CN211620630U - Hypochlorous acid generation system - Google Patents
Hypochlorous acid generation system Download PDFInfo
- Publication number
- CN211620630U CN211620630U CN201921889912.3U CN201921889912U CN211620630U CN 211620630 U CN211620630 U CN 211620630U CN 201921889912 U CN201921889912 U CN 201921889912U CN 211620630 U CN211620630 U CN 211620630U
- Authority
- CN
- China
- Prior art keywords
- opening
- closing part
- closing
- bellows
- annular boss
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Active
Links
Images
Landscapes
- Electrolytic Production Of Non-Metals, Compounds, Apparatuses Therefor (AREA)
Abstract
The utility model discloses a hypochlorous acid generating system, which comprises an electrolyte storage tank and an electrolytic tank; the electrolyte storage tank is connected with a quantitative supply device through a pipeline, and the quantitative supply device is connected with the electrolytic cell through a pipeline; wherein, the quantitative supply device comprises a shell, a first opening and closing part, a second opening and closing part, a bellows and a driving device. The utility model discloses a hypochlorous acid generation system, through the ration device, the electrolyte that will supply with the electrolysis trough passes through bellows device ration supply, can correctly generate the effect of the PH and the concentration of required hypochlorous acid.
Description
Technical Field
The present invention relates to a hypochlorous acid generation system capable of quantitatively supplying hypochlorous acid, and more particularly, to a hypochlorous acid generation system capable of quantitatively supplying an electrolyte supplied to an electrolytic bath through a bellows device to accurately generate a desired PH and concentration of hypochlorous acid.
Background
At present, in order to sterilize tap water, various drinking water, beverages, foods, etc., chlorine gas (Cl) is generated in addition to the electrolysis of salts2) In addition, chlorine disinfection is performed in the form of hypochlorite or calcium hypochlorite. In addition, the hypochlorous acid has good sterilization effectHowever, there is no device that is actually mass-produced, manufactured and used, and that can be effectively used.
In addition, in order to accurately adjust the pH and concentration, it is necessary to accurately adjust the amount of electrolyte supplied to the side of the electrolytic cell.
SUMMERY OF THE UTILITY MODEL
The utility model aims to solve the problems of the prior art, and provides a hypochlorous acid generating system which can accurately generate required pH and concentration of hypochlorous acid by quantitatively supplying electrolyte supplied to an electrolytic cell through a bellows device.
The utility model provides a technical problem adopt following technical scheme: a hypochlorous acid generation system, comprising an electrolyte storage tank and an electrolytic tank;
the electrolyte storage tank is connected with a quantitative supply device through a pipeline, and the quantitative supply device is connected with the electrolytic cell through a pipeline;
wherein the quantitative supply device comprises a shell, a first opening and closing part, a second opening and closing part, a bellows and a driving device;
an inflow port and an outflow port are formed at two ends of the shell respectively;
the first opening and closing part and the second opening and closing part have the same structure and are arranged in the shell;
the first opening and closing part comprises an opening and closing part body, the opening and closing part body is extended towards one side to form a support rod, a fixed body is formed at the end part of the support rod, a through hole is formed in the axial direction of the fixed body, an elastic body is arranged in the through hole, a protrusion is formed at one end of the elastic body, the other end of the elastic body is fixed on a cover, the cover is hermetically combined with the opening and closing part body, and the cover is used for shielding the through hole penetrating through the opening and closing part body;
between the first opening and closing part and the second opening and closing part, the bellows is communicated and combined with the inside of the shell through a first fixing block, and the other end of the bellows combined with the shell is connected with the cam through a second fixing block;
the cam shaft of the cam is provided with an eccentric periphery, and when the driving device drives the cam shaft to rotate, the eccentric periphery of the cam pressurizes the upper part of the corrugated pipe to stretch the corrugated pipe.
Optionally, a first annular boss and a second annular boss are formed inside the housing, and the first opening and closing member is in contact with the first annular boss and is limited in axial position by the first annular boss; the second opening and closing member is in contact with the second annular boss, and the axial position thereof is defined by the second annular boss.
Optionally, the first annular boss and the second annular boss are both located between the first opening and closing part and the second opening and closing part.
The utility model discloses following beneficial effect has: the utility model discloses a hypochlorous acid generation system, through the ration device, the electrolyte that will supply with the electrolysis trough passes through bellows device ration supply, can correctly generate the effect of the PH and the concentration of required hypochlorous acid.
