阅读说明：本技术 一种电解水发生装置 (Electrolyzed water generating device ) 是由 钟建华 张文英 陈振飞 于 2021-10-29 设计创作，主要内容包括：本发明公开了一种电解水发生装置,包括依次相连的进水盖、腔体以及出水盖,所述腔体内部设有若干个独立分隔的电解腔,所述腔体朝向所述进水盖的一端设有若干个正极进水孔和若干个负极进水孔,所述腔体朝向所述出水盖的一端设有若干个正极出水孔和若干个负极出水孔,所述正极出水孔处设有气泡刺破件。本发明通过在正极出水孔内设置气泡刺破件,能够将电解腔内形成的体积较大的臭氧气泡刺破,使其破碎形成小臭氧气泡,有利于臭氧溶于水体,同时一定程度上能够加快水流速度,有利于臭氧水的及时向外排出,避免电解产生的臭氧水对后续电解反应发生抑制作用,因此使得电解产生的臭氧水的浓度得到极大的提高,能够满足相应的使用要求。(The invention discloses an electrolyzed water generating device which comprises a water inlet cover, a cavity and a water outlet cover which are sequentially connected, wherein a plurality of independently separated electrolysis cavities are arranged in the cavity, one end of the cavity facing the water inlet cover is provided with a plurality of anode water inlet holes and a plurality of cathode water inlet holes, one end of the cavity facing the water outlet cover is provided with a plurality of anode water outlet holes and a plurality of cathode water outlet holes, and the anode water outlet holes are provided with bubble piercing pieces. According to the invention, the bubble puncturing piece is arranged in the water outlet hole of the anode, so that ozone bubbles with larger volume formed in the electrolytic cavity can be punctured, the ozone bubbles are crushed to form small ozone bubbles, the ozone is dissolved in water body, the water flow speed can be accelerated to a certain extent, the ozone water can be discharged outwards in time, and the inhibition effect of the ozone water generated by electrolysis on the subsequent electrolytic reaction is avoided, so that the concentration of the ozone water generated by electrolysis is greatly improved, and the corresponding use requirement can be met.)

1. The utility model provides an electrolytic water generating device, includes consecutive lid, cavity and play water cover of intaking, the inside independent divided electrolysis chamber of a plurality of that is equipped with of cavity, the cavity orientation the one end of intaking lid is equipped with anodal inlet opening of a plurality of and a plurality of negative pole inlet opening, the cavity orientation the one end of going out the water cover is equipped with anodal apopore of a plurality of and a plurality of negative pole apopore, its characterized in that: and a bubble puncturing piece is arranged at the position of the anode water outlet.

2. The electrolyzed water generating apparatus according to claim 1, characterized in that: the bubble puncture piece comprises at least one puncture needle, the tip end of the puncture needle faces the anode electrolysis cavity, and the other end of the puncture needle is fixedly connected to the water outlet cover.

3. Electrolyzed water generating apparatus according to claim 2, characterized in that: the puncture needle comprises a fixed section, a middle section and a needle point section which are sequentially arranged, the fixed section is fixedly connected with the water outlet cover, the middle section is positioned in the anode water outlet hole, the diameter of the middle section is gradually reduced from the fixed section to the direction of the needle point section, and the tip of the needle point section faces the anode electrolysis cavity.

4. The electrolyzed water generating apparatus according to claim 1, characterized in that: the electrolytic cell comprises a cavity body and is characterized in that three independent and separated electrolytic cavities are arranged inside the cavity body and comprise two anode electrolytic cavities and a cathode electrolytic cavity, the anode electrolytic cavities are respectively located on two sides of the cathode electrolytic cavity, and a positive plate, a proton exchange membrane and a negative plate are respectively arranged between the anode electrolytic cavity and the cathode electrolytic cavity.

5. The electrolyzed water generating apparatus according to claim 1, characterized in that: the positive water inlet hole is higher than the positive water outlet hole, and the negative water inlet hole is lower than the negative water outlet hole.

6. The electrolyzed water generating apparatus according to claim 1, characterized in that: the inner diameter of the negative water inlet hole is smaller than that of the positive water inlet hole.

7. The electrolyzed water generating apparatus according to claim 1, characterized in that: and the side surface of one end of the water outlet cover facing the cavity is provided with an anode water outlet area and a cathode water outlet area which are independently separated, the anode water outlet area is communicated with each anode water outlet hole, and the cathode water outlet area is connected with each cathode water outlet hole.

