KR102465402B1 - Dissolved Air or Ozone water treatment equipment - Google Patents

Abstract

The present invention relates to a dissolution water treatment apparatus of a water treatment means with enhanced dissolution efficiency which can efficiently dissolve air or ozone with water by being applied to a dissolved air floatation (DAF) method or a dissolved ozone floatation (DOF) method. More specifically, the dissolution water treatment apparatus equipped in a water treatment means using DAF or DOF comprises: a mixing tank (100) connected to a pressurization tank (10) while mixing and discharging inflow water supplied from the pressurization tank (10) with air or ozone supplied from the outside; a dissolution water storage tank (200) having one side pipe-connected to the mixing tank (100) and the other side pipe-connected to a nano-bubble generation unit (20) and accommodating the mixed dissolved water to supply the dissolution water to the nano-bubble generation unit (20); and a compressor (C) pipe-connected to the mixing tank (100) to supply air or ozone necessary for generating the dissolution water.

Description

Dissolved air or ozone water treatment equipment of water treatment means with improved dissolution efficiency {Dissolved Air or Ozone water treatment equipment}

The present invention is applied to Dissolved Air Flotation (DAF) or Dissolved Ozone Flotation (DOF) to dissolve water treatment means with improved dissolution efficiency that can efficiently dissolve air or ozone together with water. It is about a water treatment system.

In general, water treatment systems include Dissolved Air Flotation (DAF), which is a water treatment method by dissolving air and water, and Dissolved Ozone Flotation (DOF), which is a method of treating water by dissolving ozone in water. However, it is common to use dissolved water and air or water and ozone for both methods.

That is, as in the prior art shown in FIG. 1, in dissolving water and air or water and ozone, water and air or ozone are directly supplied into the dissolution tank so that the dissolution is performed for a certain period of time inside the dissolution tank. It is supplied to the pressure tank 10 equipped with the microbubble or nanobubble generator 20.

However, the conventional dissolution tank must be provided with a large amount of filler to improve the dissolution rate, and the inconvenience of continuously adjusting the water level or controlling the pressure through the control unit occurs, and due to the supply of such filler, the dissolution tank A problem arises in that there is a limiting factor for the installation space, which must have a considerable volume.

In addition, clogging of the pipe occurs frequently in the process of dissolving water due to the use of the filler, and thus the increase in working time due to frequent maintenance also causes another problem.

Korean Patent Publication No. 10-2003-72986 (published date: 2003.09.19.) Domestic Patent No. 10-0509813 (Announcement date: 2005.08.24.) Korean Patent Publication No. 10-2015-93985 (published date: 2015.08.19.)

In order to solve the above-mentioned problems of the prior art, the present invention improves the dissolution rate of water and air (or ozone) without using a filler, but implements a slimming tank volume while lowering the control point through the control unit and economically necessary for manufacturing. An object of the present invention is to provide a dissolved water treatment device capable of reducing the number of times for maintenance while having a phosphorus advantage.

In order to solve the above-described technical problem, the dissolved water treatment device of the water treatment means with improved dissolution efficiency according to the present invention is a dissolved water treatment device provided in the water treatment means using dissolved air flotation (DAF) or dissolved ozone flotation (DOF). In the dissolution water treatment device, the mixing tank 100, which is pipe-connected to the pressurization tank 10 and mixes and discharges the inflow water supplied from the pressurization tank 10 and air or ozone supplied from the outside, and one side A dissolved water storage tank 200 that is pipe-connected to the mixing tank 100 and the other side is pipe-connected to the nano-bubble generator 20, receives the mixed dissolved water and supplies it to the nano-bubble generator 20, and the It is characterized in that it includes a compressor (C) connected to the mixing tank 100 and supplying air or ozone necessary for generating dissolved water.

In addition, the dissolved water supplied to the nanobubble generator 20 is first dissolved in the fluid pipe 110 transferred from the mixing tank 100 to the dissolved water storage tank 200, and the dissolved water The secondary dissolution is made in the storage tank 200, and the primary dissolution time (T1) in the fluid pipe 110 is longer than the dissolution time (T2) in the dissolved water storage tank 200. It's better to take your time.

