CN210736278U - Electrolytic cell device - Google Patents

Abstract

The utility model relates to an electrolytic cell device, which comprises a first outer side plate, a first inner side plate, an electrolytic net, a semipermeable membrane, an electrolytic net, a second inner side plate and a second outer side plate, wherein a first electrolytic chamber and a second electrolytic chamber are respectively formed between the first outer side plate and the first inner side plate and between the second inner side plate and the second outer side plate by sequentially assembling the first outer side plate, the first inner side plate, the electrolytic net, the semipermeable membrane, the electrolytic net, the second inner side plate and the second outer side plate, and two electrolytic nets are respectively connected with a conductive electrode; the same liquid to be electrolyzed is synchronously input through the three-way pipe connected with the first inlet and the second inlet to improve the electrolysis efficiency, strong base and strong acid ionized water are respectively output from the first outlet and the second outlet, or pure water is input from the first inlet, the second inlet is connected to the containing groove containing the cation liquid to be electrolyzed and then connected to the second outlet through the containing groove, the electrolyzed liquid is repeatedly circulated and electrolyzed after passing through the containing groove, and strong base ionized water with better purification effect is obtained at the first outlet.

Description

Electrolytic cell device

Technical Field

The present invention relates to an electrolytic cell device, and more particularly to an electrolytic cell device capable of improving the electrolytic efficiency of electrolytic solution and outputting various kinds of acid and alkali electrolytes.

Background

In addition to being a basic survival element for human beings, water is increasingly used and demanded in various ways. The electrolyzed water is mainly electrolyzed to change the pH value and oxidation-reduction potential of the water and decompose to generate O^2-And H⁺It is commonly used in household, medical, industrial, agricultural and commercial applications.

In the conventional apparatus for generating electrolyzed water, an electrolytic chamber is mainly surrounded by a housing, the inside of the electrolytic chamber is divided into a cathode chamber and an anode chamber by a diaphragm, and a cathode electrolytic plate and an anode electrolytic plate are respectively arranged in the cathode chamber and the anode chamber, and the cathode electrolytic plate and the anode electrolytic plate are respectively connected with a cathode electrode and an anode electrode; accordingly, when raw water is introduced into the electrolytic chamber and the cathode and anode electrodes are energized to cause an electric current to flow between the electrodes, cations are dissociated into the cathode chamber to increase the pH of the water in the cathode chamber to form alkaline water, and anions are dissociated into the anode chamber to decrease the pH of the water in the anode chamber to form acidic water.

However, the pH of the alkaline water or acidic water generated by the conventional electrolytic apparatus is generally weakly alkaline or weakly acidic, and is mostly applied to drinking, food cleaning and soaking, disinfection in contact with human bodies or animals, and the like, and the application range is relatively small.

In addition, there are documents that strong acid water having a pH of less than 2.7 and strong alkaline water having a pH of 11.5 or more can be used in industry, medical field and agriculture, for example, strong alkaline water is used in industry for disinfecting and cleaning equipment, or as an industrial cutting fluid, or strong acid water is used in medical field for disinfecting and sterilizing wounds, strong acid water is used in agriculture for sterilizing pesticides, or strong alkaline water is used for diluting to improve the pH of soil.

Now, the present inventors have developed the present invention in view of the fact that the conventional electrolytic apparatus can only generate weakly alkaline and weakly acidic electrolytic water, and that strong acid water and strong alkaline water have wider application in practical use.

SUMMERY OF THE UTILITY MODEL

The main objective of the utility model is to provide an electrolytic cell device which can effectively produce strong acid water and strong alkaline water, and the linking state of the permeable inlet can promote the electrolytic efficiency, or make the electrolytic liquid after electrolysis recycle and electrolyze, so that the strong acid and strong alkaline electrolytic liquid of the output can have more extensive application.