8. The electrolyzed water generating apparatus according to claim 1, characterized in that: and positioning pins are arranged on the side surfaces of one ends of the water inlet cover and the water outlet cover, which face the cavity respectively, and are connected with the positioning holes on the opposite surfaces of the cavity in an inserting manner.

Technical Field

The invention belongs to the technical field of ozone generating devices, and particularly relates to an electrolytic water generating device.

Background

Ozone is the most widely recognized and efficient bactericide in the world, can quickly kill bacteria in water and air after reaching a certain concentration, and more importantly, is reduced into oxygen after being sterilized, so that the ozone is an environment-friendly disinfectant. Ozone can be dissolved in water to form ozone water, so that the ozone water can kill bacteria in water, decompose harmful pollutants such as organic matters in water and decolor water to a certain extent.

Chinese patent CN201710333784.3 discloses an ozone generator nozzle, which comprises a water inlet cover, a cavity body and a water outlet cover which are connected in sequence, wherein the cavity body is internally provided with a plurality of independent separation electrolytic cavities; the other end of the cavity is provided with an anode water outlet hole for communicating the anode electrolysis cavity with the injection pipeline of the water outlet cover, and the other end of the cavity is also provided with a cathode water outlet hole for communicating the cathode electrolysis cavity with the return pipeline of the water outlet cover. Although the positive plates for electrolysis production are all intensively arranged in the positive electrode electrolysis cavity, so that more ozone gas is produced in the positive electrode electrolysis cavity by electrolysis, and the concentration of ozone water formed by dissolving ozone in water is relatively high, the volume of ozone bubbles formed by the ozone gas concentrated in the positive electrode electrolysis cavity is large, the ozone is not favorable for dissolving ozone in water and discharging ozone water outwards in time, the ozone water produced by electrolysis has an inhibiting effect on subsequent electrolysis reaction, and finally the concentration of the ozone water produced by electrolysis cannot be increased to meet corresponding use requirements, so that the method has great significance for optimizing the arrangement of an electrolysis structure to increase the concentration of the ozone water produced by electrolysis.

Disclosure of Invention

The present invention is directed to an electrolyzed water generating apparatus to solve the problems set forth in the background art.

The technical scheme adopted for solving the technical problems is as follows: the utility model provides an electrolytic water generating device, includes consecutive lid, cavity and play water cover of intaking, the inside independent divided electrolysis chamber of a plurality of that is equipped with of cavity, the cavity orientation the one end of intaking lid is equipped with anodal inlet opening of a plurality of and a plurality of negative pole inlet opening, the cavity orientation the one end of going out the water cover is equipped with anodal apopore of a plurality of and a plurality of negative pole apopore, anodal outlet opening department is equipped with the bubble and punctures the piece.

Furthermore, the bubble puncturing piece comprises at least one puncturing needle, the tip end of the puncturing needle faces the anode electrolysis cavity, and the other end of the puncturing needle is fixedly connected to the water outlet cover.

Furthermore, the puncture needle comprises a fixed section, a middle section and a needle point section which are sequentially arranged, the fixed section is fixedly connected with the water outlet cover, the middle section is positioned in the anode water outlet hole, the diameter of the middle section is gradually reduced from the fixed section to the direction of the needle point section, and the tip end of the needle point section faces the anode electrolysis cavity.

Furthermore, the cavity is internally provided with three independent separated electrolytic cavities, wherein each electrolytic cavity comprises two anode electrolytic cavities and one cathode electrolytic cavity, the two anode electrolytic cavities are respectively positioned at two sides of the cathode electrolytic cavity, and a positive plate, a proton exchange membrane and a negative plate are respectively arranged between the anode electrolytic cavity and the cathode electrolytic cavity.

Further, the positive water inlet hole is higher than the positive water outlet hole, and the negative water inlet hole is lower than the negative water outlet hole.

Further, the inner diameter of the negative water inlet hole is smaller than that of the positive water inlet hole.

Furthermore, the side surface of one end of the water outlet cover facing the cavity is provided with an anode water outlet area and a cathode water outlet area which are independently separated, the anode water outlet area is communicated with each anode water outlet hole, and the cathode water outlet area is connected with each cathode water outlet hole.

Furthermore, the side faces of one ends, facing the cavity, of the water inlet cover and the water outlet cover are respectively provided with a positioning pin which is connected with the positioning hole on the opposite surface of the cavity in an inserting manner.