Drawings
FIG. 1 is a schematic structural view of a hypochlorous acid generation system according to the present invention;
FIG. 2 is a schematic structural view of the constant-volume supply device of the present invention;
fig. 3 and 4 are schematic views illustrating the operation state of the quantitative supply device of the present invention;
the notation in the figures means: 320-a first opening and closing member; 321-an opening and closing part body of the first opening and closing member; 322-through hole of first opening and closing part; 323-support bar of the first opening and closing member; 324-a fixed body of the first opening and closing member; 325 — a cover of the first opening and closing part; 326-elastic body of first opening and closing member; 327-projection of first opening and closing member; 330-second opening and closing part; 331-an opening and closing part body of a second opening and closing member; 333-support lever of second opening and closing part; 334-the fixed body of the second opening and closing part; 335 — a cover of the second opening and closing part; 336-elastic body of second opening and closing member; 337-projection of the second opening and closing part.
Detailed Description
The technical solution of the present invention will be further explained with reference to the following embodiments and accompanying drawings.
Example 1
The present embodiment provides a hypochlorous acid generation system, which includes an electrolyte storage tank 200 and an electrolytic tank 100.
The electrolyte storage tank 200 is connected to the electrolytic cell 100 by the quantitative supply means 300, whereby the electrolyte supplied from the electrolyte storage tank 200 to the electrolytic cell 100 is quantitatively supplied by the quantitative supply means 300.
The electrolytic solution supplied from the electrolytic solution storage tank 200 is electrolyzed by the electrolytic bath 100, and the electrolyzed effluent water flows into the dilution tank 500 disposed in the upper part of the electrolytic bath 100. The PH and concentration of the effluent discharged from dilution can be adjusted by mixing and reacting the water flowing into the dilution tank 500 with the effluent.
That is, the quantitative supply means 300 is located between the electrolyte storage tank 200 and the electrolytic bath 100, and can quantitatively supply the electrolyte supplied from the electrolyte storage tank 200 to the electrolytic bath 100. And preferably receives the electrolyte from the electrolyte storage tank 200 and the electrolyte supplied to the electrolytic bath 100 through the pipe 400 so that the outflow water can be accurately obtained at a desired PH and concentration.
The constant-volume supply device 300 includes a housing 310, a first opening/closing member 320, a second opening/closing member 330, a bellows 340, and a driving device.
The casing 310 has a tubular shape, and both ends thereof are provided with an inflow port 312 and an outflow port 314 connected to the duct 400.
The first opening/closing member 320 and the second opening/closing member 330 have the same structure and are disposed inside the housing, in this embodiment, a first annular boss 344 and a second annular boss 345 are formed inside the housing, and the first opening/closing member 320 is in contact with the first annular boss and the axial position thereof is defined by the first annular boss; the second opening and closing member 330 is in contact with the second annular boss, and the axial position thereof is defined by the second annular boss; more preferably, the first and second annular bosses are located between the first and second opening and closing parts 320 and 330.
In this embodiment, the first opening and closing member includes an opening and closing body 321, the opening and closing body 321 is engaged with the first annular boss and extended in one direction to form a support bar 323, a fixing body 324 is formed at an end of the support bar 323, a through hole is formed in the fixing body 324 in an axial direction, an elastic body 326 is provided in the through hole, a protrusion 327 is formed at one end of the elastic body such that an axial position of the elastic body 326 is fixed to the fixing body 324, and the other end of the elastic body is fixed to a cover for covering the through hole 322 penetrating through the opening and closing body 321 and hermetically coupling the cover to the opening and closing body 321, that is, the cover 325 can be tightly coupled to the opening and closing body 321 in a state of being pulled by a stretching force of the elastic body 326.
Preferably, the cover 325 is sprung by the elastic body 326 to the electrolyte inflow direction. This is generated between the first opening and closing part and the second opening and closing part according to the pressure generated by the bellows 340, whereby the pressure is varied and the opening and closing of the cover of the first opening and closing part and the cover of the second opening and closing part are different. For example, when the cover of the first opening and closing part 320 is opened, the cover of the second opening and closing part 330 is closed, and when the cover of the first opening and closing part 320 is closed, the cover of the second opening and closing part 330 is opened. In this manner, the electrolytic solution is quantitatively supplied to the electrolytic cell 100.
