TWI789966B - Cabinet-type electrolysis apparatus - Google Patents

Abstract

The cabinet-type electrolysis apparatus of present invention has a cabinet body to connect a water supply, and a mixing tank, a storage tank, an electrolytic tank and a gas-liquid mixing device are provided inside the cabinet body. A salt water solution is formed by mixing water and a plurality of salt particles through the mixing tank, and the salt water solution is stored in the storage tank. Wherein, the salt water solution is electrolyzed by the electrolytic tank to form an oxidation complex gas. An oxidation complex gas solution is formed by mixing the oxidation complex gas and water through the gas-liquid mixing device. Therefore, the gas-liquid mixing device can be assembled in the cabinet body to generate the oxidation complex gas solution for reducing the volume of electrolysis apparatus, so that users can produce the oxidation complex gas solution conveniently by themselves.

Description

Cabinet type electrolysis equipment

The present invention relates to an electrolysis equipment capable of producing composite gaseous aqueous solution of an oxidation system, in particular to an electrolysis equipment in which all relevant mechanisms of the electrolysis equipment are arranged inside a cabinet.

Oxidation system composite gas itself has an unpaired free active electron, which makes oxidation system composite gaseous aqueous solution have strong oxidation ability, which can be used to oxidize proteins, peptides, DNA or RNA of pathogens such as bacteria, viruses, molds, etc. In order to eliminate these pathogens, and because the gaseous oxidizing system compound gas cannot provide users with convenience, it is currently used in medical and health care, food processing, environmental protection, industrial water, Xumu breeding and sewage treatment: In industries such as oxidizers and other industries, most of them dissolve the oxidizing system composite gas in water to form an oxidizing system composite gaseous aqueous solution, so that users can conveniently use the oxidizing system composite gaseous aqueous solution for disinfection, sterilization, and deodorization.

Among them, the current production method of the composite gaseous aqueous solution of the oxidation system is mainly to use conventional electrolysis equipment to electrolyze salt water to generate the aforementioned composite gas of the oxidation system, and then, the conventional electrolysis equipment dissolves the composite gas of the oxidation system in water to form The composite gaseous aqueous solution of the oxidation system, however, the overall volume of the conventional electrolysis equipment is too large, so that the medical institutions that need to use the composite gaseous aqueous solution of the oxidation system for a long time do not have enough space to place the conventional electrolysis equipment, so that the medical institutions cannot Self-produced oxidized composite gaseous aqueous solution, and medical institutions must regularly purchase oxidized composite gaseous aqueous solution from manufacturers who produce oxidized composite gaseous aqueous solution. When the supply of the composite gaseous aqueous solution of the oxidation system is in short supply, medical institutions often do not have enough composite gaseous aqueous solution of the oxidation system for use.

The main purpose of the present invention is to arrange the electrolytic equipment capable of producing the composite gaseous aqueous solution of the oxidation system inside the cabinet, so that the overall volume of the electrolytic equipment can be reduced, and after the electrolytic equipment is installed inside the cabinet, the general consumer only needs to Installing a clean water supply source that can provide clean water on the electrolysis equipment and adding salt particles to the electrolysis equipment can produce an oxidizing system composite gaseous aqueous solution through the electrolysis equipment.

In order to achieve the above object, the cabinet-type electrolysis equipment of the present invention includes: a cabinet body, a brine storage tank, an electrolytic tank, a gas-liquid mixing device and a brine mixing tank, and an accommodating space is formed inside the cabinet body, and is connected to A clean water supply source capable of providing clean water, and a brine storage tank located inside the accommodating space and used for storing a brine solution.

