KR101544923B1 - Water purifier - Google Patents

Abstract

The present invention relates to a water purifier, and more particularly, to a water purifier that includes a filter unit for purifying raw water introduced from the outside, and a purified water tank for receiving and storing the filtered water from the filter unit, And thus the ultraviolet sterilizer is constructed using a cold cathode lamp that does not require a preheating process, so that even when the cold cathode lamp is repeatedly turned on and off, the ballast supplying power to the ultraviolet sterilizer is damaged And the durability of the ultraviolet sterilizer can be improved.

Description

Water purifier

The present invention relates to a water purifier provided with an ultraviolet sterilizer which can sterilize raw water by irradiating ultraviolet rays.

The water purifier includes a filter unit, a purified water tank for storing purified water purified by the filter unit, a freezing unit for producing ice or cold water, an ice reservoir for storing ice, a guide grille for guiding the ice from the freezing unit to the ice reservoir, And a cold water tank for storing cold water to supply ice or cold water to the user.

Here, the filter portion of the water purifier is generally provided in the order of a sedimentation filter, a line carbon filter, a membrane filter, and a post-carbon filter, and purifies the supplied raw water. However, microorganisms may be contained in the purified water finally generated through the after-carbon filter. In order to remove microorganisms contained in the purified water, an ultraviolet sterilizer may be provided on the rear side of the after-carbon filter to perform ultraviolet sterilization.

Accordingly, in the conventional water purifier, ultraviolet sterilization was performed on the purified water that passed through the post-carbon filter using a filament type ultraviolet sterilizer.

However, since the filament type ultraviolet sterilizer needs to be preheated when the filament is operated, there is a problem that the filament is broken or the ballast which supplies power to the ultraviolet sterilizer may be damaged during frequent On / Off control.

In addition, since the filament type UV sterilizer is relatively bulky, it takes up a large amount of space inside the water purifier.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a water purifier employing a cold cathode lamp type ultraviolet sterilizer having a semi-permanent lifetime in order to solve the above-described problems.

Further, it is an object of the present invention to provide a water purifier employing a cold cathode lamp type ultraviolet sterilizer having a relatively small volume.

It is still another object of the present invention to provide a water purifier employing an ultraviolet sterilizer which is simple in assembly process and easy to replace parts.

The water purifier according to an embodiment of the present invention includes a filter unit for purifying raw water introduced from the outside and a purified water tank for receiving and storing the filtered water from the filter unit, And an ultraviolet sterilizer having a cathode lamp.

The ultraviolet sterilizer may further include a protective tube provided to surround the cold cathode lamp to protect the cold cathode lamp from the water and having a material for transmitting ultraviolet rays, and a protection tube so that at least a part of the inside surface is spaced apart from the protective tube by a predetermined distance And a housing which is provided with a sterilizing flow path through which the purified water is sterilized and passed by ultraviolet rays.

Further, the housing is characterized by including a reflecting surface which is provided on an inner surface of the housing and reflects ultraviolet rays.

The predetermined distance is characterized by being within a sterilizing effective distance at which ultraviolet rays can sterilize the microorganisms contained in the purified water.

The ultraviolet sterilizer further includes a first cap coupled to one end of the housing and having an inlet connected to the sterilizing flow path and guiding the purified water from the outside to the sterilizing flow path and a second cap connected to the other end of the housing, And a second cap having an outlet for guiding the purified water to the outside.

The first cap and the second cap are provided on the inner surface of the first cap and the second cap, respectively, and include a first reflector and a second reflector that reflect ultraviolet light, respectively.

In addition, any one of the first cap and the second cap may be formed so as to penetrate the cold cathode lamp and the second cap, and may further include an insertion port through which the cold cathode lamp and the protective pipe are inserted and fixed, respectively.

The cold cathode lamp has a U-shaped bent shape, and one end and the other end thereof are respectively provided with a cathode and a cathode for supplying power to the cold cathode lamp.

The battery pack may further include a socket coupled to any one of the first cap and the second cap to connect the positive electrode and the negative electrode to an external power source.

Further, the socket includes a protrusion formed to protrude from the inner side of the socket, to be inserted into the insertion port and to be coupled to the protection tube, and a protrusion extending from the outer surface of the socket to the protrusion, Terminal.

