TWI513481B - Gaseous environment induction activated ozone supply device - Google Patents

Description

Gaseous fluid induction activated ozone supply device

The invention relates to a gaseous fluid induction activated ozone supply device; in particular to an innovative designer who uses the negative pressure priming state of air to control the ozone to open and close state.

According to ozone, the molecular formula (O ₃ ) is an allotrope of oxygen (O ₂ ). Ozone has the effect of eliminating the floating bacteria in the air, neutralizing and decomposing toxic gases, and removing malodor in a short time. It is widely used in purifying air, drinking water, sterilization and other related applications.

At present, there are quite a variety of ozone generating device products available on the market, and the type used to combine the existing faucets to achieve the sterilizing and purifying function of the water supply is quite common and is also desired by the present invention. Especially for the technical scope of the discussion.

At present, the starting structure of the conventional ozone generating device has found that there are still some problems in the practical application experience; for a typical case, the water flow sensing opening and closing control structure of the conventional ozone generating device is usually the water supply flow path of the faucet. A reed switch is arranged in the middle. The structure must have a fixed magnet and a movable magnet inside the water supply flow path, and an inductive switch contact is arranged outside the water supply flow path, and the operation is mainly driven by the water supply pressure of the water supply. The movable magnet is displaced toward the fixed magnet to the position corresponding to the contact of the sensing switch. At this time, the sensing switch contact turns on the contact due to the magnetic force, thereby starting the ozone generating device to open, and when the water supply is turned off, the movable magnet can be used The magnetic pole of the fixed magnet repels and returns to the original position, and at the same time, the sensing switch contact is in an open state, thereby turning off the ozone generating device; however, this The conventional structure is based on the fact that the water flow induction opening and closing control structure of the ozone generating device is disposed in the water supply flow path, and the impurities and dirt in the water flow are relatively different except for the disadvantages of the water flow smoothness and the large flow rate of the water supply flow path. It may cause the movement of the movable magnet to be unsatisfactory or even jammed. The movable magnet and the fixed magnet that are placed in the water for a long time will pollute the water due to the qualitative change, which is also a problem that both the industry and the user are worried about.

Therefore, in view of the problems existing in the above-mentioned conventional ozone generating device, how to develop an innovative structure that can be more ideal and practical, and the relevant industry should further consider the goal and direction of breakthrough.

In view of this, the inventor has been engaged in the manufacturing development and design experience of related products for many years. After detailed design and careful evaluation, the inventor has finally obtained the practical invention.

