TWI642472B - Negative hydrogen ion living water generating device - Google Patents

Abstract

A negative hydrogen ion living water generating device comprises: a casing and an inner casing, wherein the inner casing is accommodated in the casing, and the two are combined through a connecting member, and a raw water is poured into the plurality of second inlet and outlet of the casing And flowing into the first manufacturing chamber of the inner casing through the first inlet and outlet water passage of the inner casing, the raw water is mixed with a solute in the first manufacturing chamber to form a mixed water, and the mixed water flows to a second manufacturing chamber. Mixing with the solute, and then flowing the mixed water from a third inlet and outlet into a first gas chamber and flowing out of a water pipe, thereby ensuring that the raw water completely disturbs the solute in the first and second manufacturing chambers, thereby generating The target mixed water flows out of the negative hydrogen ion living water generating device.

Description

Negative hydrogen ion living water generating device

The invention relates to a filter core structure, in particular to a negative hydrogen ion living water generating device with an inner casing.

Water is an important substance that humans need to drink every day. Because environmental pollution is getting worse, people are paying more and more attention to the quality and safety of drinking water. Therefore, there are various kinds of water purifiers or pure water devices on the market, and clean water. The most important filter device in the machine is a filter element filled with various substances. The conventional filter element is a single-layer filter element, which is filled with material in the filter element. When the water flows through the whole filter element, the target water can be generated, such as purified water or energy water. .

However, due to the gravity of the earth and the influence of the water flow from the upper inflow, the filler in the filter element will have a thick bottom, which will make the water not easily penetrate into the whole filter element, resulting in the water not being able to be completely mixed with the filler. Moreover, the inlet and outlet of the filter element are generally set. At the top of the filter element, the water flowing into the filter element often flows directly from the water outlet, and is not fully mixed with the filler, so that the water flowing out is not completely purified, has no function or the concentration is not up to the predicted standard.

When it is necessary in the industry to stably obtain a solution of a specific pH value, it is necessary to inject a high-pH solvent through two lines, one line is injected with water or a low-pH solvent, and the two lines are guided to a mixing tank and mixed. Then guide it out and mix with the product, so that the required pH value can be obtained by proportionally controlling the flow rate of the double pipeline; otherwise, the product is first placed in the mixing tank, and the solvent of different concentrations flows in, and then Mixing together, the above two methods require at least two injection lines on the device, and when the pH value is mixed with the product in the same mixing barrel, the different pH values injected by the two lines may be separately carried out with the product. The reaction causes the final product to fail to meet the requirements or the quality is uncertain.

The prior art does not regulate the pH of the effluent solvent. After the pH solvent has flowed out for a period of time, the pH will gradually become neutral. For example, the initial pH will be 11 at the beginning, and may continue to decrease after a period of time. To 9 or 8, the pH of the injected solution is unstable, which will lead to the quality of the final product, which may lead to product failure.

Furthermore, water containing bubbles is now popular among the public, and the sources of bubbles include carbon dioxide or negative hydrogen ions, although the water produced by the two substances has different tastes and exerts different functions on the body after drinking. In the manufacturing process, small molecules of air bubbles are generated in the water machine. After using the water machine for a period of time, the air bubbles released from the water will be plugged in the water inlet and outlet of the filter element, causing the water to stop or become small, causing inconvenience to the user.

For this reason, the Applicant has invented a negative hydrogen ion living water generating device in view of the lack of the prior art, so that water can be sufficiently mixed with the filler of the filter element and slowly flowed out to solve the current problem.

An object of the present invention is to provide a negative hydrogen ion living water generating device for ensuring that water is sufficiently mixed with a filler in the device to further generate a target mixed water, so that the water outlet continuously flows out of the stabilized mixed water, thereby avoiding the conventional knowledge. The phenomenon of unevenness.