The water purifier according to an embodiment of the present invention may have the following effects.

First, by configuring the ultraviolet sterilizer using a cold cathode lamp having a relatively small size as compared with the filament type ultraviolet sterilizer, the internal space of the water purifier can be efficiently used.

Second, the durability of the ultraviolet sterilizer can be improved by constructing the ultraviolet sterilizer using a cold cathode lamp having a semi-permanent lifetime.

Third, the protecting tube and the cold cathode lamp can be coupled to the ultraviolet sterilizer with one-touch in a state of being integrated with the socket, thereby reducing the time required for assembling the ultraviolet sterilizer, and at the same time, replacing the protective tube and cold cathode lamp .

1 is a schematic view for explaining a water purifier according to an embodiment of the present invention.
2 is an exploded perspective view of an ultraviolet sterilizer constituting a water purifier according to an embodiment of the present invention.
3 is an assembled perspective view of an ultraviolet sterilizer constituting a water purifier according to an embodiment of the present invention.
4 is a cross-sectional view of an ultraviolet sterilizer constituting a water purifier according to an embodiment of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention. Therefore, the embodiments described in this specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

In the drawings, the size of each element or a specific part constituting the element is exaggerated, omitted or schematically shown for convenience and clarity of description. Therefore, the size of each component does not entirely reflect the actual size. In the following description, it is to be understood that the detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

FIG. 1 schematically illustrates constants according to an embodiment of the present invention. Referring to FIG. Hereinafter, a water purifier 10 according to an embodiment of the present invention will be schematically described with reference to FIG.

A water purifier 10 according to an embodiment of the present invention includes a filter unit 20 for purifying raw water introduced from the outside to generate purified water and a purified water tank 30 for receiving and storing purified water from the filter unit 20 And the filter unit 20 includes an ultraviolet sterilizer 600 having a cold cathode lamp 610 for irradiating ultraviolet rays to inflow purified water to sterilize the purified water.

1, the filter unit 20 includes a settling filter 100, a pressure valve 200, a line carbon filter 300, a membrane filter 400, a post-carbon filter 500, and an ultraviolet sterilizer 600. [ And supplies purified water to the purified water tank 30 by purifying the raw water that has flowed into the outside.

The sedimentation filter 100 performs mechanical filtration by receiving the raw water and serves to filter out pollutants such as soil, dust, and sludge of about 5 μm or more, and then to filter the other filters and related parts Protect.

The pressure valve 200 reduces the pressure of the raw water passing through the sedimentation filter 100 to maintain the pressure of the raw water constant. Here, the pressure of the raw water is 1 kgf / cm ² To 5 kgf / cm < ² >. The type of the pressure valve 200 is not particularly limited, and for example, a solenoid valve may be used.

The raw carbon filter 300 receives raw water from the pressure valve 200 and removes chemical substances harmful to the human body such as chlorine, carcinogens, and synthetic detergents by using an activated carbon adsorption method. Here, the activated carbon mainly adsorbs contaminants by a physical adsorption method, and also partially chemically adsorbs.

In addition, the line carbon filter 300 adsorbs pollutants smaller than the sediment filter 100 to adsorb and remove contaminants, and also functions to improve the taste of water.

The membrane filter 400 receives the raw water from the raw carbon filter 300 and applies a pressure of at least osmotic pressure to the purified water to some extent to concentrate the pollutant. Here, the concentrated removal of the contaminants is discharged through a discharge pipe (not shown), and the purified raw water is sent to the carbon filter 500 after being described later.

The after-carbon filter 500 can remove the unpleasant taste, smell, pigment, and the like remaining in the purified raw water to increase the purity of water. Here, activated carbon is embedded in the after-carbon filter 500 as in the case of the line carbon filter 300.

The ultraviolet sterilizer 600 receives raw water from the after-carbon filter 500, performs ultraviolet sterilization, and finally generates purified water and supplies it to the purified water tank 30. Here, in the water purifier 10 according to the embodiment of the present invention, the ultraviolet sterilizer 600 is a cold cathode type having a cold cathode lamp 610. The details of the ultraviolet sterilizer 600 will be described later.