In addition, the dissolved water storage tank 200 further includes a bypass member 210 controlled by a control unit, and one end of the bypass member 210 is pipe-connected to the fluid pipe 110, but the other side is inlet water A bypass pipe 211 connected to the inlet side of the mixing tank 100 to which is supplied, a first valve 213 provided at one end of the bypass pipe 211 to be opened and closed by the control unit, and a control unit It is provided in the fluid pipe 110 to be located between the second valve 215 provided at the other end of the bypass pipe 211 and the mixing tank 100 and the first valve 213 to be opened and closed by It includes a detection sensor 217 that detects the dissolution rate of the dissolved water transported through the fluid pipe 110 and transmits the detection information to the control unit, and the first dissolution time (T1) in the fluid pipe 110 is It is preferable that the melting time is between the mixing tank 100 and the detection sensor 217.

In addition, the control unit controls the first valve 213 and the second valve 215 when the detection information of the detection sensor 217 is less than the set value stored in the control unit, so that the primary dissolved water is supplied to the bypass pipe 211 ), it is preferable to re-accept the mixing tank 100 together with the inflow water so that re-mixing is performed.

In addition, a rotatable mixing member 120 is further provided inside the mixing tank 100, and the mixing member 120 is formed in a tubular shape and is rotatably installed inside the mixing tank 100. Mixing body 121 ) and a plurality of perforations 123 formed to have a regular or irregular pattern on the outer surface of the mixing body 121, but the mixing body 121 is inside the mixing tank 100 by the discharge pressure of the inflow water It is preferable to install so that it can rotate.

According to the present invention, in the DAF method or the DOF method, which is applied to water treatment means differently from the prior art, air or ozone is not supplied to the inside of the dissolution tank to which influent is supplied and dissolved, and the influent and air (or ozone) is firstly dissolved in the fluid pipe for a certain period of time in the process of being transported to the dissolved water storage tank, and is secondarily dissolved in the dissolved water storage tank for a certain period of time. It is possible to significantly reduce the size of, and at the same time, the configuration of the filler accommodated in the conventional dissolution tank does not exist, so the effect of preventing clogging due to the filler is realized.

In addition, unlike the prior art, since separate control through the control unit is omitted, such as adjusting the water level of the dissolved water storage tank, operation is simplified, as well as the economic burden of manufacturing to implement the treatment device of the present invention is reduced. will implement

1 is a conceptual diagram showing a water treatment system using a conventional DAF or DOF method;
Figure 2 is a conceptual diagram of a water treatment system to which the dissolved water treatment device of the water treatment means having improved dissolution efficiency according to the present invention is applied.
3 is a view showing a dissolved water treatment device of a water treatment means having improved dissolution efficiency according to the present invention.
Figure 4 is a view showing the inside of the mixing tank for Figure 3;
5 and 6 are views showing a flow chart of dissolved water according to the detection result of the primary dissolved water for the dissolved water treatment device of the water treatment means having improved dissolution efficiency according to the present invention.
7 is another embodiment of a mixing body for the dissolution water treatment device of the water treatment means with improved dissolution efficiency according to the present invention.

Hereinafter, various embodiments will be described in more detail with reference to the accompanying drawings. The embodiments described in this specification may be modified in various ways. Certain embodiments may be depicted in the drawings and described in detail in the detailed description. However, specific embodiments disclosed in the accompanying drawings are only intended to facilitate understanding of various embodiments. Therefore, the technical idea is not limited by the specific embodiments disclosed in the accompanying drawings, and it should be understood to include all equivalents or substitutes included in the spirit and technical scope of the invention.

Terms including ordinal numbers, such as first and second, may be used to describe various components, but these components are not limited by the above terms. The terminology described above is only used for the purpose of distinguishing one component from another.