In order to achieve the above object, the technical means of the present invention comprises: an outer casing and an inner casing, the inner casing being accommodating in a receiving space of the outer casing and combining the two through a connecting component; wherein the outer casing The shell has an upper cover and a body, the top of the upper cover has a first inlet and outlet and a plurality of second inlet and outlet, and the bottom of the inner casing is provided with at least a third inlet and outlet and a first inlet and outlet, and the first inlet and outlet The waterway has a first manufacturing chamber and a second manufacturing chamber. The first and second manufacturing chambers are separated by a second inlet and outlet channel and a third inlet and outlet channel, wherein the third inlet and outlet channel is a ring structure and is formed. a first air chamber, the second water inlet and the water passage penetrate through the third water inlet and outlet, and further communicate with the first and second manufacturing chambers, wherein the inner casing has a plurality of filter membranes respectively disposed at the top and bottom of the openings of the water inlet and outlet channels For separating the debris in the water, the filter is disposed on the top of the inner casing and partitioning a second air chamber; a water pipe is inserted through the top opening of the inner casing in the second air chamber, and the second The manufacturing chamber and the first gas chamber.

In this arrangement, when a raw water C is poured into the second inlet and outlet, a first inlet and outlet channel from the bottom of the inner casing enters the first manufacturing chamber of the inner casing, and the raw water is in the first manufacturing chamber. After the solute is mixed, it becomes a mixed water, and the mixed water flows from the second inlet and outlet channels to the second manufacturing chamber to be mixed with the solute therein, and then the mixed water flows into the first gas chamber from the third inlet and outlet water holes. The mixed water flowing into the first gas chamber flows into the water pipe from one of the water pipes into the water pipe, and the mixed water flows out slowly from the first water inlet and outlet of the outer casing by the water pressure; by controlling the raw water entering direction , the raw water is completely mixed with the solute in the inner shell and then flows out of the device, thereby ensuring that the raw water completely disturbs the solute in the first and second manufacturing chambers, further producing the target mixed water, and secondly, Through the continuous flow of the raw water, the solute is continuously mixed, so that the first water inlet and outlet continuously continue to flow out the stable mixed water, thereby avoiding the phenomenon of unevenness of the prior art. Third, the inner casing is provided with a plurality of pores. Let the bubbles generated when the water circulates Such porosity is released, to avoid clogging of the air bubbles out of the water holes, resulting in smaller amount of water can not flow or the like occurs.

Another object of the present invention is to provide a negative hydrogen ion living water generating device which prevents bubbles generated in the device from affecting the water discharge of the device.

In order to achieve the above object, the technical means of the present invention includes: providing a plurality of air holes on the inner casing, so that air bubbles generated when water flows are released by the air holes, thereby preventing air bubbles from blocking the water inlet and outlet holes, resulting in a small amount of water. Or the situation that cannot flow out, so that the target mixed water can be provided slowly.

10‧‧‧ Shell

11‧‧‧1st inlet and outlet

12‧‧‧2nd inlet and outlet

13‧‧‧ accommodating space

14‧‧‧Upper cover

15‧‧‧Ontology

151‧‧‧ bump

16‧‧‧ neck

20‧‧‧ inner shell

21‧‧‧First Manufacturing Room

22‧‧‧2nd manufacturing room

23‧‧‧3rd inlet and outlet

24‧‧‧1st access channel

25‧‧‧2nd access channel

26‧‧‧3rd access channel

271‧‧‧1st chamber

272‧‧‧2nd gas chamber

28‧‧‧ water pipes

281‧‧‧Water inlet and outlet

282‧‧‧ stomata

29‧‧‧ filter

211‧‧‧ stomata

30‧‧‧Connecting components

31‧‧‧ access to the waterway

32‧‧‧Block

321‧‧‧Abutment

33‧‧‧Handheld Department

34‧‧‧ accommodating space

40‧‧‧Solute

C‧‧‧ raw water

M‧‧ mixed water

Figure 1 is a schematic view of the entire invention.

Figure 2 is an exploded view of the outer casing of the present invention.

Figure 3 is a schematic view of the inner casing of the present invention.

Figure 4 is a schematic view of an embodiment of the invention.

Fig. 5 is a schematic view showing the state of water flow in the first embodiment of the present invention.

Figure 6 is a schematic view showing the state of water flow in the second embodiment of the present invention.