The purified water finally generated through the filter unit 20 is stored in the purified water tank 30 and used to generate cold water or freeze ice.

2 is an exploded perspective view of an ultraviolet sterilizer constituting a water purifier according to an embodiment of the present invention. FIG. 3 is an assembled perspective view of an ultraviolet sterilizer constituting a water purifier according to an embodiment of the present invention, Sectional view of an ultraviolet sterilizer constituting a water purifier according to an embodiment of the present invention. Hereinafter, the ultraviolet sterilizer 600 will be described with reference to FIGS.

2, the UV sterilizer 600 includes a cold cathode lamp 610, a protection tube 620, a housing 630, a first cap 640, A second cap 650, and a socket 660, and the like.

The cold cathode lamp 610 is filled with a mixed gas of argon (Ar), mercury (Hg) gas and the like, and collides with a mixed gas filled with electrons emitted from the metal electrode to generate ultraviolet rays. Ultraviolet rays thus generated are irradiated to the raw water passing through the sterilization flow path 632 of the housing 630 to be described later to remove the microorganisms contained in the raw water.

As shown in FIG. 2, the cold cathode lamp 610 has a U-shaped bent shape, and at one end and the other end thereof, a cathode 612 and a cathode (not shown) for supplying electric power to the cold cathode lamp 610 614 may be provided. However, the present invention is not limited thereto, and the cold cathode lamp 610 may have various shapes applicable to the ultraviolet sterilizer 600.

The protection tube 620 is provided to surround the cold cathode lamp 610, protects the cold cathode lamp 610 from the raw water, and can have a material that transmits ultraviolet rays.

Referring to FIG. 2, the protective pipe 620 has a hollow pipe shape, and one end of the protective pipe 620 is opened to insert the cold cathode lamp 610 therein. Here, the material of the protective pipe 620 is not particularly limited, but a quartz tube having a high ultraviolet transmittance may be employed.

The housing 630 is provided so as to surround the protective pipe 620 and at least a part of the inner surface of the housing 630 is spaced apart from the protective pipe 620 by a predetermined distance and provides sterilization flow path 632 through which the raw water is sterilized and passed by ultraviolet rays .

2, the housing 630 has the shape of a hollow pipe surrounding the protective pipe 620, and both ends thereof are opened so that the protective pipe 620 and the cold cathode lamp 610 can be inserted therein .

In addition, the housing 630 has a larger diameter than the protective pipe 620 so that the inner surface of the housing 630 and the protective pipe 620 are spaced apart from each other by a predetermined distance. Here, the predetermined distance may be determined within an effective disinfection distance for sterilizing the microorganisms contained in the purified water, and the flow rate of the raw water passing through the sterilization flow path 632 to be described later may also be considered.

As the inner surface of the housing 630 and the protective pipe 620 are spaced apart from each other by a predetermined distance, a sterilization passage 632 is formed between the inner surface of the housing 630 and the protective pipe 620, (See FIG. 4).

2, the sterilization channel 632 may be formed so as to surround the entire outer circumferential surface of the protective tube 620, but is not limited thereto and may be formed to surround only a part of the outer circumferential surface of the protective tube 620 Do.

In addition, the housing 630 may be provided on the inner side of the housing 630 and may include a reflecting surface 630a that reflects ultraviolet rays. More specifically, in order to increase the germicidal effect of the cold cathode lamp 610, a metal material capable of reflecting ultraviolet rays, for example, stainless steel is plated on the inner surface of the housing 630 to form a reflecting surface 630a can do.

The first cap 640 is coupled to one end of the housing 630 and includes an inlet 641, a first engaging portion 643, a second engaging portion 645, an insertion groove 647, a first reflector 649, A first O-ring 640a, and a second O-ring 640b.

The first cap 640 may have a stepped shape to be engageable with an open end of the housing 630 as shown in FIG. More specifically, the first cap 640 has a first engaging portion 643 having a diameter smaller than that of the housing 630 so as to be inserted and joined to an opened end of the housing 630, and a second engaging portion 643 having a larger diameter than the housing 630 And may have a first latching portion 645 which is fixedly hooked on one opened end of the housing 630.