The main purpose and effect of the present invention are achieved by the following specific technical means:

an electrolytic cell device comprises a first outer side plate, a first inner side plate, a first electrolytic net, a semipermeable membrane, a second electrolytic net, a second inner side plate and a second outer side plate which are sequentially and fixedly stacked; a first electrolytic chamber is defined between the first outer side plate and the first inner side plate, the first electrolytic chamber is respectively communicated with a second inlet and a second outlet, and after electrolytic liquid enters the first electrolytic chamber from the second inlet and is electrolyzed, the electrolytic liquid is output from the second outlet; a second electrolytic chamber is defined between the second inner side plate and the second outer side plate, the second electrolytic chamber is respectively communicated with a first inlet and a first outlet, and after the electrolytic liquid enters the second electrolytic chamber from the first inlet and is electrolyzed, the electrolytic liquid is output from the first outlet; the first electrolytic net is connected with a positive voltage, and the second electrolytic net is connected with a negative voltage; the electrolytic bath device also comprises a three-way pipe or a containing groove, the three-way pipe is provided with two output ends and an input end, and the first inlet and the second inlet are respectively connected with the two output ends of the three-way pipe; or the containing groove is filled with electrolyte to be electrolyzed, the first inlet is used for inputting pure water, the second inlet is connected to the containing groove, and the containing groove is connected to the second outlet.

The electrolyzer apparatus as described above wherein the first outer plate is provided with the first inlet, the second inlet, the first outlet and the second outlet, and a first input flow channel, a second input flow channel, a first output flow channel and a second output flow channel are defined among the first outer plate, the first inner plate, the second inner plate and the second outer plate, wherein the first inlet, the first input flow channel, the first output flow channel and the first outlet are communicated, and the second inlet, the second input flow channel, the second output flow channel and the second outlet are communicated.

The electrolytic cell device as described above, wherein the protective mesh layers are provided on both sides of the semipermeable membrane so as to be stacked correspondingly.

The electrolytic cell device as described above, wherein a concave groove for accommodating and assembling the first electrolytic mesh is formed in the center of the first inner side plate.

The electrolytic cell device as described above, wherein a protective mesh layer stacked on the first electrolytic mesh is further provided in the depressed trench.

The electrolytic cell device as described above, wherein a concave groove for accommodating and assembling the second electrolytic mesh is formed in the center of the second inner side plate.

The electrolytic cell device as described above, wherein a protective mesh layer stacked on the second electrolytic mesh is further provided in the concave tank.

The electrolyzer apparatus as described above wherein the semi-permeable membrane is provided with a waterproof gasket around the perimeter thereof, and a waterproof gasket is provided between the contact surfaces of the first outer panel, the first inner panel, the second inner panel and the second outer panel which are correspondingly laminated.

The electrolyzer apparatus as described above wherein through holes are provided around the first outer panel, the first inner panel, the second outer panel and the waterproof pad, and screw locking components are correspondingly inserted through the through holes to lock the first outer panel, the first inner panel, the second outer panel and the waterproof pad together.

The utility model has the advantages that:

the utility model discloses an electrolysis trough device sees through the electrolysis net that is netted setting, can increase the whole surface area of this electrolysis, and borrow and link up the three-way pipe synchronous input the same electrolytic liquid of treating at first entry and second entry, reach promotion electrolytic efficiency really, or make first entry input pure water, the second entry links up to the appearance groove that contains cationic electrolyte of treating again by holding the groove and linking up to the second export, make electrolytic liquid after the electrolysis circulate the electrolysis again after storing the appearance groove that contains cationic electrolyte of treating, and obtain the better strong base ion water of purification effect at first export.

Drawings

The drawings described herein are for illustration purposes only and are not intended to limit the scope of the present disclosure in any way. In addition, the shapes, the proportional sizes, and the like of the respective members in the drawings are merely schematic for helping the understanding of the present invention, and do not specifically limit the shapes, the proportional sizes, and the like of the respective members of the present invention. The skilled person in the art can, under the teaching of the present invention, choose various possible shapes and proportional dimensions to implement the invention according to the specific situation.