In addition, the electrolytic tank is located inside the accommodating space and is connected to the brine storage tank to hold the brine solution, and the electrolytic tank can electrolyze the brine solution to form a composite gas of an oxidation system. The gas-liquid The mixing device is located inside the accommodating space, and is connected to the clean water supply source and the electrolytic cell at the same time, and the gas-liquid mixing device can dissolve the above-mentioned oxidation-system composite gas in the above-mentioned clean water to form an oxidation-system composite gas. A gaseous aqueous solution, wherein the above-mentioned brine mixing tank is used to obtain the above-mentioned clean water from the above-mentioned clean water supply source, and the above-mentioned brine mixing tank has a feed inlet that can add a plurality of salt particles to the inside of the above-mentioned brine mixing tank and one in the above-mentioned brine mixing tank An internal partition, the interior of the above-mentioned brine mixing tank is divided into a feeding space connected to the above-mentioned feeding port and a suction space connected to the above-mentioned brine storage tank through the above-mentioned partition, and the above-mentioned feeding space stores the above-mentioned A plurality of salt granules, so that the above salt granules are mixed with clear water to form the above brine solution, and the above partition is provided with complex Several filter holes are used to filter the plurality of salt particles, so that the above-mentioned suction space can obtain the saline solution without the above-mentioned salt particles, and then the above-mentioned suction space can transport the saline solution to the above-mentioned brine storage tank. .

In this embodiment, the outline of the above-mentioned filter holes is smaller than the above-mentioned salt particles, so that the above-mentioned plurality of salt particles can stay in the inside of the above-mentioned feeding space and dissolve in the above-mentioned clean water, wherein the above-mentioned brine mixing tank is equipped with a motor and an electric A control valve, the motor can selectively flow the saline solution located inside the suction space to the interior of the feeding space or the interior of the saline storage tank through the electric control valve.

Furthermore, the above-mentioned cabinet type electrolysis equipment is further assembled with an add-on board at the above-mentioned material inlet, and the above-mentioned add-on board has a connecting part inside the above-mentioned accommodating space and an inclined part extending from the above-mentioned connecting part to the outside of the above-mentioned accommodating space. In a preferred embodiment, the above-mentioned connection part is provided with a flange that can penetrate into the above-mentioned feeding port, and the above-mentioned inclined part is provided with a slant plate that can introduce the above-mentioned plurality of salt particles into the above-mentioned feeding space and two Rib at the edge of the sloped plate.

The present invention is characterized in that the brine mixing tank, the brine storage tank, the electrolytic tank and the gas-liquid mixing device are all arranged inside the accommodating space of the cabinet to reduce the overall volume of the electrolysis equipment, and the brine mixing tank, the brine storage tank, After the electrolytic tank and the gas-liquid mixing device are placed inside the storage space, the general consumer only needs to install a clean water supply source that can provide clean water to the cabinet and add salt particles to the brine mixing tank to produce through the electrolytic equipment Oxidation system composite gaseous aqueous solution.

1: Cabinet type electrolysis equipment

10: Cabinet

11:Accommodating space

111: First front space

112: The second front space

113: back space

114: left space

115: First right space

116:Second right space

12: Central vertical partition

13: Front horizontal partition

14: Rear horizontal partition

15: Rear vertical partition

16: Right horizontal partition

20: Delivery pipeline module

21: Electric control valve

22: motor

30: Power Mechanism

40: Hybrid body

41: Salt water mixing tank

411: clapboard

412: Feeding space

413: suction space

414: filter hole

415: feed port

42: Add board

421: connection part

421a: Flange

422: Inclined part

422a: convex strip

422b: inclined plate

50: Salt water storage tank

60: Electrolyzer

70: Gas-liquid mixing device

80: Clean water supply source

Fig. 1 is a block diagram of the cabinet type electrolysis equipment of the present invention; Fig. 2A and Fig. 2B are schematic diagrams of the cabinet body; Fig. 3 is a schematic diagram of the conveying pipeline module and the power supply mechanism inside the cabinet body; Figure 4 is a schematic diagram of the mixing mechanism, the brine storage tank and the electrolytic tank inside the cabinet; Figure 5 is a schematic diagram of the mixing mechanism; Figure 6 is a schematic diagram of the inclined part of the adding plate outside the accommodation space; and Figure 7 is a gas-liquid Schematic diagram of the mixing unit located inside the cabinet.