Figure 7 is a schematic view of another aspect of the present invention.

In order to facilitate the review committee to have a better understanding and understanding of the technical means and operation process of the present invention, the following examples are combined with the drawings, and the details are as follows.

Referring to Figures 1 and 2, the present invention relates to a negative hydrogen ion living water generating device, comprising a housing 10 and an inner casing 20, wherein the housing 10 has a receiving space 13 for receiving the inner casing 20. An upper cover 14 and a body 15 are provided with a plurality of protrusions 151 at the bottom of the body 15, such that a space is left between the inner casing 20 and the bottom of the body 15 to allow water to circulate. The top of the upper cover 14 has a neck portion 16, A first water inlet and outlet port 11 is formed at a top end of the neck portion 16. A plurality of second water inlet and outlet ports 12 are formed at a side of the neck portion 16, and the first water inlet and outlet port 11 communicates with the inner casing 20 through a connecting member 30.

Referring to FIGS. 1 and 2 again, the connecting member 30 has an inlet and outlet channel 31 at the top, a blocking portion 32 at the neck portion thereof, and a hand-held portion 33 at the bottom. Since the connecting member 30 has a hollow structure, the blocking member is blocked. The portion 32 has an accommodating space 34. The top end of the inner casing 20 is placed into the accommodating space 34. The opening of the top of the inner casing 20 is aligned with the water inlet and outlet 31, and the water inlet and outlet channel 31 is plugged. The inner and outer casings 20 and 10 are joined together in the first water inlet and outlet port 11 of the outer casing 10, and a plurality of convex abutting portions 321 are formed on one surface of the blocking portion 32, and the outer casing and the outer casing 10 are used. A gap is formed, and the water supply flows into the accommodating space 13 of the outer casing 10 from the gap. The connecting member 30 can avoid the situation that the inner casing 20 is too tight when the inner casing 20 is joined to the outer casing 10, and the water cannot flow out. The connecting component 30 further It can be designed according to the size of the top of the inner and outer casings 20, 10 to achieve the various inner and outer casings 20, 10.

Referring to FIG. 3, at least one third water inlet and outlet port 23 and a first water inlet and outlet channel 24 are provided at the bottom of the inner casing 20, and a first manufacturing chamber 21 and a second one are provided on the first water inlet and outlet channel 24. In the manufacturing chamber 22, the first and second manufacturing chambers 21 and 22 are separated by a second inlet and outlet channel 25 and a third inlet and outlet channel 26, wherein the third inlet and outlet channel 26 is an annular hollow structure having a first a gas chamber 271, the second water inlet and outlet 25 is inserted through the third water inlet and outlet 26, and further connected to the first and second manufacturing chambers 21 and 22. The inner casing 20 has a plurality of filter membranes 29 disposed therein. The top and bottom of the opening of the waterway are used to isolate the debris in the water, and the plurality of compartments can be separated by the filter membrane 29 in the first and second manufacturing chambers 21 and 22 according to the user's needs (see the 7 is shown), and a filter film 29 is disposed on the top of the inner casing 20, and a second air chamber 272 is partitioned; a water pipe 28 is opened from the top opening of the inner casing 20 to the second air chamber. 272. In the second manufacturing chamber 22 and the first gas chamber 271, the water pipe 28 is provided with at least one water inlet and outlet 281 in the first gas chamber 271, and is provided in the second gas chamber 272 to the second gas chamber 272. The inner casing 20 is provided with a plurality of air holes 211. The top casing of the inner casing 20 is provided with a hole 211 extending through the casing wall. The second inlet and outlet channel 25 is provided with a transverse hole extending through the casing. 211, when the water is circulated, the bubbles generated by the air holes 211 are released to avoid air bubbles. The water inlet hole 281 is blocked, resulting in a small amount of water or no flow. Further, the water pipe 28 can add a plurality of the water inlet holes 281 according to the use requirements (refer to Fig. 7).