FIG. 1 is an exploded perspective view of an electrolytic cell apparatus of the present invention;

FIG. 2 is a partially enlarged exploded view of the electrolyzer unit of the present invention;

FIG. 3 is a schematic view showing the construction of first and second inner side plates of the electrolyzer unit of the present invention;

FIG. 4 is a schematic view of the second inner side plate and the second outer side plate of the electrolyzer unit of the utility model after being overlapped;

FIG. 5 is a rear view of a first inner side plate of the electrolyzer unit of the invention;

FIG. 6 is a cross-sectional view A-A of FIG. 5;

FIG. 7 is a cross-sectional view B-B of FIG. 6;

FIG. 8 is a cross-sectional view C-C of FIG. 6;

FIG. 9 is an exploded perspective view of a preferred embodiment of the electrolyzer apparatus of the invention; FIG. 10 is a top cross-sectional view of a preferred embodiment of the electrolyzer apparatus of the invention; FIG. 11 is an exploded perspective view of the electrolytic cell apparatus of the present invention in accordance with two preferred embodiments.

Description of reference numerals:

1 first outer side plate 11 through hole

12 first inlet 13 second inlet

14 first outlet 15 second outlet

16 first through hole 17 first long groove

18 second through hole 19 second long groove

10 three-way pipe 101 output end

102 input 2 first inner side plate

21 sunken groove 22 protection net layer

23 through hole and 24 through hole

25 lower through holes 26 third through hole

27 fourth perforation 20 connecting pipe

3 first electrolytic network 4 semi-permeable membrane

41 waterproof pad 42 through hole

43 protective netting 44 fifth perforations

45 sixth perforated 5 second electrolytic net

6 second inner side plate 61 recess groove

62 protective net layer 63 through hole

64 upper through hole, 65 lower through hole

66 seventh through hole 67 eighth through hole

7 second outer plate 71 through hole

72 third long groove 73 fourth long groove

A a first electrolytic chamber and B a second electrolytic chamber

C a first input flow path D a first output flow path

E second input flow path F second output flow path

30 screw lock assembly 40 container

Detailed Description

The details of the present invention can be more clearly understood with reference to the accompanying drawings and the description of the embodiments of the present invention. However, the specific embodiments of the present invention described herein are for the purpose of explanation only, and should not be construed as limiting the invention in any way. Given the teachings of the present invention, the skilled person can conceive of any possible variants based on the invention, which should all be considered as belonging to the scope of the invention.

For a more complete and clear disclosure of the technical content, objectives and effects achieved by the present invention, reference is made to the following detailed description, taken in conjunction with the accompanying drawings and reference numerals:

as shown in FIG. 1, the electrolytic cell apparatus of the present invention mainly comprises: a first outer side plate 1, a first inner side plate 2, a first electrolytic net 3, a semi-permeable membrane 4, a second electrolytic net 5, a second inner side plate 6 and a second outer side plate 7; wherein:

a through hole 11 is arranged around the first outer side plate 1, a first inlet 12, a second inlet 13, a first outlet 14 and a second outlet 15 are arranged, and a first through hole 16, a first long groove 17, a second through hole 18 and a second long groove 19 are respectively arranged at the positions, corresponding to the first inlet 12, the second inlet 13, the first outlet 14 and the second outlet 15, of the inner side of the first outer side plate 1;

a concave groove 21 is formed in the center of the first inner side plate 2, a protective mesh layer 22 is flatly laid in the concave groove 21, a through hole 23 corresponding to the through hole 11 of the first outer side plate 1 is arranged around the first inner side plate 2, an upper through hole 24 and a lower through hole 25 are respectively arranged on the upper and lower peripheries of the concave groove 21 (refer to fig. 2 to 4), the upper through hole 24 and the lower through hole 25 respectively correspond to the second long groove 19 and the first long groove 17 of the first outer side plate 1, and a third through hole 26 and a fourth through hole 27 are arranged on the first inner side plate 2 corresponding to the first through hole 16 and the second through hole 18 of the first outer side plate 1;