Accordingly, the first engaging portion 643 is inserted into the opened end of the housing 630 and is fixed by interference fit, so that the first cap 640 and the housing 630 can be engaged with each other have. A first engaging protrusion 643a for engaging the first reflector 649 and the first engaging portion 643 to be described later is protruded from the outer surface of the first engaging portion 643, .

2 and 4, the inlet 641 is formed in the first latching portion 645 of the first cap 640 and extends to the insertion groove 647 to be described later and is supplied from the rear carbon filter 500 The raw water can be guided to the sterilization flow path 632. [ Here, the flow of the raw water inside the ultraviolet sterilizer 600 will be described in detail later.

The insertion groove 647 is formed through a portion of the first cap 640 as shown in FIG. The cold cathode lamp 610 and the protective pipe 620 may be inserted and fixed. More specifically, the insertion groove 647 is formed through the central portion of the first cap 640 and may have a larger diameter than the protective tube 620 so that the protective tube 620 can be inserted.

4, when the first cap 640 is coupled to the opened end of the housing 630, the insertion groove 647 is connected to the sterilizing flow path (not shown) of the housing 630, 632). That is, the inlet 641 of the first cap 640 and the sterilization passage 632 of the housing 630 are connected through the insertion groove 647.

The first reflection plate 649 is provided on the inner surface of the first cap 640 and reflects ultraviolet rays. More specifically, the first reflecting plate 649 is provided on one side thereof as shown in Figs. 2 and 4 and includes a first coupling hook 649a which is hooked to the first coupling protrusion 643a of the first coupling portion 643, And a plurality of first through holes 649b formed through the first reflection plate 649 at predetermined intervals to communicate the insertion groove 647 with the sterilization flow path 632. [

The first reflector 649 may have a hollow 'O' shape so that the protective tube 620 inserted into the insertion groove 647 may pass through the central portion thereof, as shown in FIG. 2, For example, stainless steel, which can reflect ultraviolet rays, such as the reflection surface 630a of the reflection surface 630. [

The first reflector 649 prevents the ultraviolet light emitted from the cold cathode lamp 610 from leaking to the outside through the insertion groove 647 and the inlet 641 of the first cap 640, The raw water that has flowed into the inlet 641 and passed through the insertion groove 647 can be guided to the sterilizing flow path 632 through the plurality of first through holes 649b.

The first O-ring 640a is provided between the inner surfaces of the first reflector 649 and the first engaging portion 643 as shown in FIG. More specifically, the first O-ring 640a seals between the first engaging portion 643 and the inner side surface of the housing 630 so that the raw water passing through the insertion groove 647 can pass through the first engaging portion 643 and the housing 630, It is possible to prevent leakage through the space between the inner surfaces of the side walls 630.

The second O-ring 640b is inserted into the insertion groove 647 of the first cap 640 to prevent water from flowing between the protection tube 620 and the insertion groove 647 have. 4, the second O-ring 640b may be inserted into and fixed to the inner surface of the insertion groove 647. The O-

The second cap 650 is coupled to the other end of the housing 630 and may include an outlet 651, a guide groove 657, a second reflector 659, a third O-ring 650a, and the like.

The second cap 650 may have a stepped shape so as to be engageable with the other open end of the housing 630, similarly to the first cap 640, as shown in FIG. More specifically, the second cap 650 includes a second engaging portion 653 having a smaller diameter than the housing 630 and inserted and coupled to the other opened end of the housing 630, and a second engaging portion 653 having a diameter larger than that of the housing 630 And may have a second latching portion 655 which is caught and fixed to the other open end of the housing 630.

Accordingly, the second engaging portion 653 is inserted into the other open end of the housing 630 and is fixed by interference fit so that the second cap 650 and the housing 630 can be engaged with each other have. A second coupling protrusion 653a for coupling the second reflection plate 659 and the second coupling portion 653 to be described later protrudes from the outer surface of the second coupling portion 653, .

The outlet 651 is formed in the second stop 655 of the second cap 650 as shown in Figures 2 and 4 and extends to the guide groove 657 to be described later and passes through the sterilization passage 632 The finally generated purified water can be guided to the purified water tank 30.

2 and 4, the guide groove 657 is formed by piercing a central portion of the inner surface of the second cap 650 to a predetermined depth, and the closed end of the protective pipe 620 is inserted and fixed The diameter of the protective tube 620 may be larger than the diameter of the protective tube 620.

