DE102012018278A1 - Ozone supplier switchable by gaseous fluid comprises housing comprising receiving chamber, air inlet, ozone outlet opening, discharge tube comprising connecting end and discharge end, ozone generator, and fluid sensor - Google Patents

Abstract

Ozone supplier switchable by gaseous fluid comprises (i) a hollow housing (10) comprising a receiving chamber, (ii) an air inlet (20), (iii) an ozone outlet opening (30), which is arranged at other point of the housing, (iv) a discharge tube (40) comprising a connecting end (41) and a discharge end, (v) an ozone generator comprising an air inlet tube, an ozone outlet tube and an ozone generating body, (vi) a fluid sensor, which is arranged between the air inlet and the ozone generator, and (vii) a controller, which is arranged in the receiving chamber of the housing. Ozone supplier switchable by a gaseous fluid comprises (i) a hollow housing (10) comprising a receiving chamber, (ii) an air inlet (20), which is arranged at a point outside or inside the housing, for introducing the outside air, (iii) an ozone outlet opening (30), which is arranged at other point of the housing and provided in a check valve for preventing backflow, (iv) a discharge tube (40) comprising a connecting end (41) and a discharge end, (v) an ozone generator comprising an air inlet tube, an ozone outlet tube and an ozone generating body between the air inlet tube and the ozone outlet tube, (vi) a fluid sensor, which is arranged between the air inlet and the ozone generator, and (vii) a controller, which is arranged in the receiving chamber of the housing and is electrically connected with the induction circuit board and the ozone generator. The connecting end is connected with the ozone outlet opening. The discharge end extends to a target object, which has suction action. The discharge tube generates negative pressure. The ozone discharge tube is connected with the ozone outlet opening. The ozone generator is arranged in the receiving chamber of the housing and generates ozone. The fluid sensor comprises (a) a vertically arranged tubular body comprising a lower inlet opening, an upper outlet opening and a guide zone between the upper outlet opening and the lower inlet opening, (b) a movable magnetic inductor element, which is movable up and down in the guide zone of the tubular body, and (c) an induction circuit board with a hall element, which is arranged on one side of the induction circuit board. The upper outlet opening is connected by a connecting tube to the air inlet tube of the ozone generator. The lower inlet opening is connected with the air inlet. A magnetic body is arranged on one side of the movable magnetic inductor element. The movable magnetic inductor element is suctioned under a reduced pressure, and increased. The magnetic body lies opposite to the hall element, when the movable magnetic inductor element is raised. The hall element generates an induction signal. The controller activates the ozone generator body of the ozone generator, when the controller receives the induction signal from the hall element. The controller deactivates the ozone generator body of the ozone generator, when the controller receives no induction signal from the hall element.

Description

Technical area

The invention relates to a switchable from a gaseous fluid ozone supplier, which can control the ozone supply by the negative air pressure.

State of the art

Ozone O ₃ is the allotrope of oxygen and can kill bacteria in the air in a short time, neutralize toxic gas and eliminate odor. Therefore, ozone is widely used for air purification, drinking water and bactericidal purpose.

The ozone supplier has different types and shapes. The ozone provider, which is combined with a faucet to kill the bacteria in the water, is known.

However, the conventional ozone supplier of this type has the following drawbacks: the control unit for controlling the ozone supply is formed by a magnetic switch in the water path of the faucet having a fixed magnet and a movable magnet. Outside the waterway, an induction switch is provided. By the water pressure at the water discharge of the movable magnet is moved to the fixed magnet, whereby the induction switch is closed by the magnetic field, so that the ozone generator is turned on. When the water discharge ceases, the movable magnet returns to the original position by the magnetic repulsive force of the stationary magnet, thereby opening the induction switch, so that the ozone generator is turned off. Since the control unit of the ozone generator is located in the waterway, the movable magnet can be blocked by foreign matter or dirt in the water, so that the ozone supply is interrupted.

For this reason, in view of the disadvantages of conventional solutions based on many years of experience in this field, the inventor has, after much study, numerous trials and continual improvements, developed the present invention.

Brief description of the drawings

1 a perspective view of the invention,

2 a perspective view of the internal structure of the invention,

3 an enlarged view of the ozone generator and the fluid sensor of the invention,

4 a perspective view of an embodiment of the invention,

5 an exploded view of the movable magnetic induction element of the invention,

6 a perspective view of another embodiment of the movable magnetic induction element of the invention,

7 a perspective view of yet another embodiment of the movable magnetic induction element of the invention,

8th a representation of the operation of the invention,

9 a block diagram of the invention.