the first electrolytic net 3 is a net body and is accommodated in the concave groove 21 in the center of the first inner side plate 2;

the semipermeable membrane 4 is a biological semipermeable membrane, a waterproof pad 41 is arranged around the semipermeable membrane 4, a through hole 42 is arranged on the waterproof pad 41, the through hole 42 simultaneously corresponds to the through hole 11 of the first outer side plate 1 and the through hole 23 of the first inner side plate 2, protective net layers 43 are correspondingly arranged on two sides of the semipermeable membrane 4, and the waterproof pad 41 is further provided with a third through hole 26 corresponding to the first inner side plate 2, a fifth through hole 44 corresponding to the fourth through hole 27 and a sixth through hole 45;

the second electrolytic net 5 is a net body and is accommodated in the concave groove 61 in the center of the second inner side plate 6;

a concave groove 61 is formed in the center of the second inner side plate 6, a protective mesh layer 62 is also laid in the concave groove 61, a through hole 63 corresponding to the through hole 42 around the waterproof pad 41 is arranged around the second inner side plate 6, an upper through hole 64 and a lower through hole 65 are respectively arranged on the upper and lower peripheries of the concave groove 61, and a seventh through hole 66 and an eighth through hole 67 corresponding to the fifth through hole 44 and the sixth through hole 45 around the semipermeable membrane 4 are arranged on the second inner side plate 6 (see fig. 2 to 5);

a through hole 71 corresponding to the through hole 63 of the second inner side plate 6 is arranged around the second outer side plate 7, and a third long groove 72 and a fourth long groove 73 are arranged at the positions of the inner side of the second outer side plate 7, which correspond to the upper through hole 64 and the lower through hole 65 of the second inner side plate 6; the third long groove 72 and the fourth long groove 73 also correspond to the eighth through hole 67 and the seventh through hole 66 of the second inner side plate 6, respectively;

in assembly, referring to fig. 5 to 8, the protective mesh layer 22, the first electrolytic mesh 3 and the protective mesh layer 43 are disposed in the recessed groove 21 of the first inner plate 2, the protective mesh layer 62, the second electrolytic mesh 5 and the protective mesh layer 43 are disposed in the recessed groove 61 of the second inner plate 6, and then the first outer plate 1, the first inner plate 2, the first electrolytic mesh 3, the semipermeable membrane 4, the second electrolytic mesh 5, the second inner plate 6 and the second outer plate 7 are sequentially stacked, a waterproof pad (not shown) is further disposed between the first outer plate 1 and the first inner plate 2, and between the second inner plate 6 and the second outer plate 7, the through holes 11 of the first outer plate 1, the through holes 23 of the first inner plate 2, the through holes 42 of the semipermeable membrane 4, the through holes 63 of the second inner plate 6 and the through holes 71 of the second outer plate 7 correspond to each other, the screw lock assembly 30 penetrates through the through holes 11, the through holes 11, 23. 42, 63 and 71, and integrally locking the first outer plate 1, the first inner plate 2, the first electrolytic net 3, the semipermeable membrane 4, the second electrolytic net 5, the second inner plate 6 and the second outer plate 7; accordingly, a first electrolytic chamber a is defined between the first outer side plate 1 and the first inner side plate 2, a second electrolytic chamber B is defined between the second inner side plate 6 and the second outer side plate 7, a first inlet flow channel C is formed by the first inlet 12, the first through hole 16, the third through hole 26, the fifth through hole 44, the seventh through hole 66, the fourth long groove 73 and the lower through hole 65, and a first outlet flow channel D is formed by the upper through hole 64, the third long groove 72, the eighth through hole 67, the sixth through hole 45, the fourth through hole 27, the second through hole 18 and the first outlet 14, so that the liquid to be electrolyzed enters the second electrolytic chamber B from the first inlet flow channel C and is output from the first outlet flow channel D; the second inlet 13, the first long groove 17 and the lower through hole 25 form a second input flow passage E, the upper through hole 24, the second long groove 19 and the second outlet 15 form a second output flow passage F, so that the liquid to be electrolyzed enters the first electrolysis chamber A from the second input flow passage E, and the electrolyzed liquid is output from the second output flow passage F; in the present embodiment, the first electrolytic network 3 is connected to the positive electrode of the power supply, and the second electrolytic network 5 is connected to the negative electrode of the power supply, but the connection method of the positive electrode and the negative electrode of the electrolytic network is not limited in this way.