Compared with the prior art, the technical scheme of the invention has the following advantages:

according to the invention, the bubble puncturing piece is arranged in the water outlet hole of the anode, so that ozone bubbles with larger volume formed in the electrolytic cavity can be punctured, the ozone bubbles are crushed to form small ozone bubbles, the ozone is dissolved in water body, the water flow speed can be accelerated to a certain extent, the ozone water can be discharged outwards in time, and the inhibition effect of the ozone water generated by electrolysis on the subsequent electrolytic reaction is avoided, so that the concentration of the ozone water generated by electrolysis is greatly improved, and the corresponding use requirement can be met.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a top view of the chamber of the present invention;

FIG. 3 is a schematic structural view of a chamber according to the present invention;

FIG. 4 is a side view of the chamber of the present invention;

FIG. 5 is a schematic view of the structure of the water outlet cover of the present invention;

FIG. 6 is a schematic view of the structure of the lancet of the present invention.

The reference numbers illustrate: 1-a water inlet cover; 2-a cavity; 3-water outlet cover; 4-positive pole water inlet; 5-negative pole water inlet; 6-anode water outlet; 7-cathode water outlet; 8-a bubble piercing member; 801-a fixed segment; 802-middle section; 803-the needle tip section; 9-positive electrode electrolytic chamber; 10-a negative electrode electrolysis chamber; 11-a positive plate; 12-a proton exchange membrane; 13-negative plate; 14-anode water outlet area; 15-negative pole water outlet area; 16-a locating pin; 17-positioning holes.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and back … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components, the movement situation, and the like in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indications are changed accordingly.

Referring to fig. 1 to 5, the invention provides an electrolyzed water generating device, which comprises a water inlet cover 1, a cavity 2 and a water outlet cover 3 which are connected in sequence, wherein a plurality of independently separated electrolysis cavities are arranged in the cavity 2, a plurality of anode water inlets 4 and a plurality of cathode water inlets 5 are arranged at one end of the cavity 2 facing the water inlet cover 1, a plurality of anode water outlets 6 and a plurality of cathode water outlets 7 are arranged at one end of the cavity 2 facing the water outlet cover 3, and a bubble puncture piece 8 is arranged at the position of the anode water outlet 6. According to the electrolytic water generating device, the bubble puncturing piece 8 is arranged in the anode water outlet hole 6, so that ozone bubbles with a larger volume formed in the electrolytic cavity can be punctured, the ozone bubbles are broken to form small ozone bubbles, ozone is dissolved in a water body, the water flow speed can be increased to a certain extent, the ozone water is discharged outwards in time, the inhibition effect of the ozone water generated by electrolysis on the subsequent electrolytic reaction is avoided, the concentration of the ozone water generated by electrolysis is greatly improved, and the corresponding use requirement can be met.

Preferably, the bubble-puncturing member 8 comprises at least one puncturing needle, the tip of the puncturing needle faces the anode electrolysis chamber 9, and the other end of the puncturing needle is fixedly connected to the water outlet cover 3. Referring to fig. 6, in this embodiment, the bubble puncturing element 8 is a puncturing needle, the puncturing needle includes a fixing section 801, a middle section 802 and a needle point section 803, which are sequentially disposed, the fixing section 801 is fixedly connected to the water outlet cover 3, the middle section 802 is located in the anode water outlet hole 6, the diameter of the middle section 802 gradually decreases from the fixing section 801 to the needle point section 803, and the tip of the needle point section 803 faces the anode electrolysis chamber 9. In the water outlet process, the puncture needle can puncture the large bubbles in the ozone water to facilitate the large bubbles to be dissolved in the water, and the diameter of the section 802 changes to enable the space of the anode water outlet hole 6 to be gradually reduced in the water outlet direction, so that the puncture needle can accelerate water flow, is beneficial to timely discharge of ozone water outwards, and prevents the ozone water generated by electrolysis from inhibiting subsequent electrolytic reaction.

In addition, in another embodiment, in order to meet different use requirements, when different types of electrolyzed water generation apparatuses are used, the size of the cathode water outlet hole 6 is generally different, so the bubble puncturing element 8 can be provided as a plurality of puncturing needles which are uniformly arranged according to the size of the cathode water outlet hole 6, and the puncturing needles can be the puncturing needles with the structure described above or can be ordinary fine needles.