The bellows 340 is a pipe having a zigzag outer peripheral surface, the cam shaft 352 of the cam 350 has an eccentric outer periphery and is driven by a motor, that is, eccentrically rotated by a driving force of the motor, and the eccentric outer peripheral surface of the cam 350 presses the upper portion of the bellows 340 to expand and contract the bellows.
The first opening/closing member 320 is inserted into the inlet 312 of the housing 310, and the second opening/closing member 330 is inserted into the outlet 314. Between the first opening/closing member 320 and the second opening/closing member 330, a bellows 340 is coupled to the inside of the case 310 by a first fixing block 342. At the other end of the bellows 340 coupled to the housing 310, a second fixing block 343 is coupled to the cam 350.
On the other hand, the duct 400 is connected to the inlet 312 and the outlet 314 of the housing 310, and the first opening/closing member and the second opening/closing member are closely attached to the inside of the housing by the duct 400, thereby preventing the flow inside the housing. Preferably, the first opening/closing member 320 and the second opening/closing member 330 are closely inserted and coupled to each other in the direction in which the opening/closing portion main body and the electrolyte flow. This makes it possible to make the inflow amount of the electrolyte constant by differently setting the opening directions of the first opening/closing member 320 and the second opening/closing member 330 according to the direction of action of the pressure generated by the bellows 340. That is, when the first opening and closing member 320 is opened, the second opening and closing member 330 is closed, and when the first opening and closing member 320 is closed, the second opening and closing member 330 is opened. By operating in this manner, the inflow port 312 and the discharge port 314 can be opened and closed.
In a state where the duct 400 and the housing 310 are coupled, the driving motor rotates the cam 350. When the cam 350 is eccentrically rotated such that the top dead center of the cam is positioned in the upper direction, the bellows 340 is expanded, and a certain pressure is generated inside the housing by the expansion force of the bellows 340. The cover 325 of the first opening/closing member 320 is isolated from the opening/closing portion main body 321 by the pressure generated thereby, and the closed through hole 322 is opened, so that the electrolyte flows into the inlet 312. The electrolyte is introduced in a certain amount and may be stored in the bellows 340. That is, when the bellows 340 expands, the housing internal pressure acts on the bellows 340 to pull the first opening/closing member 320 and the second opening/closing member 330 toward the bellows side. At this time, the covers of the first opening/closing member 320 and the second opening/closing member 330 are in a state of being sprung by the elastic body in the electrolyte inflow direction. Therefore, the lid of the first opening/closing member 320 is kept open and the lid of the second opening/closing member 330 is kept in close contact with the opening/closing portion main body by the expansion force of the bellows 340.
In this state, when the cam 350 rotates and the top dead center rotates in the downward direction, the compression force of the bellows 340 connected to the cam acts in the housing inner direction. The lid 325 of the first opening/closing member 320 is in close contact with the opening/closing portion main body 321 by the pressure of the operation at this time, whereas the lid 335 of the second opening/closing member 330 acts on the discharge port 314 by the compressive force of the bellows, and opens the lid from the opening/closing portion main body 331 to move the housing and the electrolyte flowing into the bellows to the duct through the discharge port 314. At this time, the cover 335 is in close contact with the opening/closing unit body 331 in a state of being respectively pushed to the fixed body by the elastic body 336, and is prevented from being opened and closed by a slight pressure change in the case.
That is, the first opening/closing member 320 and the second opening/closing member 330 are controlled by the expansion and contraction of the bellows 340, and the electrolyte flowing into the case is discharged through the bellows 340 in a state where a certain amount is stored, so that the electrolyte can be quantitatively supplied to the side of the electrolytic tank.
The sequence of the above embodiments is only for convenience of description and does not represent the advantages and disadvantages of the embodiments.
Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects.