In this way, the liquid to be electrolyzed can be inputted from the first inlet 12 and the second inlet 13, or the first inlet 12 and the second inlet 13 can be connected to two output ends 101 (see fig. 9 and 10) of a three-way pipe 10, when the liquid to be electrolyzed is inputted from a single input end 102 of the three-way pipe 10, the same liquid to be electrolyzed can be simultaneously inputted from the first inlet 12 and the second inlet 13, so that the liquid to be electrolyzed enters the second electrolysis chamber B from the first inlet 12 through the first input flow passage C and enters the first electrolysis chamber a from the second inlet 13 through the second input flow passage E; at this time, because the first electrolytic network 3 in the first electrolytic chamber a is connected with the positive pole of the power supply, and the second electrolytic network 5 in the second electrolytic chamber B is connected with the negative pole of the power supply, the anions in the liquid to be electrolyzed will move towards the first electrolytic chamber a, and the cations in the liquid to be electrolyzed will move towards the second electrolytic chamber B, so that the liquid to be electrolyzed will generate the acidic liquid and the alkaline liquid in the first electrolytic chamber a and the second electrolytic chamber B respectively after being electrolyzed, and the alkaline liquid is output from the first output flow channel D through the first outlet 14, and the acidic liquid is output from the second output flow channel F through the second outlet 15. The liquid to be electrolyzed used in this embodiment may be a mixture of potassium chloride and water, wherein negative ions (such as chlorine) in the potassium chloride aqueous solution are electrolyzed and dissociated to the first electrolytic chamber a and output from the second outlet 15 to obtain an acidic liquid, which can be used for sterilization or floor cleaning, and can be used as an agricultural sterilization substitute if the acidity reaches a pH value below 2.7, and positive ions (such as potassium) in the potassium chloride aqueous solution are electrolyzed and dissociated to the second electrolytic chamber B and output from the first outlet 14 to obtain an alkaline liquid, and the pH value of the alkaline liquid is 7.5 to 9.2, which is suitable for drinking water.

In addition, the second outlet 15 can also be connected to a container 40 through a connecting pipe 20, the container 40 is connected to the second inlet 13 through another connecting pipe 20 (see fig. 11), in this state, the liquid to be electrolyzed is stored in the container 40, the liquid to be electrolyzed is inputted from the container 40 through another connecting pipe 20 from the second inlet 13, and enters the first electrolytic chamber a through the second input flow passage E for electrolysis, the electrolytic liquid after electrolysis is outputted from the first electrolytic chamber a through the second output flow passage F from the second outlet 15, and then returns to the container 40 through the connecting pipe 20, and is continuously and repeatedly performed, the RO reverse osmosis pure water is inputted at the first inlet 12, the RO reverse osmosis pure water enters from the first inlet 12, enters the second electrolytic chamber B through the first input flow passage C for electrolysis, and the electrolyzed pure water is outputted from the first outlet 14 through the first output flow passage D; therefore, when the liquid to be electrolyzed is the potassium carbonate aqueous solution formed by mixing potassium carbonate and water, cations (such as potassium ions) of the potassium carbonate aqueous solution entering the first electrolytic chamber A can be continuously dissociated into the second electrolytic chamber B through the semipermeable membrane 4 and are output from the first outlet 14, so that the alkaline electrolytic liquid is output from the first outlet 14, if the pH value of the output alkaline electrolytic liquid reaches strong alkaline water of more than 11.5, the alkaline electrolytic liquid can be used for equipment disinfection and cleaning decontamination, or can be used as cutting fluid for cutting metal lubrication, and alkaline water rich in a large amount of potassium ions can be used as a fertilizer for plants after being diluted.