In this specification, terms such as "comprise" or "having" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more other features It should be understood that the presence or addition of numbers, steps, operations, components, parts, or combinations thereof is not precluded. It is understood that when an element is referred to as being "connected" or "connected" to another element, it may be directly connected or connected to the other element, but other elements may exist in the middle. It should be. On the other hand, when an element is referred to as “directly connected” or “directly connected” to another element, it should be understood that no other element exists in the middle.

In addition, in describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be abbreviated or omitted.

Hereinafter, a dissolved water treatment device (hereinafter, simply referred to as a 'treatment device') of a water treatment means having improved dissolution efficiency according to the present invention will be described in detail with reference to the accompanying drawings.

Prior to the description, the treatment device 1 in the present invention is a method of treating water by dissolving air and water used in the water treatment means (DAF: Dissolved Air Flotation) or a method of dissolving ozone and water to treat water Note that the treatment device 1 can be applied to both dissolved ozone flotation (DOF), and will be described below as an example for dissolving air and water.

First, as shown in FIGS. 2 and 3, the processing apparatus 1 according to the present invention largely includes a mixing tank 100, a dissolved water storage tank 200, and a compressor C, but in addition to the above components A control unit (not shown) for controlling at least one of may be further included.

More specifically, referring to FIG. 4, the mixing tank 100 is a mixing member ( 120).

For example, as shown, the mixing tank 100 is formed in the shape of a hollow enclosure as a whole, and the outer surface is pipe-connected to the pressure tank 10, the compressor C, and the dissolving water storage tank 200 to be described later. After mixing the inflow water and air therein, it is supplied to the dissolved water storage tank 200 through a pump or the like.

In this process, the mixing tank 100 and the dissolved water storage tank 200 are interconnected through a fluid pipe 110 having a predetermined length, and the water mixed in the fluid pipe 110 is primarily to have a dissolvable structure.

Here, the dissolved water that is primarily dissolved in the fluid pipe 110 is transported in the fluid pipe 110 for at least 30 seconds or more to have a time T1 in which dissolution takes place, and the corresponding time T1 is shown in the figure. As shown, it means the time to transfer along the fluid pipe 110 from the outlet side of the mixing tank 100 to the detection sensor 217.

The mixing member 120 for maximizing the mixing effect of inflow water and air includes a mixing body 121 and a perforation part 123.

As shown, the mixing body 121 is located inside the mixing tank 100, but at least one of its upper part or lower part is axially coupled so that it can rotate in the mixing tank 100. The inflow water and air introduced into the mixing tank 100 generate a turbulence phenomenon so that mixing is performed.

At this time, the mixing body 121 is molded into a hollow cylindrical tube shape, and a plurality of perforations 123 having regular or irregular patterns on the outer surface thereof are perforated to communicate with the inside of the mixing body 121. Preferably do.

On the other hand, as shown, the mixing body 121 in the present invention does not rotate in the mixing tank 100 in another embodiment, but the fluid pipe 110 through which the primary dissolved water is discharged, as well as inflow water, air or ozone It is also possible that the inlet pipe is installed so that it can pass through the inside of the mixing body 121 (see FIG. 7).

As shown, the perforations 123 may be perforated to have different diameters or may be perforated to have the same diameter, and the inflow water and air pass in and out through the plurality of the perforations 123 to achieve a mixing effect. to be maximized.

In addition, the power required for the rotation of the mixing body 121 is rotated by the discharge pressure of the inflow water, and for this purpose, the inflow water flowing into the mixing tank 100 is supplied from the side of the mixing tank 100 to the inside It is connected to the pressure tank 10 to have a structure.

On the other hand, although not shown, each of the perforations 123 collides with inflow water having a predetermined discharge pressure to improve the rotational force of the mixing body 121. Outward or inward protrusions (not shown) may be further formed. have.

Further, referring to FIG. 5, the dissolved water storage tank 200 stores the dissolved water that is firstly dissolved and transported in the fluid pipe 110 and is secondarily dissolved so that the nanobubble generating unit 20 needs to dissolve. It includes a bypass member 210 as a configuration for supplying water through a pump or the like.

