JP2003230879A - Method and apparatus for sterilizing flowing water - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To sufficiently irradiate flowing water with ultraviolet rays in a relatively short cylindrical body. <P>SOLUTION: A pipe body made of an ultraviolet-ray transmissible material is installed in the cylindrical body made of an ultraviolet-ray intransmissible material so that they are parallel to each other. One end of the pipe body is opened and made to communicate at one closed end side of the cylindrical body, and a water supply pipe is formed eccentrically to the other end sidewall of the cylindrical body. A plurality of bactericidal lamps are installed parallel to each other between the inner side of the pipe body or inner wall of the cylindrical body and the outer wall of the pipe body, and a water discharge pipe is connected to the other end of the pipe body. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sterilizing method and a sterilizing apparatus for flowing water, which is intended to surely sterilize by flowing a relatively short distance.

[0002]

2. Description of the Related Art Conventionally, for sterilizing flowing water with ultraviolet rays, an inlet is provided on one side of a sterilization tank equipped with an ultraviolet lamp and an outlet is provided on the other side, so that the flowing water is temporarily put into the sterilization tank. I try to make it stay. In addition to the above, an ultraviolet lamp is also installed in the water pipe.

Further, there is known an ultraviolet sterilizer in which an ultraviolet lamp is installed in the central portion of a cylindrical container, water is eccentrically fed from one side of the cylindrical container, and water is discharged from the other side (Japanese Patent Laid-Open No. Hei. 10-272460).

The applicant of the present patent has proposed an invention in which a tube is installed in parallel inside a tube and a sterilizing lamp is installed between the inner wall of the tube and the outer wall of the tube (Japanese Patent Application No. 2000- 303
129).

[0005]

The above sterilizers have achieved their respective objectives. However, due to the relationship between the amount of water supplied and the ultraviolet lamp (ultraviolet capacity), there are various points such as uniform irradiation of ultraviolet rays and flow distance. There was a point to improve.

Further, in the above-mentioned published invention, the water is spirally flowed, there is no change in the flow velocity, and the ultraviolet irradiation has temporal identity, but the density identity tends to be inaccurate. There was a point.

Next, the applicant's prior application had a problem when the cylindrical body had a relatively small diameter (small capacity) or a large diameter (large capacity).

[0008]

According to the present invention, the above-mentioned problems are solved by causing the sterilizing lamp to reciprocate the water supply in and out and to change the flow velocity and the flow direction. Further, it can be used when the cylindrical body has a small diameter or a large diameter.

That is, according to the invention of the method, the sterilizing lamps arranged in parallel to the inside or outside of the tubular body in the tubular body change the flow velocity and the flowing direction of the water flowing in the tubular body.
This is a method of sterilizing flowing water by sterilizing the water by reciprocating the reciprocating flow. The reciprocating flow causes the inner peripheral side of the tubular body to flow and then the tubular body.

Further, in the invention of the apparatus, a tube body made of an ultraviolet ray transmitting material is installed in parallel inside a tube body made of an ultraviolet ray opaque material, and one end of the tube body is attached at one end closed side of the tube body. A water supply pipe is provided so as to communicate with the opening and eccentrically to the other end side wall of the tubular body, and a plurality of sterilization lamps are installed in parallel between the inner wall of the tubular body or the inner wall of the tubular body and the outer wall of the tubular body. A sterilizing apparatus for flowing water, characterized in that a water outlet pipe is connected to the other end of the pipe body. Next, the tubular body is a metal tube provided with a protective layer on the inner wall, and the tubular body is a quartz glass tube.

The sterilizing lamp is provided with ultraviolet rays (2
It is an ultraviolet lamp containing a part of deep ultraviolet rays (1900 to 1700 angstroms) from 900 to 1900 angstroms. The output of the ultraviolet lamp and the irradiation time are determined according to the amount of water, the water quality and the use.

The change of the flow velocity in the present invention varies depending on the time to be retained (time to sterilize), but for example, the diameter and length of the tubular body and the tubular body are determined within the range of 2 to 10 times the inflow rate. . Does not prevent the use of germicidal lamps in place of UV lamps.

The amount of eccentricity of the water pipe is determined according to the desired change in the flow direction. For example, the outer wall of the pipe is set at the center of the water pipe. When the swirl inflow is insufficient due to the eccentric inflow, the direction of the water flow can be regulated by using the guide vanes.

In the present invention, a small capacity (for example, 2 m ³
/ Hour), the diameter of the cylinder will inevitably become smaller, so a sterilization lamp should be installed inside the tube. In addition, in the case of a large capacity, a sterilization lamp is provided inside and outside the tube.

The protective layer in the present invention is considered to be a synthetic resin or an inorganic paint of a quality in which the inner wall of the cylinder is protected and the adhesion of fine particles in water is small.