The above embodiments are only used for convenience of illustration, the utility model discloses not limiting, the utility model discloses can see through the difference according to its pH value of the acid liquid or the alkaline liquid of anticipated output, adjust the voltage value of first electrolysis net, second electrolysis net, see through the input even and treat the chooseing of electrolysis liquid for use, make the brineelectrolysis that it obtained use in different industries, the utility model discloses an electrolysis trough device possesses industrial practicality deeply.

In the following description of the embodiments, the invention is described in detail, but the description is not to be construed as limiting the invention for any reason, and in particular, the features described in the different embodiments may be combined with each other as desired, thereby forming other embodiments, and the features are understood to be applicable to any one embodiment and not limited to the described embodiments unless explicitly described to the contrary.

Claims (9)

1. An electrolytic cell device is characterized by comprising a first outer side plate, a first inner side plate, a first electrolytic net, a semi-permeable membrane, a second electrolytic net, a second inner side plate and a second outer side plate which are sequentially and fixedly stacked; a first electrolytic chamber is defined between the first outer side plate and the first inner side plate, the first electrolytic chamber is respectively communicated with a second inlet and a second outlet, and after electrolytic liquid enters the first electrolytic chamber from the second inlet and is electrolyzed, the electrolytic liquid is output from the second outlet; a second electrolytic chamber is defined between the second inner side plate and the second outer side plate, the second electrolytic chamber is respectively communicated with a first inlet and a first outlet, and after the electrolytic liquid enters the second electrolytic chamber from the first inlet and is electrolyzed, the electrolytic liquid is output from the second outlet; the first electrolytic net is connected with a positive voltage, and the second electrolytic net is connected with a negative voltage; the electrolytic cell device also comprises a three-way pipe or a containing groove, the three-way pipe is provided with two output ends and an input end, and the first inlet and the second inlet are respectively connected with the two output ends of the three-way pipe so as to synchronously input the same electrolyte to be treated; the containing groove is filled with electrolyte to be electrolyzed, the first inlet is used for inputting pure water, the second inlet is connected to the containing groove, the containing groove is connected to the second outlet, and the state that the second inlet is communicated with the second outlet is formed.

2. The electrolyzer apparatus of claim 1 wherein the first outer side plate defines the first inlet, the second inlet, the first outlet and the second outlet, the first outer side plate, the first inner side plate, the second inner side plate and the second outer side plate defining a first inlet flow channel, a second inlet flow channel, a first outlet flow channel and a second outlet flow channel therebetween, the first inlet flow channel, the first outlet flow channel and the first outlet being in communication, the second inlet flow channel, the second outlet flow channel and the second outlet being in communication.

3. The electrolyzer apparatus of claim 1 or 2 characterized in that both sides of the semi-permeable membrane are provided with protective mesh layers stacked in correspondence therewith.

4. The electrolyzer unit of claim 3 wherein the center of the first inner side plate is formed with a recessed channel for receiving a corresponding set of the first electrolytic mesh.

5. The electrolyzer unit of claim 4 wherein a protective mesh layer is also provided in the depression overlying the first electrolytic mesh.

6. The electrolyzer unit of claim 5 wherein the center of the second inner side plate is formed with a recessed channel for receiving a corresponding set of the second electrolysis mesh.

7. The electrolyzer unit of claim 6 wherein a protective mesh layer is also provided in the recess overlying the second electrolytic mesh.

8. The electrolyzer unit of claim 7 wherein the semi-permeable membrane is surrounded by a waterproof gasket and the first outer side plate, the first inner side plate, the second inner side plate and the second outer side plate are laminated to each other with a waterproof gasket between the contacting surfaces.

9. The electrolyzer unit of claim 8 wherein the first outer panel, the first inner panel, the second outer panel and the waterproof gasket are provided with through holes around them, and screw locking members are correspondingly inserted through the through holes to lock the first outer panel, the first inner panel, the second outer panel and the waterproof gasket together.

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