CN106669524A - High-concentration ozone water all-in-one machine - Google Patents

Abstract

The invention relates to the field of preparation of ozone water and particularly relates to a high-concentration ozone water all-in-one machine. The all-in-one machine comprises a main control part, a high-concentration ozone generator (1), a low-voltage water source supplying device (4), a gas-liquid mixing pump (5), an efficient integration reaction separation tank (6), a high-pressure pump (12), a tail gas absorption device (19) and a high-concentration ozone water collection device (21), and further comprises a jet flow mixer (13) and a multi-grade efficient mixer (14). The all-in-one machine is additionally provided with two grades of ozone absorption, pressurizing and mixing systems so that the utilization rate of ozone gas is improved and the zone gas can be dissolved into water to the greater extent; meanwhile, the high-concentration ozone water all-in-one machine has the characteristics of one-key starting and stopping, water and electricity protection, low tail gas treatment difficulty, convenience for operation and capability of moving at any time; and diversified control can also be realized. The high-concentration ozone water generated by the all-in-one machine can also reach disinfection standards of the field of medicines.

Description

High-concentration ozone water integrated machine

Technical Field

The invention relates to the field of ozone water preparation, in particular to a high-concentration ozone water all-in-one machine.

Background

In the prior art, an apparatus for preparing ozone water is mainly composed of an ozone gas generator main body and a mixing apparatus. The ozone gas generator body is made of a high dielectric constant material and can be divided into three general types: glass, enamel and ceramics are also divided into different generators according to the material and the process of the materials of the glass, the enamel and the ceramics. The more delicate and fine the material used, the higher the concentration of ozone produced. The positive electrode material of the ozone gas generator comprises carbon steel, stainless steel, aluminum alloy, graphite and the like. The gas source of the ozone gas generator is used for providing gas for the ozone gas generator, the oxygen content in the gas source is determined by the type of the gas source, wherein when the gas source is air, the oxygen concentration is lowest; the gas source uses an oxygen generator to provide oxygen, and the oxygen is secondarily contained; when the gas source uses pure oxygen, the oxygen concentration is highest.

The mixing mode of the mixing equipment is mainly a jet flow mixing mode and a gas-liquid mixing pump mixing mode.

The existing ozone water preparation equipment is designed in a machine body separation mode, and the number of pipelines and electric control points is too many, so that the operation is inconvenient. The mixing mode used in the ozone water preparation equipment is gas-liquid mixing pump mixing or simple stirring and pressurizing mixing. The ozone water produced by adopting the two mixing modes has low concentration, can only carry out simple sterilization and disinfection, has slightly insufficient concentration when the surface of an object is sterilized and disinfected, and particularly can not reach the required concentration when medicinal materials are sterilized and disinfected. Meanwhile, the un-mixed ozone gas is discharged or decomposed, and the part of ozone is prepared by consuming a large amount of electric power, so that resources are seriously wasted, and the concept of environmental protection is not met.

Disclosure of Invention

The invention aims to provide the high-concentration ozone water all-in-one machine which is simple and convenient to operate, is green and environment-friendly and is used for preparing the ozone water with the concentration meeting the sterilization requirement.

The technical scheme adopted by the invention for solving the technical problems is as follows:

the high-concentration ozone water all-in-one machine comprises a main control component, a high-concentration ozone generator 1, a low-pressure water source providing device 4, a gas-liquid mixing pump 5, a high-efficiency integrated reaction separation tank 6, a high-pressure pump 12, a tail gas absorber 19 and a high-concentration ozone water collecting device 21, and further comprises a jet flow mixer 13 and a multi-stage high-efficiency mixer 14.

The high-concentration ozone generator 1 is internally provided with a positive reaction electrode and a negative reaction electrode, the positive electrode is an ultrathin high borosilicate glass tube 24, and the surface of the ultrathin high borosilicate glass tube 24 is coated with a conductive layer of graphene conductive coating; the cathode is a precision stainless steel tube 23; the precision stainless steel tube 23 penetrates through the ultrathin high borosilicate glass tube 24, and a gas channel is formed between the precision stainless steel tube and the ultrathin high borosilicate glass tube; and air ventilation gaskets 25 are fixedly arranged at two ends of the ultrathin high borosilicate glass tube 24.