The guide groove 657 communicates with the outlet 651 as shown in FIG. 4. When the second cap is coupled to the other end of the housing 630, the guide groove 657 is also communicated with the sterilization passage 632. That is, the outlet 651 of the second cap 650 and the sterilization passage 632 of the housing 630 are connected through the guide groove 657.

The second reflection plate 659 is provided on the inner surface of the second cap 650 and reflects ultraviolet rays. More specifically, the second reflection plate 659 is provided at one side thereof as shown in Figs. 2 and 4 and includes a second coupling hook 659a hooked to the second coupling projection 653a of the second coupling portion 653, And a plurality of second through holes 659b formed through the second reflection plate 659 at predetermined intervals to communicate the guide groove 657 with the sterilization flow path 632. [

2, the second reflector 659 may have a convex shape at its central portion so as to be inserted into the guide groove 657. The second reflector 659 may be formed of a material such as ultraviolet For example, stainless steel.

The ultraviolet rays irradiated from the cold cathode lamp 610 are prevented by the second reflecting plate 659 leaking to the outside through the outflow port 651 of the second cap 650 and the ultraviolet rays emitted from the cold cathode lamp 610 pass through the sterilizing flow path 632 So that the sterilized raw water can be guided to the outlet 651 through the second through hole 659b.

The third O-ring 650a is provided between the inner surface of the second reflection plate 659 and the second engagement portion 653 as shown in FIG. More specifically, the third O-ring 650a seals between the second engaging portion 653 and the inner surface of the housing 630 so that the raw water that has passed through the second through hole 659b passes through the second engaging portion 653, And between the inner surface of the housing 630 and the inner surface of the housing 630.

The socket 660 is coupled to the outer surface of the first cap 640 and is connected to the anode 612 and the cathode of the cold cathode lamp 610 exposed to the outside of the first cap 640 through the insertion groove 647. [ 614 to an external power source, and may include protrusions 662, stoppers 664, and connection terminals 666, and the like.

The protrusion 662 protrudes from the inner surface of the socket 660 as shown in FIG. 2 and is inserted and fixed to the open end of the protective pipe 620 through the insertion groove 647. In other words, the protection tube 620 is fixedly installed by coupling the open end of the protection tube 620 and the protrusion 662 of the socket 660.

The stopper 664 has a hollow 'O' shape so that it can be fitted into the protrusion 662 as shown in FIG. The stopper 664 is fitted in the protrusion 662 so as to be disposed between the inner surface of the socket 660 and the protective pipe 620 so that the protective pipe 620 fitted to the protrusion 662 can be prevented from being damaged have.

The connection terminal 666 extends from the outer surface of the socket 660 to the inner surface of the socket 660, that is, the protrusion 662 of the socket 660, as shown in Figs. 2 and 4, The anode 612 and the cathode 614 of the anode 610 are connected to an external power source.

4, the anode 612 and the cathode 614 are inserted into one side of the connection terminal 666 provided in the protrusion 662 of the socket 660, and are fixed So that it can be fixedly installed inside the protective pipe 620 while being supplied with power from the external power source.

An electric wire 670 connected to an external power source may be inserted and fixed to the other side of the connection terminal 666 provided on the outer surface of the socket 660 so that the anode 612 of the cold cathode lamp 610, The wire 614 and the wire 670 can be connected. Here, a power terminal 672 may be provided at an end of the electric wire 670 to connect the electric wire 670 to an external power source.

The protection tube 620 and the cold cathode lamp 610 are provided so that the protection tube 620 and the cold cathode lamp 610 are combined with the socket 660 integrally, 1 cap 640 into the housing 630 through the insertion groove 647 of the cap 640. [

As a result, the assembling process of the ultraviolet sterilizer 600 is simplified and the assembly time is saved. Even if the entire ultraviolet sterilizer 600 is not separated, only the socket 660 is separated from the ultraviolet sterilizer 600, 610 and the protective pipe 620 can be replaced.

Hereinafter, a process of sterilizing raw water supplied from the after-carbon filter 500 through the ultraviolet sterilizer 600 will be described.