For example, the dissolved water storage tank 200 is made in the shape of a hollow enclosure as a whole, but has a structure connected to the nanobubble generator 20 as well as the fluid pipe 110 soccer side on the outer surface, so that 1 Secondary dissolution is performed for a predetermined time (T2) while the primary dissolved dissolved water is stored.

At this time, the dissolution time for obtaining the dissolved water to be supplied to the nanobubble generator 20 is the time during which the primary dissolution (T1) in the fluid pipe 110 is dissolved in the dissolved water storage tank 200 It is preferable to make the size of the dissolved water storage tank 200 relatively small compared to the prior art by allowing it to be applied larger than (T2).

Through this, in contrast to the prior art, even if the filler 31 necessary for dissolving inflow water and air is not provided inside the dissolved water storage tank 200, the desired dissolved water can be obtained and at the same time clogging due to the filler 31 The phenomenon can be prevented, and furthermore, the level control of the dissolved water accommodated in the dissolved water storage tank 200 is omitted, and the control function through the control unit is also significantly reduced, thereby providing convenience in maintenance and economic benefits required for manufacturing. It has the advantage of simplifying the operation capability of the treatment device 1 according to the present invention.

In addition, as shown in FIGS. 5 and 6, the bypass member 210 detects the degree of dissolution of the primarily dissolved water and automatically determines whether or not the primarily dissolved water is accepted according to the detection information. As a configuration for controlling, it includes a bypass pipe 211, a first valve 213, a second valve 215 and a detection sensor 217.

At this time, the first and second valves 213 and 215 are preferably three-phase valves that can be opened and closed through a control signal from a control unit.

As shown, the bypass pipe 211 is connected so that one end communicates with each other through the fluid pipe 110 and the first valve 213 located between the detection sensor 217 and the dissolved water storage tank 200, , The other end is connected to communicate with the supply pipe between the pressure tank 10 and the mixing tank 100 through the second valve 215.

The detection sensor 217 is provided in the fluid pipe 110 so as to be located in front of the first valve 213, and detects the degree of dissolution of the primary dissolved water transported through the fluid pipe 110 and obtains the detection information. is sent to the control unit.

The control unit receiving such detection information controls a result of whether or not the first dissolved dissolved water is accommodated in the dissolved water storage tank 200 by comparing the previously determined set value with the corresponding detected information.

For example, as shown, the detection sensor 217 detects the dissolved water in which the primary dissolution is made, which is mixed in the mixing tank 100 and transferred to the dissolved water storage tank 200 through the fluid pipe 110, and the control unit If it is determined that the dissolution rate does not reach the set value through the above, the control unit controls the first and second valves 213 and 215 to transfer the primary dissolved water to be supplied to the dissolved water storage tank 200 to the bypass pipe 211. Water is exchanged so that it can be (see Fig. 6).

Thereafter, the primary dissolved water returned to the bypass pipe 211 is re-mixed with the inflow water into the mixing tank 100 through the second valve 215 or by blocking the inflow water and introducing only the primary dissolved water, and At the same time, water is discharged through the fluid pipe 110.

Thus, the re-mixed dissolved water transported to the fluid pipe 110 is re-dissolved during the transport time T1 so that the detection sensor 217 can control the dissolution rate desired by the control unit, through which The generation of bubbles through the nanobubble generating unit 20 is performed more effectively.

And, as shown, the compressor (C) is pipe-connected to the above-described mixing tank 100 and supplies inflow water and air or ozone to be dissolved into the mixing tank 100 through the control of the control unit. , The compressor (C) is conventional, and a detailed description thereof will be omitted so as not to obscure the gist of the present invention.

As described above, the treatment device 1 according to the present invention does not dissolve by supplying air or ozone into the dissolution tank 30 to which inflow water is supplied in the DAF method or the DOF method applied to the water treatment means differently from the prior art. In the process of transporting the inflow water and air (or ozone) mixed in the mixing tank 100 to the dissolved water storage tank 200, the first dissolution takes place in the fluid pipe 110 for a certain period of time T1. The size of the dissolved water storage tank 200 can be remarkably reduced by having a structure in which the dissolved water storage tank 200 undergoes secondary dissolution for a predetermined time period T2, and at the same time, the conventional dissolution tank 30 Since the configuration of the filler 31 accommodated in does not exist, the effect of preventing clogging due to the filler 31 is realized.