The inlet of the gas-liquid mixing pump 5 is respectively communicated with the high-concentration ozone generator 1 and the low-pressure water source supply device 4 through pipelines.

The inside of the high efficiency integrated reaction separation tank 6 is partitioned into a first chamber and a second chamber by a partition 22.

A spherical flow damper 7 and a flow stabilizer 8 are arranged on the side wall in the first chamber of the high-efficiency integrated reaction separation tank 6; a water inlet of a first chamber of the high-efficiency integrated reaction separation tank 6 is communicated with an outlet of the gas-liquid mixing pump 5 through a pipeline, and the spherical flow damper 7 is arranged below the water inlet; the flow stabilizer 8 is arranged below the spherical flow damper 7.

An impact mixer bracket 16 and an impact mixer 15 are arranged in the second chamber of the high-efficiency integrated reaction separation tank 6; the impact mixer support 16 is fixed on the inner wall of the top end of the second chamber of the high-efficiency integrated reaction separation tank 6, and the impact mixer 15 is fixedly arranged on the impact mixer support 16.

The bottom of the second chamber of the high-efficiency integrated reaction separation tank 6 is communicated with a high-concentration ozone water collecting device 21 through a pipeline.

The inlet of the high-pressure pump 12 is communicated with the bottom of the first chamber of the high-efficiency integrated reaction separation tank 6 through a pipeline.

A first-stage automatic exhaust valve 11 is arranged on the wall of the first chamber of the high-efficiency integrated reaction separation tank 6; the inlet of the jet mixer 13 is respectively communicated with the first-stage automatic exhaust valve 11 and the outlet of the high-pressure pump 12 through pipelines.

The inlet of the multi-stage high-efficiency mixer 14 is communicated with the outlet of the jet flow mixer 13, and the outlet of the multi-stage high-efficiency mixer 14 is communicated with an impact mixer 15 in the second chamber of the high-efficiency integrated reaction separation tank 6 through a pipeline.

A second-stage automatic exhaust valve 18 is arranged on the outer tank wall of the second chamber of the high-efficiency integrated reaction separation tank 6; the secondary automatic exhaust valve 18 is connected with a tail gas absorber 19.

An ozone electromagnetic valve 2 is arranged on a pipeline between the high-concentration ozone generator 1 and the mixing pump 5.

A water flow switch 3 is arranged on a pipeline which is communicated with the first chamber of the high-efficiency integrated reaction tank 6 by the gas-liquid mixing pump 5.

The first chamber of the high-efficiency integrated reaction separation tank 6 is provided with a primary pressure sensor 9.

A first-stage middle electric valve 10 is arranged on a pipeline between the first chamber of the high-efficiency integrated reaction separation tank 6 and the high-pressure pump 12.

A second-stage pressure sensor 17 is arranged in the second chamber of the high-efficiency integrated reaction separation tank 6.

A second-stage water production electric valve 20 is arranged on a pipeline between the second chamber of the high-efficiency integrated reaction separation tank 6 and the high-concentration ozone water collecting device 21.

The high-concentration ozone generator 1 is electrically connected with the main control unit.

The main control part is respectively and electrically connected with the ozone electromagnetic valve 2, the water flow switch 3, the primary pressure sensor 9, the primary middle electric valve 10, the primary automatic exhaust valve 11, the secondary pressure sensor 17, the secondary automatic exhaust valve 18 and the secondary water production electric valve 20.

The distance between the ultrathin high borosilicate glass tube 24 and the precision stainless steel tube 23 is 1.5 mm.

The material of the fixed ventilation gasket 25 is polytetrafluoroethylene.

The flow stabilizer 8 has a working cross-section identical to the cross-section of the first chamber.

The direction of the partition plate 22 for dividing the high-efficiency integrated reaction separation tank 6 is a vertical direction.

The invention has the beneficial effects that:

1) the high-concentration ozone water generated by the high-concentration ozone water all-in-one machine can improve the disinfection level of the ozone water on the surface of an object and can reach the disinfection standard in the field of medicine;

2) a secondary ozone absorption pressurization mixing system is added, so that the utilization rate of ozone gas is increased, and the ozone gas can be dissolved in water to a greater extent;

3) the ozone gas emission is reduced, the tail gas treatment difficulty is reduced, and the environment is not polluted;

4) the integrated machine has the advantages of one-key start-stop and water-electricity protection, convenient operation, capability of being moved at any time and realization of diversified control.