Hereby for the convenience of a further clear and detailed understanding and understanding of the structure of the present invention, use and its features, the preferred embodiment is enumerated, and the detailed description of the drawings is as follows: please refer to shown in Fig. 1, the cabinet of the present invention The modular electrolysis equipment 1 is mainly composed of a cabinet 10, a delivery pipeline module 20, a power supply mechanism 30, a mixing mechanism 40, a brine storage tank 50, an electrolytic tank 60 and a gas-liquid mixing device 70, please 2A and 2B, the inside of the cabinet 10 is hollow, so that an accommodating space 11 is formed inside the cabinet 10, wherein the cabinet 10 has a central vertical partition in the center of the accommodating space 11. plate 12, and the front side of the central vertical partition 12 is provided with a front horizontal partition 13 vertically arranged in the central vertical partition 12, and the rear side of the central vertical partition 12 is provided with a rear horizontal partition parallel to the front horizontal partition 13 Plate 14, wherein the top of the rear horizontal partition 14 is provided with a rear vertical partition 15 perpendicular to the central vertical partition 12 and the rear horizontal partition 14 at the same time, and the right side of the rear vertical partition 15 is provided with a vertical interval arranged in the rear horizontal The right horizontal partition 16 of the partition 14, in this embodiment, the accommodating space 11 passes through the central vertical partition 12, the front horizontal partition 13, the rear horizontal partition 14, the rear vertical partition 15 and the right horizontal partition 16 It is divided into a first front space 111 directly below the front horizontal partition 13, a second front space 112 directly above the front horizontal partition 13, and a rear space 112 directly below the rear horizontal partition 14. Space 113, a left space 114 on the left side of the rear vertical partition 15, a first right space 115 between the rear horizontal partition 14 and the right horizontal partition 16, and a first right space 115 directly above the right horizontal partition 16 The second right space 116 of .

1 and 3, the delivery pipeline module 20 is located inside the first front space 111 of the cabinet 10, so that the delivery pipeline module 20 is located under the front horizontal partition 13 of the cabinet 10, wherein The delivery pipeline module 20 is connected to a clean water supply source 80 assembled in the cabinet 10, and the delivery pipeline module 20 is used to connect the mixing mechanism 40, the brine storage tank 50, the electrolytic tank 60, the gas-liquid mixing device 70 and the The clean water supply sources 80 communicate with each other. In this embodiment, the delivery pipeline module 20 has an electric control valve 21 connected between the mixing mechanism 40 and the brine storage tank 50 and a motor 22 connected to the electric control valve 21. The electric control valve 21 is used to control the selective flow of liquid to the mixing mechanism 40 or the brine storage tank 50, and the clean water supply source 80 can provide clean water to the delivery pipeline module 20, wherein the power supply mechanism 30 is located at the second Inside the front space 112 , the power supply mechanism 30 is located above the front horizontal partition 13 , and the power supply mechanism 30 is electrically connected to the delivery pipeline module 20 and the electrolytic tank 60 , so that the power supply mechanism 30 can provide voltage to the electrolytic tank 60 .

1, 4 and 5, the mixing mechanism 40 has a brine mixing tank 41 and an adding plate 42, the brine mixing tank 41 is located inside the rear space 113 of the cabinet body 10, and the brine mixing tank 41 is connected to In the delivery pipeline module 20, the clean water supply source 80 can deliver the clean water to the salt water mixing tank 41 through the delivery pipeline module 20, and then the salt water mixing tank 41 can hold the clean water provided by the clean water supply source 80, as shown in Figure 5 As shown, the inside of the brine mixing tank 41 is provided with a partition 411, so that the inside of the brine mixing tank 41 is divided into a feeding space 412 and a suction space 413 adjacent to the feeding space 412 through the partition 411, and The separator 411 penetrates to form a plurality of filter holes 414, so that the feed space 412 communicates with the suction space 413 through the plurality of filter holes 414, wherein the feed space 412 communicates with a feed port arranged on the upper side of the brine mixing tank 41 415. In addition, a part of the adding plate 42 is set as a connecting portion 421 connected to the brine mixing tank 41, and the remaining part of the adding plate 42 is set as a slope for introducing a plurality of salt particles into the feeding space 412. part 422, in this embodiment, the connecting part 421 is provided with a flange that can penetrate into the material inlet 414 421a, and the inclined portion 422 is provided with two protruding strips 422a arranged at intervals and a slanting plate 422b between the two protruding strips 422a.