Preferably, three independent and separated electrolytic cavities are arranged in the cavity 2, and each electrolytic cavity comprises two positive electrode electrolytic cavities 9 and one negative electrode electrolytic cavity 10, the two positive electrode electrolytic cavities 9 are respectively positioned at two sides of the negative electrode electrolytic cavity 10, and a positive electrode plate 11, a proton exchange membrane 12 and a negative electrode plate 13 are respectively arranged between the positive electrode electrolytic cavities 9 and the negative electrode electrolytic cavity 10. So set up, can avoid ozone gas to form the big bubble in the positive pole electrolysis intracavity that a space is great relatively, that is to say, under the unchangeable prerequisite of the same and positive pole electrolysis chamber 9 of cavity 2 volume, can avoid forming great bubble in positive pole electrolysis chamber 9, consequently be favorable to ozone to be dissolved in the water.

Preferably, the anode water inlet 4 is higher than the anode water outlet 6, and the cathode water inlet 5 is lower than the cathode water outlet 7. Set up anodal inlet opening 4 and be higher than anodal apopore 6, the water has certain difference in height in the inside transportation process forward of anodal electrolysis chamber 9, therefore the water forms turbulent phenomenon in anodal electrolysis chamber 9 easily for the speed of ozone dissolved in the water. And set up negative pole inlet opening 5 and lower than negative pole apopore 7, because the product after the electrolysis is hydrogen in negative pole electrolysis chamber 10, hydrogen density is less than the air, consequently hydrogen gathers in negative pole electrolysis chamber 10 inside top and can discharge along the negative pole apopore along with the water for ozone water that the electrolysis process produced gets into corresponding transfer passage smoothly with the water that mixes hydrogen, can improve corresponding electrolysis work efficiency, also can make ozone and water carry out the intensive mixing to dissolve simultaneously.

Preferably, the inner diameter of the negative water inlet 5 is smaller than the inner diameter of the positive water inlet 4. Because the water gets into the product after carrying out the electrolysis in negative pole electrolysis chamber 10 through negative pole inlet opening 5 and is for the hydrogen of difficult water-soluble, if set up positive pole inlet opening 4 and negative pole inlet opening 5's internal diameter unanimous, it is the same with the volume of the water in negative pole electrolysis chamber 10 to get into anodal electrolysis chamber 9 like this, the hydrogen volume in negative pole electrolysis chamber 10 increases gradually makes negative pole electrolysis chamber 10 internal pressure too big, negative pole electrolysis chamber 10 is through negative pole inlet opening 5 reverse entering into 1 pipeline of water inlet cover and to the inside pressure of exerting of anodal electrolysis chamber 9, thereby disturb the ozone dissolution work in anodal electrolysis chamber 9, make ozone concentration reduce. Therefore, the inner diameter of the negative water inlet hole 5 is set to be smaller than that of the positive water inlet hole 4, so that the water flow flowing into the negative electrode electrolysis cavity 10 in the same time is smaller than that flowing into the positive electrode electrolysis cavity 9, and the disturbance of the electrolysis product of the negative electrode electrolysis cavity 10 to the electrolysis process in the positive electrode electrolysis cavity 9 can be reduced.

Preferably, the side surface of one end of the water outlet cover 3 facing the cavity 2 is provided with an anode water outlet area 14 and a cathode water outlet area 15 which are independently separated, the anode water outlet area 14 is communicated with each anode water outlet hole 6, and the cathode water outlet area 15 is connected with each cathode water outlet hole 7. The water bodies coming out of the anode electrolysis cavities 9 are converged and mixed in the anode water outlet zone 14, so that the concentration of the ozone water can be further improved. The positive pole water outlet area 14 and the negative pole water outlet area 15 respectively convey ozone water and water mixed with hydrogen out through the conveying pipelines which are respectively connected. It is worth mentioning that the water body mixed with hydrogen can be correspondingly treated, so that a large amount of relatively pure hydrogen can be obtained, and the electrolytic water generating device with the hydrogen-oxygen separation function can be applied to other fields.

As a preferable mode of the invention, referring to FIGS. 4 and 5, the side surfaces of one end of each of the water inlet cover 1 and the water outlet cover 3 facing the cavity 2 are provided with positioning pins 16 which are inserted into positioning holes 17 on the opposite surfaces of the cavity 2. The corresponding positioning pins 16 are inserted into the positioning holes 17, so that the connection and positioning relation between the water inlet cover 1 and the water outlet cover 3 and the cavity 2 is more accurate and reliable.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.