Referring to Fig. 4, the first and second manufacturing chambers 21 and 22 may be filled with a solute 40 which changes the water quality characteristics, and the permeated water flows into the inner portion, and the outer casings 20 and 10 are sufficiently mixed with the solute 40 to obtain a target. Water, in addition, the filter membrane 29 may be a porous stainless steel metal material or gauze, the pore size of which depends on the characteristics of the solute 40 and the particle size to prevent the solute 40 from falling out of the first and second manufacturing chambers 21 22, pollute the water source or block the water inlet and outlet.

Embodiment 1

Referring to FIG. 5, a raw water C is poured into the second inlet/outlet port 12, flows into the accommodating space 13, and flows from the bottom of the outer casing 10, from the third inlet and outlet port 23 of the inner casing 20, and The first inlet and outlet channel 24 enters the first manufacturing chamber 21 of the inner casing 20, and the filter film 29 is provided in the third inlet and outlet port 23 and the first inlet and outlet channel 24 to filter impurities in the water, and to avoid the The solute 40 flows out, and the raw water C is mixed with the solute 40 in the first manufacturing chamber 21 to become a mixed water M, and the mixed water M flows from the second inlet and outlet channel 25 to the second manufacturing chamber 22, the first The filter film 29 is disposed at both ends of the inlet and outlet water channel 25, and the mixed water M enters the second manufacturing chamber 22 and is mixed with the solute 40 therein, and then the mixed water M flows from the third inlet and outlet water hole 26. In the first gas chamber 271, the filter film 29 is provided in the same manner as the top portion and the bottom portion of the first gas chamber 271, and the mixed water M flowing into the first gas chamber 271 flows into the water inlet hole 281 from the water pipe 28. In the water pipe 28, the mixed water M flows out from the first water inlet and outlet port 11 of the outer casing 10 by the water pressure.

Embodiment 2

Referring to Fig. 6, in the present embodiment, the raw water C is poured from the first inlet/outlet port 11 and flows directly into the water pipe 28 of the inner casing 20, and flows into the first water inlet port 281. In the gas chamber 271, water affected by the water pressure flows into the second manufacturing chamber 22 from the first gas chamber 271 and is mixed with the solute 40 to form the The water M is mixed, and the mixed water M flows into the first manufacturing chamber 21 through the second water inlet and outlet 25, and is mixed with the solute 40 of the first manufacturing chamber 21, and passes through the first water inlet and outlet 24, from the third inlet and outlet. The nozzle 23 flows into the accommodating space 13 of the casing 10, and after the mixed water M fills the accommodating space 13, it flows out from the second inlet/outlet port 12 by the influence of the water pressure.

In the first embodiment, the raw water C enters from the bottom of the inner casing 20, so that the raw water C flows upward from the bottom of the solute 40, and if the raw water C is to flow out, it will fill the entire first and second manufacturing chambers 21, 22, the raw water C is sufficiently mixed with the solute 40 to further generate the mixed water M and flow out at the first inlet/outlet port 11 of the outer casing 10; in the second embodiment, the raw water C enters from the first inlet and outlet port 21 The third inlet/outlet port 23 from the bottom of the inner casing 20 flows into the outer casing 10, and then flows out from the second inlet and outlet ports 12, so that the raw water C flows from top to bottom and completely contacts the solute 40; In the first and second water flows, the raw water C is completely mixed with the solute 40 to achieve complete purification, stable supply of target water or adjustment, whether the first inlet/outlet 11 or the second inlet/outlet 12 is filled with water. The effect of the concentration liquid; in addition, the first and second water outlets 11, 12 are all located in the neck 16, but the two are not connected, so there is no water flowing out immediately, and the solute 40 is not well mixed with the solute 40 The phenomenon of mixing occurs.

The inner casing 20 of the present invention is a material capable of releasing negative hydrogen ions. Therefore, when the liquid flows, negative hydrogen ions are also released into the liquid, so that the first mixed water M flowing out contains negative hydrogen ions and negative hydrogen ions. The water generates bubbles, and the bubbles are discharged through the air holes 211 and 282 to prevent the air bubbles from entering and exiting the water hole 281, thereby prolonging the service life of the negative hydrogen ion water generating device. .