Please refer to Fig. 6, when the flange 421a of the connecting part 421 is connected to the feed port 414 of the brine mixing tank 41, the connecting part 421 is located directly above the feeding space 412, so that the connecting part 421 is located in the rear space 113 At the same time, the inclined portion 422 of the adding plate 42 is located outside the accommodating space 11 of the cabinet body 10, whereby a plurality of salt particles pass through the inclined portion 422 and can be added to the outside of the accommodating space 11 to the feeding space 412 so that the clean water inside the brine mixing tank 41 can be mixed with a plurality of salt particles to form a brine solution, and then the brine solution can pass through the filter hole 414 and flow between the feeding space 412 and the suction space 413 , in this embodiment, the suction space 413 is connected to the delivery pipeline module 20 , so that the saline solution inside the suction space 413 can flow to the delivery pipeline module 20 .

In this embodiment, the motor 22 of the delivery pipeline module 20 of the mixing mechanism is installed in the brine mixing tank 41 of the mixing mechanism 40, and the motor 22 can be positioned in the suction space 413 through the electric control valve 21 of the delivery pipeline module 20. The internal brine solution is introduced into the feed space 412 of the brine mixing tank 41, so as to speed up the time for the salt particles to dissolve in the clear water, and relatively increase the salt content of the brine solution. In this embodiment, the filter holes 414 of the partition 411 The profile is smaller than the salt particles, so that the plurality of salt particles cannot pass through the filter hole 414 and move from the inside of the feeding space 412 to the inside of the suction space 413, and then the plurality of salt particles can only stay in the inside of the feeding space 412, thereby , when the motor 22 introduces the brine solution located inside the suction space 413 into the inside of the feeding space 412, only the brine solution will pass through the inside of the motor 22, and the larger salt particles will not enter the inside of the motor 22 Internally, the opposing motor 22 will not be damaged by ingesting salt particles with a larger profile.

Referring to Fig. 4 again, the brine storage tank 50 is located above the right horizontal partition 16 of the cabinet body 10, so that the brine storage tank 50 is located inside the second right space 116 of the cabinet body 10, wherein the brine storage tank 50 The solenoid valve 21 connected to the delivery pipeline module 20 enables the motor 22 of the delivery pipeline module 20 to transport the brine solution located inside the suction space 413 to the brine storage tank through the delivery pipeline module 21 50, so that the brine storage tank 50 is used to store the brine solution. In addition, the electrolytic cell 60 is located between the right horizontal partition 16 and the rear horizontal partition 14 of the cabinet body 10, so that the electrolytic cell 60 is located at the bottom of the cabinet body 10. Inside the first right space 115, the electrolytic tank 60 is connected to the delivery pipeline module 20 and the gas-liquid mixing device 70, so that the brine solution located inside the brine storage tank 50 can flow into the electrolytic tank through the delivery pipeline module 20 60, when there is a brine solution stored in the electrolytic tank 60, the power supply mechanism 30 provides voltage to the electrolytic tank 60, so that the electrolytic tank 60 electrolyzes the brine solution located inside the brine storage tank 50 to form a gas-liquid mixture. The oxidizing compound gas of the device 70.