Ways to carry out the invention

The 1 to 5 show a preferred embodiment of the invention, which serves only to illustrate the invention. The invention is not limited thereto. As shown, the inventive gaseous fluid switchable ozone supplier comprises 05
a housing 10 which is hollow and a receiving space 11 having,
an air inlet 20 which is at one point of the outside or inside of the case 10 is arranged to introduce the outside air (in the present embodiment on the outside),
an ozone exit opening 30 located at a different location of the housing 10 is arranged and in a check valve 31 is provided ( 1 ) to prevent backflow
a delivery tube 40 that is a connecting end 41 and a delivery end 42 having the connection end 41 with the ozone exit opening 30 connected, wherein the discharge end 42 to a target object 06 extends, which has a suction effect, whereby the discharge tube 40 creates a negative pressure,
an ozone generator 50 in the recording room 11 of the housing 10 is arranged, which can produce ozone and an air inlet pipe 51 , an ozone outlet pipe 52 and an ozone generating body 53 between the air inlet pipe 51 and the ozone exit tube 52 having, wherein the ozone exit tube 52 with the ozone exit opening 30 connected is,
a fluid sensor 60 that is between the air inlet 20 and the ozone generator 50 is arranged and a tubular body 61 , which is arranged vertically, a lower inlet opening 611 , an upper one outlet opening 612 and a leadership zone 613 between the upper outlet opening 612 and the lower entrance opening 611 having, wherein the upper outlet opening 612 through a connecting pipe 614 with the air inlet pipe 51 of the ozone generator 50 is connected, wherein the lower inlet opening 611 with the air inlet 20 is connected, a movable magnetic induction element 62 that moves up and down in the guide zone 613 of the tubular body 61 is arranged, wherein on one side of the movable magnetic induction element 62 a magnetic body 63 is arranged, wherein the movable magnetic induction element 62 is sucked at a negative pressure and thus lifted, and an induction circuit board 65 with a Hall element 64 located on one side of the induction circuit board 65 is arranged, wherein when the movable magnetic induction element 62 is raised, the magnetic body 63 the Hall element 64 opposite, whereby the Hall element 64 generates an induction signal, and
a controller 70 in the recording room 11 of the housing 10 is arranged ( 2 ) and with the induction circuit board 65 and the ozone generator 50 electrically connected, where if the controller 70 the induction signal from the Hall element 64 he receives the ozone generating body 53 of the ozone generator 50 enabled, and if the controller 70 no induction signal from the Hall element 64 he receives the ozone generating body 53 of the ozone generator 50 disabled.

As a result, the invention can control the ozone supply through the negative air pressure.

The possible embodiments of the invention are described below:
Like from the 1 and 3 It can be seen is in the air intake 20 of the housing 10 a filter element 21 arranged, which is preferably formed by sponge. However, the invention is not limited thereto.

How out 5 It can be seen possesses the leadership zone 613 of the tubular body 61 a rectangular, square or polygonal cross-section. The cross section of the movable magnetic induction element 62 is the same as the leadership zone 613 , whereby a rotation of the movable magnetic induction element 62 is prevented, so that the movable magnetic induction element 62 stable in the direction of the Hall element 64 can move.

How out 7 can be seen, the movable magnetic induction element 62 a continuous ventilation space 66 have. The ventilation room 66 can through a through hole of the movable magnetic induction element 62 be formed. How out 6 can be seen, the movable magnetic induction element 62 also on the outside spaced ribs 80 form, through which the ventilation space 66 is formed. The spaced ribs 80 lie on the inner wall of the guide zone 613 of the tubular body 61 , whereby the frictional resistance for the movement of the movable magnetic induction element 62 is reduced, so that the movable magnetic induction element 62 can move more smoothly.

How out 7 can be seen, the movable magnetic induction element 62 also be cylindrical.

The operation of the invention will be described below:
Like from the 2 to 4 . 8th and 9 can be seen, the target object 06 through a mixer 12 a faucet A be formed with a water outlet A1. The mixer 12 can mix the water with the air and is with the discharge end 42 of the delivery tube 40 of the ozone supplier 05 connected. When the user turns on the tap A and the water flows out of the water outlet A1 (arrow L1 in FIG 8th ), the mixer can 12 the air through the air inlet pipe 51 (Arrow L2 in 8th ), whereby in the delivery tube 40 a negative pressure is generated, so that the movable magnetic induction element 62 in the leadership zone 613 of the tubular body 61 is raised (arrow L3 in 8th ) and the magnetic body 63 the Hall element 64 opposite, which thus generates an induction signal. If the controller 70 the induction signal from the Hall element 64 receives, it activates the ozone generating body 53 of the ozone generator 50 , whereby the ozone generating body 53 that produces ozone gas. The ozone gas from the delivery pipe 40 is mixed with the water (arrow L4 in 8th ). When the water discharge stops, the negative pressure disappears, causing the moving magnetic induction element 62 sinks into the original position. Because the controller 70 no induction signal from the Hall element 64 receives, it deactivates the ozone generating body 53 of the ozone generator 50 , Therefore, an interruption of the ozone supply by foreign matter or dirt in the water can be avoided.

The target object 06 may also be formed by a Venturi tube (not shown) in the water inlet of the faucet. The pressure difference as the water flows through the Venturi tube also controls the ozone supply

Advantages of the invention:

The gaseous fluid switchable ozone supplier according to the present invention comprises a housing, a discharge pipe, an ozone generator and a fluid sensor, and can generate a negative pressure by the suction force at the water outlet in the discharge pipe as compared with the prior art by which the ozone supply can be controlled that an interruption of the ozone supply by foreign bodies or dirt in the water can be avoided.