The main object of the present invention is to provide a gaseous fluid-sensing activated ozone supply device, and the problem to be solved is to think about an innovative breakthrough in how to develop a new ozone supply device with more ideal practicability; The technical feature of the present invention is that the structural component of the gaseous fluid-sensing activated ozone supply device comprises a casing, which has a receiving space for the hollow casing type; an air intake portion is disposed outside the casing or One inside is for introducing external air; an ozone outlet is provided at another part of the outer casing for outputting ozone, and the ozone outlet is provided with a check valve to make the output irreversible; an output conduit, The utility model comprises a set of connecting ends and an extending end, wherein the set of connecting ends is combined with the ozone output port, The extension end is extended to connect to a predetermined target object to be used for ozone, and the predetermined target object must be capable of generating drainage so that the output conduit is subsequently subjected to a negative pressure state; an ozone generator disposed in the outer casing Ozone is generated in one place in the space, and the ozone generator includes a gas introduction portion, an ozone deriving portion, and an ozone generating portion interposed between the gas introduction portion and the ozone deriving portion, wherein the ozone deriving portion and the ozone output portion The air connection sensing member is disposed between the air intake portion and the ozone generator, and includes a guiding tube in an upright setting manner, including a lower inlet end, an upper outlet end, and an upper exit a guiding section between the end and the lower inlet end, wherein the upper outlet end is connected to the gas introduction part of the ozone generator by a communication tube, and the lower inlet end is connected to the inlet portion; an active magnetic induction The member is placed in a guiding section of the guiding tube in a movable position, and a magnetic body is disposed on one side of the movable magnetic sensing member, and the movable magnetic sensing member is in the transmission When the catheter is in a negative pressure state, it is pulsated and is in a floating state; an induction circuit board having a Hall element is disposed on one side of the pilot tube, and the Hall element is disposed on one side of the sensing circuit board, and is active When the magnetic sensing element is in a floating state, the magnetic body corresponds to the Hall element, so that the Hall element generates an inductive signal; a controller is disposed in the housing space of the housing, and the controller is The induction circuit board and the ozone generator are electrically connected, so that when the sensing signal of the Hall element is received, the ozone generating part of the ozone generator is started to operate, and when the controller does not receive the sensing signal of the Hall element, The ozone generating portion of the ozone generator is stopped to operate; thereby, the unique and innovative design enables the present invention to extract the air in the output conduit while the water flow is being exported, so that the output conduit can be used along with the prior art. Producing a negative pressure state, and controlling the ozone to open and close by the negative pressure priming state of the air, so compared with the conventional The inductive opening and closing control structure is set in the structural mode of the water supply flow path. The long-term use can keep the water flow smoothness and flow rate of the water supply flow path, and can also eliminate the movement of the magnetic induction parts due to impurities and dirt in the water, and even The loss of functionality has further brought about practical benefits such as substantial improvement in usability and ease of use.

Referring to Figures 1 through 5, there is shown a preferred embodiment of the gaseous fluid-sensing activated ozone supply device of the present invention, but the embodiments are for illustrative purposes only and are not limited by the structure in the patent application; The gaseous fluid-sensing activated ozone supply device 05 includes an outer casing 10 formed with a receiving space 11 for a hollow casing type, and an air intake portion 20 disposed at an outer portion or an inner portion of the outer casing 10. For the purpose of introducing external air (this embodiment is provided as an external example); an ozone output port 30 is provided at another portion of the outer casing 10 for outputting ozone, and the ozone output port 30 is provided with a check valve 31 ( Only shown in FIG. 1), so that its output is irreversible; an output conduit 40 includes a set of terminals 41 and an extended end 42, which is in combination with the ozone output port 30, the extension The end 42 is extended to connect to a predetermined target object 06 to be used with ozone, and the predetermined target object 06 must be capable of generating a drainage effect, so that the output conduit 40 is subsequently subjected to a negative pressure state; an ozone generator 50 is disposed on the outer casing. 10 inside the accommodation space 11, In order to generate ozone, the ozone generator 50 includes a gas introduction portion 51, an ozone deriving portion 52, and an ozone generating portion 53 interposed between the gas introduction portion 51 and the ozone deriving portion 52, wherein the ozone deriving portion 52 is coupled to The ozone output port 30 is connected to each other; An airflow sensing member 60 is disposed between the air intake portion 20 and the ozone generator 50, and includes: a pilot tube 61 in an upright configuration, including a lower inlet end 611, an upper outlet end 612, and a guiding section 613 between the upper outlet end 612 and the lower inlet end 611, wherein the upper outlet end 612 is connected to the gas introduction portion 51 of the ozone generator 50 via a communication tube 614, and the lower inlet end 611 is connected. The movable magnetic sensing member 62 is connected to the guiding portion 613 of the guiding tube 61 in a limitable lifting and moving state, and a magnetic body is disposed on one side of the movable magnetic sensing member 62. 63, and the movable magnetic induction member 62 is pulsated in a floating state when the output conduit 40 is in a negative pressure state; and an induction circuit board 65 having a Hall element 64 is disposed on the side of the pilot tube 61. The element 64 is disposed on the side of the sensing circuit board 65, and when the movable magnetic sensing element 62 is in a floating state, the magnetic body 63 is corresponding to the Hall element 64, so that the Hall element 64 generates an inductive signal; A controller 70 is disposed in the accommodating space 11 of the casing 10 (as shown in FIG. 2) The controller 70 is electrically connected to the sensing circuit board 65 and the ozone generator 50, so that when the sensing signal of the Hall element 64 is received, the ozone generating portion 53 of the ozone generator 50 is instructed to start operation, and vice versa when the controller 70 When the sensing signal of the Hall element 64 is not received, the ozone generating portion 53 of the ozone generator 50 is instructed to stop operating; thereby, the 俾 can provide an ozone supply that controls the ozone to be opened and closed by the negative pressure priming state of the air. Device structure type.