Claims (3)
1. A hypochlorous acid generation system is characterized by comprising an electrolyte storage tank and an electrolytic tank;
the electrolyte storage tank is connected with a quantitative supply device through a pipeline, and the quantitative supply device is connected with the electrolytic cell through a pipeline;
wherein the quantitative supply device comprises a shell, a first opening and closing part, a second opening and closing part, a bellows and a driving device;
an inflow port and an outflow port are formed at two ends of the shell respectively;
the first opening and closing part and the second opening and closing part have the same structure and are arranged in the shell;
the first opening and closing part comprises an opening and closing part body, the opening and closing part body is extended towards one side to form a support rod, a fixed body is formed at the end part of the support rod, a through hole is formed in the axial direction of the fixed body, an elastic body is arranged in the through hole, a protrusion is formed at one end of the elastic body, the other end of the elastic body is fixed on a cover, the cover is hermetically combined with the opening and closing part body, and the cover is used for shielding the through hole penetrating through the opening and closing part body;
between the first opening and closing part and the second opening and closing part, the bellows is communicated and combined with the inside of the shell through a first fixing block, and the other end of the bellows combined with the shell is connected with the cam through a second fixing block;
the cam shaft of the cam is provided with an eccentric periphery, and when the driving device drives the cam shaft to rotate, the eccentric periphery of the cam pressurizes the upper part of the corrugated pipe to stretch the corrugated pipe.
2. The hypochlorous acid generating system of claim 1, wherein a first annular boss and a second annular boss are formed inside the housing, the first opening and closing member being in contact with the first annular boss and having its axial position defined by the first annular boss; the second opening and closing member is in contact with the second annular boss, and the axial position thereof is defined by the second annular boss.
3. The hypochlorous acid generating system of claim 2, wherein the first and second annular bosses are each located between the first and second shutter members.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201921889912.3U CN211620630U (en) | 2019-11-05 | 2019-11-05 | Hypochlorous acid generation system |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201921889912.3U CN211620630U (en) | 2019-11-05 | 2019-11-05 | Hypochlorous acid generation system |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN211620630U true CN211620630U (en) | 2020-10-02 |
Family
ID=72624787
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN201921889912.3U Active CN211620630U (en) | 2019-11-05 | 2019-11-05 | Hypochlorous acid generation system |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN211620630U (en) |
-
2019
- 2019-11-05 CN CN201921889912.3U patent/CN211620630U/en active Active
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| US9656896B2 (en) | Method for sterilizing water supply apparatus | |
| WO2007129727A1 (en) | Electrolyzed water generator and electrode set with membrane used in the electrolyzed water generator | |
| JP2009072659A (en) | Electrolyzed water producing method and apparatus | |
| JP5156793B2 (en) | Electrolyzed water production equipment | |
| CN211620630U (en) | Hypochlorous acid generation system | |
| US10167208B2 (en) | Sterilization system | |
| KR20190128924A (en) | A washing method using the electrolyted water of nano bubble and apparatus thereof | |
| JPH10140384A (en) | Device for simultaneously generating strongly alkaline water and hypochlorous acid sterilizing water by electrolysis | |
| JP2007007632A (en) | Electrolytic water producing apparatus | |
| JPH10263542A (en) | Undersink type electrolytic water tidying device forming selectively alkaline ionized water and sterilizing water | |
| KR102349309B1 (en) | Apparatus for production of chlorine dioxide solution | |
| JP2008249053A (en) | Liquid pressure feeding device | |
| CN109527992B (en) | Drinking water supply device with hidden water taking part | |
| KR200442014Y1 (en) | Endoscope Disinfection Equipment | |
| KR100900187B1 (en) | Hypochlorous Acid Generating System | |
| JP2009002613A (en) | Hot water storage type water heater | |
| CN109663554B (en) | Chlorine dioxide activation generating device and air sterilizing device | |
| JP2013085979A (en) | Apparatus for manufacturing aqueous hypochlorous acid | |
| JP4237776B2 (en) | Pitcher and electrolyzed water generator using the same | |
| TWM612257U (en) | Miniature cabinet type electrolysis equipment | |
| JP2009297696A (en) | Method and device for preparing sterilized water containing carbonic acid gas | |
| JP2016169669A (en) | Liquid pumping device | |
| KR101091867B1 (en) | A manufacturing system of electrolytic sterilizing water | |
| KR102399942B1 (en) | Movable electrolysis sterilizing water generator | |
| CN212835631U (en) | Direct-connected variable-frequency water supply equipment |
Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| GR01 | Patent grant | ||
| GR01 | Patent grant | ||
| TR01 | Transfer of patent right |
Effective date of registration: 20230316 Address after: 101500 280 meters west of Wanggezhuang Village, Shilibao Town, Miyun District, Beijing Patentee after: Meidile (Beijing) Medical Technology Co.,Ltd. Address before: A2, No. 7, Fuqian Street West Road, Beixiaoying Town, Shunyi District, Beijing, 101300 Patentee before: Beijing Chengjin United Technology Co.,Ltd. |
|
| TR01 | Transfer of patent right |