[0016]

BEST MODE FOR CARRYING OUT THE INVENTION According to the present invention, a sterilizing lamp arranged in parallel to the inside or the outside of a pipe body changes the flow speed and the flow direction of the water supply flowing in the cylinder, while reciprocating the water supply. It is a method for sterilizing flowing water, which is characterized by sterilization by flowing water.

Further, a tube body made of an ultraviolet ray permeable material is installed in parallel at the center of a tube body made of an ultraviolet ray opaque material, and one end of the tube body is opened and communicated with one end closed side of the tube body.
While providing a water pipe eccentrically to the other end wall of the tubular body, a plurality of sterilizing lamps are installed in parallel and at equal intervals between the inner wall of the tubular body and the outer wall of the tubular body. It is a fluid water sterilizer with a water outlet pipe connected to the other end.

The present invention irradiates a sufficient amount of ultraviolet rays at a relatively short distance in accordance with the amount of processing capacity to completely sterilize. The ultraviolet lamp also includes an ozone lamp. In the present invention, the flow velocity of the flowing water can be changed by changing the area of the flow passage, and in order to make the spiral flow, the water supply pipe is eccentric, and if necessary, guide vanes are provided to change the flow direction for water supply.

As a protective layer on the inner wall of the cylinder of the present invention,
For example, a tetrafluoroethylene polymer (registered trademark “Teflon”) is used to protect from ultraviolet rays and prevent adhesion of foreign matter.

[0020]

Embodiment 1 An embodiment (small capacity) of the present invention is shown in FIGS.
3 will be described. The glass tube 2 is installed inside the stainless steel tube 1, and the ultraviolet lamps 3 and 3 are inserted into the glass tube 2.
(For example, UV-C, 2357 angstrom) are arranged at equal intervals. One end of the stainless steel cylinder 1 is a closing plate 4
And the flow path on the inner peripheral side of the stainless steel cylinder 1 and the one end opening of the glass tube 2 are communicated with each other on the closing plate 4 side of the stainless steel cylinder 1.
The water supply pipe 5 is eccentrically connected to the other end of the.

The other end of the glass tube 2 penetrates the closing plate 4a at the other end of the stainless steel cylinder 1 and is eccentrically connected to the water outlet pipe 6. In the figure, 7 is a tetrafluoroethylene polymer layered on the inner wall of the stainless steel cylinder 1, 8 is a sight glass, 9, 9
Is a support leg. In the figure, 10 is a support plate for the glass tube 2.

In the above embodiment, when the water to be sterilized is supplied from the water supply pipe 5 as shown by the arrow 11, the water is guided by the guide vanes 12, and as shown by the arrows 13, 14, 15, the stainless steel cylinder 1 Moves spirally between the inner wall of the glass tube and the outer wall of the glass tube 2 (swirl flow) to reach the inside of the closing plate 4, changes the direction as shown by the arrow 16, and is guided by the spiral blade 17. It becomes a swirling flow and the flow velocity also changes (becomes faster), enters the glass tube 2, swirls and flows in the glass tube 2 as shown by arrows 18 and 19, and is taken out from the water discharge pipe 6 as shown by arrow 20. Be done. If the water supply pipe 5 and the water discharge pipe 6 have the same inner diameter, the water flow has the same flow velocity in this portion.

Therefore, if the cross-sectional area of the water pipe 5 is set to 1/6 of the cross-sectional area of the gap between the inner wall of the stainless steel tube 1 and the outer wall of the glass pipe 2, the flow velocity in the water pipe 5 is 1 m / m. When it is set to sec, the flow velocity in the gap becomes 1/6 m / sec. However, since the glass tube 2 also has a swirling flow, the flow velocities of the respective parts may differ.

If the cross-sectional area of the glass tube 2 is 4 times the cross-sectional area of the water supply tube, the flow velocity in the glass tube 2 is 1/4 m / se.
c. In the above, for example, 90 at 50 m ³ / h
Use a 0 W UV lamp.

As described above, the water pipe 5 and the stainless steel tube 1
The flow velocity can be changed by changing the cross-sectional area of the gap between the inner wall of the glass tube and the outer wall of the glass tube 2 and the cross-sectional area of the glass tube 2. Further, by making the water flow swirl, it is possible to irradiate the ultraviolet rays uniformly and for a long time.

In the above description, the glass tube 2 has a relatively large diameter and the ultraviolet lamps 3 are installed therein, so that the ultraviolet lamp can be easily installed even when the capacity is small.

[0027]

[Embodiment 2] Another embodiment (large capacity) of the present invention is shown in FIG.
5 and 6 will be described. The glass tube 2 is installed in parallel in the central part of the stainless steel tube 1, and the ultraviolet lamps 3, 3 (for example, UV-C, 3357 angstrom) are installed in the central part between the inner wall of the stainless steel tube 1 and the outer wall of the glass tube 2. )
Are arranged at equal intervals.