According to the above-mentioned structural composition design, the specific embodiment of the present invention can be described as follows: Please refer to FIGS. 1 and 3, wherein the outer casing 20 is provided with an air inlet portion 20 and a filter element 21 is disposed. The element 21 is preferably a sponge, and this portion is not limited.

As shown in FIG. 5, the cross-sectional shape of the guiding section 613 of the guiding tube 61 can be set to a non-circular shape such as a rectangle, a square, a long shape, or a polygon. And the cross-sectional shape of the movable magnetic sensing member 62 cooperates with the cross-sectional shape of the guiding portion 613, so that the lifting and lowering state of the movable magnetic sensing member 62 can prevent the rotation from being oriented, and the movable magnetic body is activated. The magnetic body 63 provided in the sensing member 62 can be normally oriented toward the direction in which the Hall element 64 is located; as shown in FIG. 7, the movable magnetic sensing member 62 can be provided with a through-type venting portion 66, which can be borrowed. The through hole of the movable magnetic sensing member 62 is formed; or as shown in FIG. 6, the spacer rib 80 may be formed on the circumferential side of the movable magnetic sensing member 62, and the space between the spacer ribs 80 may be used. The spacing space is opposite to the venting portion 66, and the spacer ribs 80 are in contact with the guiding portion 613 of the guiding tube 61, thereby reducing the frictional resistance when the movable magnetic sensing member 62 is moved up and down. The movable magnetic induction member 62 is more smoothly moved up and down.

In addition, the movable magnetic sensing member 62 shown in FIG. 7 is arranged in a cylindrical shape, which is also a specific embodiment of the appearance of the movable magnetic sensing member 62.

Next, the state of use of the present invention will be described as follows: Please refer to Figures 2 to 4 and Figures 8 and 9 for a preferred embodiment of the present invention, wherein the predetermined target object to be used for ozone 06 The mixer 12 may be provided with one of the water outlets A1 of the faucet A. The mixer 12 is an existing water flow and air mixing member, which is an extension end of the output conduit 40 of the ozone supply device 05 of the present invention. 42 sets of communication; thereby, when the user opens the faucet A and forms the water outlet A1 with water flow (such as the eighth icon arrow L4), the mixer 12 can generate drainage effect to output the conduit 40 The air inside is taken out by the gas introduction portion 51 of the ozone generator (as shown by the eighth icon, the arrow L2), so that the output conduit 40 is brought into a negative pressure state, thereby being accommodated in the guide section 613 of the pilot tube 61. The movable magnetic sensing member 62 is pulsating and raised, and the magnetic field generated by the magnetic body 63 (such as the eighth icon arrow L3) can generate an inductive signal with the Hall element 64 when the controller When the sensing signal of the Hall element 64 is received, the ozone generator 5 is commanded. The ozone generating portion 53 of 0 starts to operate, and The ozone generating portion 53 is caused to produce ozone, and the ozone is led out by the output conduit 40 together with the water flow (as shown by the eighth icon, the arrow L1); conversely, when the water flow is stopped, the negative pressure state is released to make the active magnetic The sensing member 62 returns to the original position, and when the controller 70 does not receive the sensing signal of the Hall element 64, the ozone generating portion 53 of the ozone generator 50 is instructed to stop operating, thereby improving the structure and sensing. The opening and closing control structure is designed to prevent the movement of the water supply flow path due to impurities and dirt in the water, and even lose the ozone function.

