add equipment such as air pump, can simply realize that the raw water becomes to mix fine bubble and form vaporific bubble water, make vaporific bubble water can send out along output device 3's predetermined direction to supply follow-up formation rivers to realize the separation, the mode of this vaporific bubble water more enables raw water layering separation.

The raw water in this embodiment may also be water such as tap water, and preferably may be pumped into the second input device 2 by pressure, so as to facilitate easier atomization of the bubble water by the output device 3. Of course, for the case where a better atomization is particularly desired, the first inlet means 1 may also be pressurized and supplied with gas. In this case, the gas is preferably ambient air.

As a preferable mode of the output device 3, the output device 3 is a plurality of spray holes 6 formed in the pipe wall of the annular pipe 4, and the diameter of the spray holes 6 is smaller than the inner diameter of the annular pipe 4. The spray holes 6 are circular holes, raw water entering the annular pipe 4 is collided and guided by the inner wall of the annular pipe 4 to be mixed with air, bubble water is formed and then accelerated at the spray holes 6, and accordingly the mist bubble water is formed.

In order to make the output mist bubble water more favorable to form turbulent flow after being collected, the spray holes 6 of the embodiment are a plurality of spray holes arranged around the annular pipe 4 at equal intervals, and the spray holes 6 are positioned at the side part of the annular pipe 4. The atomized bubble water output from the side part can directly impact and collide with the external closed container 8 to laterally and rapidly form turbulent flow.

In order to increase the atomization amount, the spray holes 6 of the present embodiment are provided in a plurality of rows at equal intervals around the annular tube 4, and the spray holes 6 are located at the side, top and bottom of the annular tube 4. In order to further facilitate the improvement of the atomization uniformity, the outer wall of the annular tube 4 of the embodiment is arc-shaped, so that the arrangement of the spray holes 6 also forms an arc-shaped arrangement, and the spray holes can be sprayed to the periphery more uniformly so as to mix the air and the raw water more fully and form a layered turbulent flow.

In an alternative embodiment, for the water body which is easy to atomize or needs to be easier to separate out multiple layers of turbulent flow, the output device 3 is a plurality of nozzles arranged on the pipe wall of the annular pipe 4, the nozzles are used for further atomizing the bubble water in the annular pipe 4, and the nozzles can be configured in a mode of being provided with an extending nozzle and gradually narrowing openings. The mode of the nozzle is more beneficial to atomizing water and fully mixing air and raw water, so that collagen-like organisms and organic matters in the raw water are driven upwards by more full and finer bubbles and float upwards for separation.

In order to mix the gas more thoroughly with the raw water, the second inlet 2 of the present embodiment has a water passage for introducing the raw water into the inlet 5, and the first inlet 1 is connected to and communicates with the water passage. Therefore, gas (such as air) can be mixed with raw water in the first input device 1, the mixing time is prolonged, the mixing is more sufficient, the volume of the annular atomizing conduit is saved, and the structure is smaller. In this example, the first input device 1 is a first input pipe, the second input device 2 is a second input pipe, the second input pipe is butted with the inlet 5 and communicated with the inlet 5, and the first input pipe is connected to the second input pipe. The first input device 1 and the second input device 2 are tubular, so that the butt joint of raw water or tap water of a pipeline output by the pressure of a pump is facilitated.

In order to control the input amount of the gas and/or the raw water or control the on-off of the gas and/or the raw water, the first input pipe and the second input pipe are respectively provided with a valve body 7, so that the mixing degree of the gas and the raw water can be conveniently adjusted.

As shown in fig. 3-4, the atomization separation device of this embodiment includes a closed container 8 and the annular atomization conduit, the annular tube 4 extends into the closed container 8, and at least one output device 3 is opposite to the inner wall of the closed container 8, the first input device 1 and the second input device 2 extend out of the closed container 8, and the annular tube 4 is fixedly mounted on the closed container 8 through the first input device 1 or the second input device 2. The output device 3 is opposed to the inner wall of the closed vessel 8 to form a turbulent flow revolving along the inner wall of the closed vessel 8 by collision to whirlingly separate the water body.

The atomization separation device of the embodiment guides and collects the mist bubble water output by the output device 3, a pressure area is naturally formed above the inner part of the closed container 8, the mist bubble water continuously flows into the pressure area, the output mist bubble water guided by the annular pipe 4 forms turbulence in the closed container 8, under the separation action of the turbulence, the water buoyancy and the gravity of impurities, the mist bubble water is separated into an upper section interface layer, a middle section interface layer and a lower section interface layer with different weight qualities, the upper section water body is generally collagen organisms and organic matters lighter than water, the middle section is gasification fine bubble water, the lower section is silt heavier than the water body, iron rust, yellow water and other large-particle impurities, thus, the separation of raw water can be realized without materials such as a filter screen, the gasification fine bubble water in the middle section can be utilized, the condition of cross contamination caused by using the filter element and the filter screen is avoided, and the water purification cost is greatly reduced.

The embodiments of the present invention are not limited thereto, and according to the above-mentioned contents of the present invention, the present invention can be modified, substituted or combined in other various forms without departing from the basic technical idea of the present invention.

Claims (10)

1. The utility model provides an annular atomizing pipe, a serial communication port, including first input device, the second input device, ring channel and output device, the ring channel lateral part disposes the entry, first input device and second input device all with the sealed intercommunication of entry, first input device is used for letting in gas, the second input device is used for letting in the raw water, output device locates the pipe wall of ring channel, raw water and gas are in the ring channel, form the vaporific bubble water of the fine bubble of zone through the collision mixing of ring channel inner wall, bubble water leads and exports the external world through output device.

2. The annular atomizing conduit of claim 1, wherein the outlet means is a plurality of orifices formed in the wall of the annular tube, the orifices having a smaller diameter than the inner diameter of the annular tube.

3. The annular atomizing conduit of claim 2, wherein the spray holes are a plurality of spray holes equally spaced around the annular tube and the spray holes are located at a side of the annular tube.

4. The annular atomizing conduit of claim 2, wherein the spray holes are in a plurality of rows equally spaced around the annular tube and the spray holes are located at the sides, top and bottom of the annular tube.

5. The annular atomizing conduit of claim 2, wherein the outer wall of the annular tube is radiused.

6. The annular atomizing conduit of claim 2, wherein the output means is a plurality of nozzles disposed in the wall of the annular tube for further atomizing the bubble water in the annular tube.

7. The annular atomizing conduit according to any one of claims 1 to 6, wherein the second inlet means has a water passage for introducing raw water to the inlet, and the first inlet means is connected to and communicates with the water passage by the water passage.

8. The annular atomizing conduit of claim 7, wherein the first input device is a first input tube and the second input device is a second input tube, the second input tube being in abutting communication with the inlet, the first input tube being connected by the second input tube.

9. The annular atomizing conduit of claim 8, wherein the first inlet conduit and the second inlet conduit are each configured with a valve body.

10. An atomizing separator comprising a closed vessel and an annular atomizing conduit according to any one of claims 1 to 9, the annular conduit extending into the closed vessel and having at least one outlet means opposite the inner wall of the closed vessel, the first inlet means and the second inlet means extending outside the closed vessel, the annular conduit being fixedly mounted to the closed vessel by the first inlet means or the second inlet means.

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