In addition, unlike the prior art, since separate control through the controller is omitted, such as adjusting the water level of the dissolved water storage tank 200, operation is simplified, as well as economic efficiency according to manufacturing to implement the treatment device 1 of the present invention. It also realizes the effect of reducing the human burden.

As described above, the present invention has been described by specific details such as specific components and limited embodiments and drawings, but these are provided to help a more general understanding of the present invention, and the present invention is not limited to the above embodiments. , Those skilled in the art in the field to which the present invention belongs can make various modifications and variations from these descriptions.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and it will be said that not only the claims to be described later, but also all modifications equivalent or equivalent to these claims belong to the scope of the present invention. .

One; Dissolution water treatment device of water treatment means with improved dissolution efficiency
100: mixing tank
110: fluid pipe 120: mixing member
121: mixing body 123: perforation
200: dissolved water storage tank
210: bypass member 211: bypass pipe
213: first valve 215: second valve
217: detection sensor
C: Compressor

Claims (5)

In the dissolved water treatment device provided in the water treatment means using dissolved air flotation (DAF) or dissolved ozone flotation (DOF),
The dissolved water treatment device
A mixing tank 100 connected to the pressurization tank 10 and mixing and discharging inflow water supplied from the pressurization tank 10 and air or ozone supplied from the outside;
A dissolved water storage tank 200 having one side connected to the mixing tank 100 and the other side connected to the nanobubble generator 20, receiving the mixed dissolved water and supplying it to the nanobubble generator 20 ; and
A compressor (C) connected to the mixing tank 100 and supplying air or ozone necessary for generating dissolved water; including,
The dissolved water supplied to the nanobubble generator 20 is first dissolved in the fluid pipe 110 transferred from the mixing tank 100 to the dissolved water storage tank 200, and the dissolved water storage tank 200 so that the secondary dissolution takes place, and the primary dissolution time (T1) in the fluid pipe 110 is longer than the dissolution time (T2) in the dissolved water storage tank 200 to have,
The dissolved water storage tank 200 further includes a bypass member 210 controlled by a control unit, wherein one end of the bypass member 210 is pipe-connected to the fluid pipe 110, but the other side is A bypass pipe 211 connected to the inlet side of the mixing tank 100 to be supplied, a first valve 213 provided at one end of the bypass pipe 211 to be opened and closed by the control unit, and a control unit It is provided in the fluid pipe 110 to be located between the second valve 215 provided at the other end of the bypass pipe 211 and the mixing tank 100 and the first valve 213 so as to be opened and closed by It includes a detection sensor 217 that detects the dissolution rate of the dissolved water transported through the fluid pipe 110 and transmits the detection information to the control unit, but the time T1 for primary dissolution in the fluid pipe 110 is Dissolving water treatment device of water treatment means with improved dissolution efficiency, characterized in that the dissolving time between the mixing tank 100 and the detection sensor 217.
delete delete According to claim 1,
the control unit
If the detection information of the detection sensor 217 is less than the set value stored in the control unit, the first valve 213 and the second valve 215 are controlled so that the primary dissolved water passes through the bypass pipe 211 as the inflow water. Dissolving water treatment device of a water treatment means with improved dissolution efficiency, characterized in that it is re-accepted into the mixing tank 100 and re-mixed.
According to claim 1,
A rotatable mixing member 120 is further provided inside the mixing tank 100.
The mixing member 120 is
A mixing body 121 having a tubular shape and rotatably installed inside the mixing tank 100; and
A plurality of perforations 123 perforated to have a regular or irregular pattern on the outer surface of the mixing body 121; including,
Dissolution water treatment device of a water treatment means with improved dissolution efficiency, characterized in that the mixing body 121 is installed to rotate inside the mixing tank 100 by the discharge pressure of the inflow water.

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