Moreover, the predetermined target object to be used for ozone may also be an embodiment in which a venturi (not shown in the figure) is provided at the water inlet end of the existing faucet, and the water may flow through the venturi. The resulting pressure difference creates a drainage effect, thereby also achieving the purpose of causing the output conduit to subsequently generate a negative pressure state, which is also a specific implementation.

Advantages of the invention:

The "gaseous fluid induction activated ozone supply device" disclosed in the present invention is mainly constructed by an outer structure of an outer casing, an output conduit, an ozone generator, a gas flow sensing member and a controller, so that the present invention is compared with the prior art. At the same time as the water flow is derived, the drainage can be induced to draw out the air in the output conduit, so that the output conduit is in a negative pressure state, and the negative pressure of the air is used to control the ozone to open and close. Compared with the conventional structure in which the induction opening and closing control structure is provided in the water supply flow path, the long-term use can maintain the smooth flow and flow rate of the water supply flow path, and exclude the movable magnetic induction parts from impurities and dirt in the water. The hidden worry of being impeded or even losing function further achieves practical benefits such as substantial improvement in practicality and ease of use.

The embodiments disclosed in the above embodiments are used to specifically illustrate the present invention, and The description of the present invention is not limited to the scope of the invention, and it is intended that the person skilled in the art can change and modify the spirit and principles of the invention to achieve the same purpose. Such changes and modifications shall be covered by the scope of the patent application as described later.

05‧‧‧Ozone supply device

06‧‧‧Predetermined target object

10‧‧‧ Shell

11‧‧‧ accommodating space

12‧‧‧ Mixer

20‧‧‧Air intake

21‧‧‧Filter elements

30‧‧‧Ozone outlet

31‧‧‧Check valve

40‧‧‧Output catheter

41‧‧‧ group end

42‧‧‧Extension

50‧‧‧Ozone generator

51‧‧‧Gas introduction department

52‧‧Ozone Export Department

53‧‧‧Ozone generating parts

60‧‧‧Airflow sensing components

61‧‧‧Guiding tube

611‧‧‧ lower entrance

612‧‧‧Upper exit

613‧‧‧Guiding section

614‧‧‧Connected pipe

62‧‧‧Active magnetic induction parts

63‧‧‧ magnetic body

64‧‧‧ Hall element

65‧‧‧Induction board

66‧‧‧ Ventilation Department

70‧‧‧ Controller

80‧‧‧ spaced ribs

A‧‧‧Water tap

A1‧‧‧ water outlet

Fig. 1 is a perspective view showing the combination of the ozone supply device of the present invention.

Fig. 2 is a perspective view showing the internal structure of the ozone supply device of the present invention.

Fig. 3 is a perspective enlarged view of the ozone generator and the air flow sensing member of the present invention.

Fig. 4 is a perspective view showing an embodiment of the present invention.

Fig. 5 is an exploded perspective view showing the arrangement state of the movable magnetic induction member of the present invention.

Fig. 6 is a perspective view showing another embodiment of the movable magnetic induction member of the present invention.

Figure 7 is a perspective view showing still another embodiment of the movable magnetic induction member of the present invention.

Figure 8 is a schematic view showing the state of actuation of the ozone supply device of the present invention.

Fig. 9 is a block diagram showing the connection relationship of the components of the ozone supply device of the present invention.