Please refer to Fig. 7, the gas-liquid mixing device 70 is located inside the left space 114 of the cabinet body 10, wherein the gas-liquid mixing device 70 is connected to the delivery pipeline module 20 and the electrolytic cell 60, so that the composite gas of the oxidation system can not only It can flow into the inside of the gas-liquid mixing device 70, and the clean water from the clean water supply source 80 can also enter the inside of the gas-liquid mixing device 70. When the inside of the gas-liquid mixing device 70 contains an oxidizing system composite gas and clean water, the gas-liquid mixing The device 70 is capable of dissolving the composite gas of the oxidation system in clear water to form a composite gaseous aqueous solution of the oxidation system.

The above-mentioned embodiments are only used for convenience to illustrate this creation and do not limit it. Without departing from the scope of the present invention, various simple deformations and modifications made by skilled persons familiar with this industry according to the patent scope of this creation and the description of the invention should still be applied. Included in the scope of the following patent applications.

1: Cabinet type electrolysis equipment

10: Cabinet

20: Delivery pipeline module

30: Power Mechanism

40: Hybrid body

50: Salt water storage tank

60: Electrolyzer

70: Gas-liquid mixing device

Claims (5)

A cabinet-type electrolysis equipment, comprising: a cabinet body with an accommodating space formed inside and connected to a clean water supply source capable of providing clean water; a brine storage tank located inside the above-mentioned accommodating space and used to store a A saline solution; an electrolytic tank located inside the accommodating space and connected to the brine storage tank to hold the above-mentioned brine solution, and the above-mentioned electrolyzer can electrolyze the above-mentioned brine solution to form a composite gas of an oxidation system; and A gas-liquid mixing device, located inside the above-mentioned accommodating space, and connected to the above-mentioned clean water supply source and the electrolytic cell at the same time, and the above-mentioned gas-liquid mixing device can dissolve the above-mentioned oxidizing system composite gas in the above-mentioned clean water to mix to form a It is a composite gaseous aqueous solution; it is characterized in that: the interior of the above-mentioned accommodating space is further provided with a salt water mixing tank that can obtain the above-mentioned clean water from the above-mentioned clean water supply source, and the above-mentioned salt water mixing tank has a device that can add a plurality of salt particles to the above-mentioned salt water mixing tank An internal feeding port and a partition inside the above-mentioned brine mixing tank, the inside of the above-mentioned brine mixing tank is divided into a feeding space connected to the above-mentioned feeding port and a feeding space connected to the above-mentioned brine storage tank through the above-mentioned partition The above-mentioned suction space, and the above-mentioned feeding space stores the above-mentioned plurality of salt particles, so that the above-mentioned salt particles are mixed with clean water to form the above-mentioned brine solution, and the above-mentioned separator is provided with a plurality of filter holes to filter the above-mentioned multiple salt particles, so that the above-mentioned pumping The suction space can obtain the saline solution free from the salt particles, and then the suction space can transport the saline solution to the saline storage tank. The cabinet-type electrolysis equipment according to Claim 1, wherein the outline of the filter hole is smaller than the salt particles, so that the plurality of salt particles can stay in the feeding space and dissolve in the clear water. The cabinet-type electrolysis equipment as described in Claim 1, wherein the above-mentioned brine mixing tank is equipped with a motor and an electric control valve, and the above-mentioned motor can selectively flow the brine solution inside the above-mentioned suction space to the The interior of the above-mentioned feeding space or the interior of the above-mentioned brine storage tank. The cabinet-type electrolysis equipment as described in Claim 1, wherein the above-mentioned cabinet-type electrolysis equipment is further assembled with an additional plate at the above-mentioned material inlet, and the above-mentioned additional plate has a connection part inside the above-mentioned accommodating space and a connection part from the above-mentioned The connecting portion extends to the inclined portion outside the accommodating space. The cabinet-type electrolysis equipment as described in Claim 4, wherein the above-mentioned connection part is provided with a flange that can penetrate into the above-mentioned material inlet, and the above-mentioned inclined part is provided with a flange that can introduce the above-mentioned plurality of salt particles into the inside of the above-mentioned material-feed space slant plate and two ribs on the edge of the slant plate.

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