The foregoing description represents only the preferred embodiments of the invention and is not intended to serve as a definition of the limits and scope of the invention. All equivalent changes and modifications are within the scope of this invention.

Claims (6)

A gaseous fluid switchable ozone supplier, comprising a housing ( 10 ), which is hollow and a receiving space ( 11 ), an air inlet ( 20 ) located at a location on the outside or inside of the housing ( 10 ) is arranged to introduce the outside air, an ozone outlet ( 30 ) located at a different location of the housing ( 10 ) is arranged and in which a check valve ( 31 ) to prevent backflow, a delivery tube ( 40 ), which is a connection end ( 41 ) and a dispensing end ( 42 ), wherein the connection end ( 41 ) with the ozone exit opening ( 30 ), the discharge end ( 42 ) to a target object ( 06 ), which has a suction effect, whereby the discharge tube ( 40 ) generates a negative pressure, an ozone generator ( 50 ), in the recording room ( 11 ) of the housing ( 10 ) is arranged, which can produce ozone and an air inlet pipe ( 51 ), an ozone exit tube ( 52 ) and an ozone generating body ( 53 ) between the air inlet tube ( 51 and the ozone exit tube ( 52 ), wherein the ozone exit tube ( 52 ) with the ozone exit opening ( 30 ), a fluid sensor ( 60 ) between the air inlet ( 20 ) and the ozone generator ( 50 ) and comprising: a tubular body ( 61 ), which is arranged vertically, a lower inlet opening ( 611 ), an upper outlet opening ( 612 ) and a leadership zone ( 613 ) between the upper outlet opening ( 612 ) and the lower entrance opening ( 611 ), wherein the upper outlet opening ( 612 ) through a connecting tube ( 614 ) with the air inlet tube ( 51 ) of the ozone generator ( 50 ), wherein the lower entrance opening ( 611 ) with the air inlet ( 20 ), a movable magnetic induction element ( 62 ), which can be moved up and down in the guide zone ( 613 ) of the tubular body ( 61 ) is arranged, wherein on one side of the movable magnetic induction element ( 62 ) a magnetic body ( 63 ), wherein the movable magnetic induction element ( 62 ) is sucked at a negative pressure and thus lifted, and an induction circuit board ( 65 ) with a Hall element ( 64 ) located on one side of the induction circuit board ( 65 ), wherein when the movable magnetic induction element ( 62 ), the magnetic body ( 63 ) the Hall element ( 64 ), whereby the Hall element ( 64 ) generates an induction signal, and a controller ( 70 ), in the recording room ( 11 ) of the housing ( 10 ) and with the induction circuit board ( 65 ) and the ozone generator ( 50 ), wherein when the controller ( 70 ) the induction signal from the Hall element ( 64 ), it receives the ozone generating body ( 53 ) of the ozone generator ( 50 ), and if the controller ( 70 ) no induction signal from the Hall element ( 64 ), it receives the ozone generating body ( 53 ) of the ozone generator ( 50 ) disabled. A gaseous fluid switchable ozone supplier according to claim 1, characterized in that the guiding zone ( 613 ) of the tubular body ( 61 ) has a rectangular, square or polygonal cross section, wherein the cross section of the movable magnetic induction element ( 62 ) is the same as that of the leadership zone ( 613 ), whereby a rotation of the movable magnetic induction element ( 62 ) is prevented, so that the movable magnetic induction element ( 62 ) stable in the direction of the Hall element ( 64 ) can move. A gaseous fluid switchable ozone supplier according to claim 1, characterized in that the target object ( 06 ) through a mixer ( 12 ) of a faucet (A) with a water outlet (A1) is formed, wherein the mixer ( 12 ) with the delivery end ( 42 ) of the delivery tube ( 40 ) of the ozone supplier ( 05 ), whereby when the water flows out of the water outlet (A1), the mixer ( 12 ) the air in the delivery tube ( 40 ), whereby in the delivery tube ( 40 ) a negative pressure is generated so that the movable magnetic induction element ( 62 ) in the guiding zone ( 613 ) of the guide tube ( 61 ) is raised. A gaseous fluid switchable ozone supplier according to claim 1, 2 or 3, characterized in that the movable magnetic induction element ( 62 ) a continuous ventilation space ( 66 ) owns. A gaseous fluid switchable ozone supplier according to claim 4, characterized in that the ventilation space ( 66 ) through a through hole of the movable magnetic induction element (FIG. 62 ) or the movable magnetic induction element ( 62 ) at the Outside spaced ribs ( 80 ), through which the ventilation space ( 66 ) is formed, wherein the spaced ribs ( 80 ) on the inner wall of the guide zone ( 613 ) of the guide tube ( 61 ), whereby the frictional resistance for the movement of the movable magnetic induction element ( 62 ) is reduced. A gaseous fluid switchable ozone supplier according to claim 1, characterized in that in the air inlet ( 20 ) of the housing ( 10 ) a filter element ( 21 ) is arranged.

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