05‧‧‧Ozone supply device

10‧‧‧ Shell

11‧‧‧ accommodating space

40‧‧‧Output catheter

50‧‧‧Ozone generator

51‧‧‧Gas introduction department

52‧‧Ozone Export Department

60‧‧‧Airflow sensing components

65‧‧‧Induction board

70‧‧‧ Controller

Claims (6)

A gaseous fluid-sensing activated ozone supply device includes: an outer casing forming a receiving space for a hollow casing type; and an air intake portion disposed at an outer portion or an inner portion of the outer casing for introducing external air; An ozone outlet is provided at another portion of the outer casing for outputting ozone, and the ozone outlet is provided with a check valve to make the output irreversible; and an output conduit includes a set of ends and an extended end, The set of terminals is coupled to the ozone outlet for extending communication to a predetermined target object to be used with ozone, and the predetermined target object is capable of generating a drainage effect so that the output conduit generates a negative pressure a state in which an ozone generator is disposed in a housing space of the outer casing to generate ozone, and the ozone generator includes a gas introduction portion, an ozone deriving portion, and an intervening portion between the gas introduction portion and the ozone deriving portion. An ozone generating portion, wherein the ozone deriving portion is connected to the ozone output port; and an air flow sensing member is disposed between the air intake portion and the ozone generator, a pilot tube in an upright configuration comprising a lower inlet end, an upper outlet end, and a pilot section between the upper outlet end and the lower inlet end, wherein the upper outlet end is by a connecting pipe is connected to the gas introduction portion of the ozone generator, and the lower inlet end is connected to the inlet portion; and a movable magnetic sensing member is placed in the guiding portion of the guiding tube in a limitable lifting state. a magnetic body is disposed on one side of the movable magnetic induction member, and the movable magnetic induction member is pulsated in a floating state when the output conduit is in a negative pressure state; An induction circuit board having a Hall element is disposed on one side of the pilot tube, and the Hall element is disposed on one side of the induction circuit board, and when the movable magnetic induction element is in a floating state, the magnetic body is obtained Corresponding to the element, so that the Hall element generates an inductive signal; a controller is disposed in the housing space of the housing, and the controller is electrically connected to the sensing circuit board and the ozone generator, thereby receiving When the sensing signal of the Hall element is instructed, the ozone generating portion of the ozone generator is started to operate, and when the controller does not receive the sensing signal of the Hall element, the ozone generating portion of the ozone generator is stopped to operate; thereby, It is possible to provide an ozone supply device configuration type that controls the ozone to be opened and closed by the negative pressure priming state of the air. The gaseous fluid-sensing activated ozone supply device according to claim 1, wherein the guiding section of the guiding tube has a non-circular shape such as a rectangular shape, a square shape, a long shape, and a polygonal shape. The cross-sectional shape of the movable magnetic sensing member cooperates with the cross-sectional shape of the guiding portion to ensure the rotation of the movable magnetic sensing member to prevent the rotation from being oriented, and the magnetic property of the movable magnetic sensing member is set. The body can be normally oriented in the direction of the Hall element. A gaseous fluid-sensing activated ozone supply device according to claim 1, wherein the predetermined target system to be used for ozone is a mixer that is provided with one of the outlets of the existing faucet, and the mixer is used for output. The extended end of the conduit is connected in a set manner, so that when the water flow from the outlet end of the faucet is derived, a drainage effect can be generated to take out the air in the output conduit, so that the output conduit is subsequently subjected to a negative pressure state, thereby allowing the displacement to be placed in the guide tube guide. The movable magnetic sensing member in the moving section is pulsating and is in a rising state. A gaseous fluid-sensing activated ozone supply device according to claim 1 or 2 or 3, wherein the movable magnetic induction member is provided with a through-type vent. A gaseous fluid-sensing activated ozone supply device according to claim 4, wherein the venting portion is formed by a through hole penetrating the movable magnetic induction member, or formed by a peripheral side of the movable magnetic induction member. The spacer ribs are formed by the spacing spaces between the spaced apart ribs to form the venting portion, and the spaced ribs are in contact with the guiding sections of the guiding tube, thereby reducing the lifting of the movable magnetic sensing element Frictional resistance when operating. The gaseous fluid-sensing activated ozone supply device according to claim 1, wherein the outer casing is provided with an air intake portion and a filter element is disposed.