However, the above is only the preferred embodiment of the present invention, and the scope of the present invention is not limited thereto; therefore, the simple equivalent changes and modifications made in accordance with the scope of the present invention and the contents of the invention are modified. All should remain within the scope of the invention patent.

Claims (9)

A negative hydrogen ion living water generating device comprises: a casing having an upper cover and a body, the top of the upper cover having a neck, the top end of the neck is provided with a first inlet and outlet, and the side of the neck is provided with a side a plurality of second water inlets and outlets having an accommodating space therein; and an inner casing accommodating the accommodating space of the outer casing, wherein the bottom of the inner casing is provided with at least one third inlet and outlet and a first inlet and outlet The waterway has a first manufacturing chamber and a second manufacturing chamber on the first water inlet and the waterway, and the first and second manufacturing chambers are separated by a second water inlet and a third water inlet and a water inlet, wherein the third inlet and outlet The water passage is an annular hollow structure having a first air chamber therein, and the second water inlet and outlet passage penetrates through the third water inlet and outlet passage, and further communicates with the first and second manufacturing chambers, wherein the inner casing has a plurality of filter membranes. The filter membrane is disposed at the third inlet and outlet and the two ends of the inlet and outlet channels, and a filter membrane is disposed at the top of the inner casing, and a second gas chamber is partitioned, and a water pipe is opened through the top of the inner casing. Provided in the second gas chamber, the second manufacturing chamber, and the first gas chamber, The water pipe is provided with at least one water inlet hole at the first gas chamber, at least one air hole is disposed at the second gas chamber, and the inner casing is provided with a plurality of air holes, wherein the inner shell has a through hole on the top shell The air hole of the shell wall is provided with a horizontal hole penetrating through the water channel for gas to escape from the water inlet hole. The negative hydrogen ion living water generating device according to claim 1, wherein the inner and outer casings are tightly coupled and communicated through a connecting member. The negative hydrogen ion living water generating device according to claim 1, wherein the filter membrane is used for isolating water impurities, and is selected from the group consisting of stainless steel metal materials and gauze. The negative hydrogen ion living water generating device according to claim 1, wherein the first and second manufacturing chambers are filled with a solute. The negative hydrogen ion living water generating apparatus according to claim 1, wherein the first and second manufacturing chambers can form a plurality of compartments through the filter membranes. The negative hydrogen ion living water generating device according to claim 1, wherein the water pipe in the second manufacturing chamber may be provided with a plurality of inlet and outlet water holes. The negative hydrogen ion living water generating device according to claim 1, wherein the inner casing is made of a material capable of releasing negative hydrogen ions. The negative hydrogen ion living water generating device according to claim 4, wherein a raw water is poured into the second inlet and outlet, flows into the accommodating space, and the third inlet and outlet of the inner casing and the first (1) The water inlet and outlet enter the first manufacturing chamber of the inner casing, and the raw water is mixed with the solute in the first manufacturing chamber to become a mixed water, and the mixed water flows from the second inlet and outlet to the second manufacturing chamber. The mixed water enters the second manufacturing chamber and is mixed with the solute therein, and then the mixed water flows into the first gas chamber from the third water inlet and outlet, and the mixed water flowing into the first gas chamber enters and exits the water from the water pipe. The hole flows into the water pipe, and the mixed water flows out from the first water inlet and outlet of the outer casing due to the water pressure. The negative hydrogen ion living water generating device according to claim 8, wherein the raw water is poured from the first inlet and outlet, directly flows into the water pipe of the inner casing, and flows into the first gas in the inlet and outlet holes. In the room, water affected by the water pressure flows into the second manufacturing chamber from the first gas chamber to be mixed with the solute to form the mixed water, and then the mixed water flows into the first manufacturing chamber through the second inlet and outlet channel, and the first The solute of the manufacturing chamber is mixed and flows into the accommodating space of the outer casing through the third water inlet and outlet through the first water inlet and outlet, and further, the mixed water fills the accommodating space, and is affected by the water pressure from the second water inlet and outlet. Flow out.