First, raw water is introduced through the inlet 641 of the first cap 640 connected to the after-carbon filter 500. The raw water flowing into the inlet 641 passes through the insertion groove 647 communicated with the inlet 641 and then passes through the plurality of first through holes 649b of the first reflector 649 to the sterilizing flow path 632 Guidance.

The raw water guided to the sterilizing flow path 632 is sterilized by the ultraviolet rays irradiated from the cold cathode lamp 610, and thus raw water is ultimately filtered to generate purified water. The ultraviolet light irradiated by the cold cathode lamp 610 is incident on the reflecting surface 630a of the housing 630, the first reflecting plate 649 of the first cap 640, It is prevented from leaking to the outside of the ultraviolet sterilizer 600 by the air vent 659.

The purified water generated by the sterilization treatment while passing through the sterilization flow path 632 is guided to the guide groove 657 through the plurality of second through holes 659b of the second reflector 659. The purified water guided to the guide groove 657 by the guide groove 657 is guided to the outside of the UV sterilizer 600 through the outlet 651 communicated with the guide groove 657 and supplied to the purified water tank 30.

As described above, the ultraviolet sterilizer 600 having the cold cathode lamp 610 is provided in the filter unit 20, so that the water purifier 10 according to the embodiment of the present invention has the following effects have.

The internal space of the water purifier 10 can be efficiently used by constructing the ultraviolet sterilizer 600 using the cold cathode lamp 610 having a relatively small size as compared with the filament type ultraviolet sterilizer.

Secondly, the durability of the ultraviolet sterilizer 600 can be improved by constructing the ultraviolet sterilizer 600 using the cold cathode lamp 610 having a semi-permanent lifetime.

Thirdly, the protection tube 620 and the cold cathode lamp 610 can be coupled to the ultraviolet light sterilizer 600 at one-touch in a state where the protection tube 620 and the cold cathode lamp 610 are integrally combined with the socket 660, The protection tube 620 and the cold cathode lamp 610 can be easily replaced.

10: water purifier 20: filter part
30: water tank 600: ultraviolet sterilizer
610: cold cathode lamp 620: protective pipe
630: housing 640: first cap
650: Second cap 660: Socket

Claims (10)

At least one filter for purifying raw water to generate an integer, and an ultraviolet sterilizer for sterilizing the purified water; And
And a purified water tank for receiving and storing the purified water from the filter unit;
In the ultraviolet sterilizer,
A cold cathode lamp that emits ultraviolet rays;
A protective tube installed to surround the cold cathode lamp and transmitting the ultraviolet ray;
A housing installed to surround the protection tube and having a sterilizing flow path formed between the inner side surface and the protection tube, the sterilizing flow passage being sterilized by the ultraviolet light;
And a first reflector provided between the inlet and the sterilizing flow path for reflecting the ultraviolet light and having a first through hole communicating the inlet and the sterilizing flow path A first cap coupled to one end of the housing; And
And a second reflector provided between the outlet and the sterilizing flow path for reflecting the ultraviolet light and having a second through hole communicating the outlet with the sterilizing flow path And a second cap coupled to the other end of the housing. delete The method according to claim 1,
The housing includes:
And a reflecting surface that is provided on an inner side surface thereof and reflects the ultraviolet ray. The method according to claim 1,
Wherein the inner surface of the housing and the outer surface of the protection tube are spaced apart from the sterilizing effective distance at which the ultraviolet rays are contained in the purified water. delete delete The method according to claim 1,
Wherein one of the first cap and the second cap includes a first cap,
Wherein the cold cathode lamp and the protection tube are inserted and fixed to each other. 8. The method of claim 7,
The cold cathode lamp includes:
And a cathode and a cathode for supplying electric power to the cold cathode lamp are provided at one end and the other end, respectively. 9. The method of claim 8,
Further comprising a socket coupled to one of the first cap and the second cap to connect the anode and the cathode to an external power source. 10. The method of claim 9,
The socket includes:
A protrusion formed protruding from an inner side surface thereof and inserted into the insertion groove to be coupled with the protection tube; And
And a connection terminal extending from the outer surface of the socket to the protrusion and connecting the anode and the cathode of the cold cathode lamp to the external power source.

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