One end of the stainless steel tube 1 is closed by a closing plate 4, and the flow passage on the inner peripheral side of the stainless steel tube 1 and the one end opening of the glass tube 2 are closed by the closing plate 4. 4 side is communicated, the stainless steel cylinder 1
The water supply pipe 5 is eccentrically (tangentially) connected to the side wall of the other end.

The other end of the glass tube 2 penetrates the closing plate 4a at the other end of the stainless steel cylinder 1 and is connected to the water discharge pipe 6. Outside the glass tube 2, ultraviolet lamps 3a, 3
a are arranged in parallel and at equal intervals, and the ultraviolet lamp 3
a, a protective layer 7 is formed on the inner wall of the stainless steel cylinder 1 so as to cover 3a.
(Polytetrafluoroethylene polymer) is provided. In the figure, 8 is a peep window, 9 and 9 are support legs, and 10 is a support plate that supports the glass tube 2.

In the above embodiment, when the water to be sterilized is supplied from the water supply pipe 5 as shown by the arrow 11, the water is guided by the guide vanes 1.
2 is guided by 2 and spirally moves between the inner wall of the stainless steel tube 1 and the outer wall of the glass tube 2 to reach the inside of the closing plate 4 as indicated by arrows 13, 14 and 15; The direction is changed as shown in FIG.
The flow velocity also changes and enters the glass tube 2 and the arrows 18, 19
As shown by the arrow 20, the glass tube 2 is swirled and flows, and is taken out from the water discharge pipe 6 as indicated by an arrow 20. If the water supply pipe 5 and the water discharge pipe 6 have the same inner diameter, the water flows in both pipes will have the same velocity.

If the cross-sectional area of the water pipe 5 is set to 1/6 of the cross-sectional area of the gap between the inner wall of the stainless steel tube 1 and the outer wall of the glass pipe 2, the flow velocity in the water pipe 5 is, for example, 1 m / m. sec
Then, the flow velocity in the gap becomes 1/6 m / sec.

As described above, the water pipe 5 and the stainless pipe 1
Since the flow velocity can be changed by changing the cross-sectional areas of the inner wall of the glass tube and the outer wall of the glass tube 2, predetermined sterilization can be performed by designing the sterilization time by the ultraviolet lamp, the treatment capacity and the like. Further, the number of times of turning can be adjusted by changing the turning angle of the water flow.

[0033]

EFFECTS OF THE INVENTION According to the present invention, the treated water flows in the glass tube after passing through the gap, so that the ultraviolet rays are emitted over a distance of at least twice the length of the cylindrical body (since it swirls). There is an effect that can be irradiated.

Further, the treated water is uniformly irradiated with ultraviolet rays due to the change in the flow velocity and the swirling flow, and as a result, the flow path is lengthened and the treatment time is extended.

Next, when the diameter of the cylinder is relatively small, the tube is eccentric to facilitate the installation of the ultraviolet lamp. Further, when the diameter of the cylindrical body is increased to increase the capacity, an ultraviolet lamp is also installed outside the cylindrical body to increase the sterilizing ability.

[Brief description of drawings]

FIG. 1 is a vertical sectional front view in which a part of an embodiment of the present invention is omitted.

FIG. 2 is a plan view of the same.

FIG. 3 is likewise a vertical side view.

FIG. 4 is a vertical sectional front view in which a part of another embodiment is omitted.

FIG. 5 is a plan view of the same.

FIG. 6 is a vertical side view of the same.

[Explanation of symbols]

1 stainless steel tube 2 glass tubes 3 Sterilization lamp 4, 4a closure plate 5 water pipe 6 water pipe 7 Tetrafluoroethylene polymer 8 peep windows 9 Support legs

Claims (5)

[Claims] 1. A reciprocating flow of water is performed by changing the flow velocity and flow direction of the water flowing in the cylinder and the pipe by a sterilizing lamp arranged in parallel to the inside or outside of the pipe in the cylinder. A method of sterilizing flowing water, which is characterized by sterilization by flowing water. 2. The reciprocating flow causes the inner peripheral side of the cylindrical body to flow,
The method for sterilizing flowing water according to claim 1, characterized in that the tube is then caused to flow. 3. Inside the tubular body made of an ultraviolet opaque material,
The tubes made of an ultraviolet ray transmitting material are installed in parallel, one end of the tube is closed at the one end closed side, the one end of the tube is opened and communicated, and the water pipe is provided eccentrically to the other end side wall of the tube, and A plurality of germicidal lamps are installed in parallel between the inner wall of the tube or the inner wall of the tube and the outer wall of the tube, and the water outlet is connected to the other end of the tube to generate flowing water. Sterilizer. 4. The sterilizer for flowing water according to claim 3, wherein the tubular body is provided with a protective layer on an inner wall of a metal tube. 5. The apparatus for sterilizing flowing water according to claim 3, wherein the tube body is a quartz glass tube.