Drawings

FIG. 1 is a schematic structural diagram of the high concentration ozone water all-in-one machine of the present invention;

fig. 2 is a schematic diagram of the positive and negative electrodes of the high concentration ozone generator 1 of the high concentration ozone water all-in-one machine of the present invention.

Wherein the reference numerals are:

1 high concentration ozone generator 2 ozone electromagnetic valve

3 water flow switch 4 low pressure water source providing device

5 gas-liquid mixing pump 6 high-efficiency integrated reaction separation tank

7 spherical current damper 8 current stabilizer

9 one-stage pressure sensor and 10 one-stage intermediate electric valve

12 high-pressure pump with 11-stage automatic exhaust valve

13 jet mixer 14 multistage high-efficiency mixer

15 impingement Mixer 16 impingement Mixer holder

17 two-stage pressure sensor 18 two-stage automatic exhaust valve

19 tail gas absorber 20 second grade water production electric valve

21 high concentration ozone water collecting device 22 baffle

23-precision stainless steel tube 24 ultrathin high borosilicate glass tube

25 fixed ventilating cushion ring

Detailed Description

The invention will be further explained with reference to the drawings.

As shown in fig. 1, the high concentration ozone water all-in-one machine of the present invention comprises a main control unit, a high concentration ozone generator 1, a low pressure water source providing device 4, a gas-liquid mixing pump 5, a high efficiency integrated reaction separation tank 6, a high pressure pump 12, a jet mixer 13, a multistage high efficiency mixer 14, a tail gas absorber 19 and a high concentration ozone water collecting device 21, wherein:

as shown in fig. 2, the high concentration ozone generator 1 is provided with a positive and a negative reaction electrode, the positive electrode is an ultra-thin borosilicate glass tube 24, and the surface of the ultra-thin borosilicate glass tube 24 is coated with a conductive layer of graphene conductive coating; the negative electrode is a precision stainless steel tube 23. The precision stainless steel tube 23 penetrates through the ultra-thin high borosilicate glass tube 24, and a gas channel is formed between the precision stainless steel tube and the ultra-thin high borosilicate glass tube. And two ends of the ultrathin high borosilicate glass tube 24 are provided with fixed air-permeable cushion rings 25, and the materials of the fixed air-permeable cushion rings 25 are polytetrafluoroethylene. Preferably, the distance between the ultra-thin borosilicate glass tube 24 and the precision stainless steel tube 23 is 1.5 mm.

The inlet of the gas-liquid mixing pump 5 is respectively communicated with the high-concentration ozone generator 1 and the low-pressure water source supply device 4 through pipelines.

The inside of the high-efficiency integrated reaction separation tank 6 is divided into a first chamber and a second chamber by a partition plate 22; preferably, the direction in which the partition plate 22 partitions the high-efficiency integrated reaction separation tank 6 is a vertical direction.

The side wall in the first chamber of the high-efficiency integrated reaction separation tank 6 is provided with a spherical flow damper 7 and a flow stabilizer 8 through bolts. A water inlet of a first chamber of the high-efficiency integrated reaction separation tank 6 is communicated with an outlet of the gas-liquid mixing pump 5 through a pipeline, and the spherical flow damper 7 is arranged below the water inlet; the flow stabilizer 8 is arranged below the spherical flow damper 7 and has a working section the same as the cross section of the first chamber.

An impact mixer bracket 16 and an impact mixer 15 are arranged in the second chamber of the high-efficiency integrated reaction separation tank 6; the impact mixer support 16 is fixed on the inner wall of the top end of the second chamber of the high-efficiency integrated reaction separation tank 6 through bolts, and the impact mixer 15 is fixed on the impact mixer support 16 through bolts.

The bottom of the second chamber of the high-efficiency integrated reaction separation tank 6 is communicated with a high-concentration ozone water collecting device 21 through a pipeline.

The inlet of the high-pressure pump 12 is communicated with the bottom of the first chamber of the high-efficiency integrated reaction separation tank 6 through a pipeline.

The first chamber of the high-efficiency integrated reaction separation tank 6 is provided with a first-stage automatic exhaust valve 11 on the wall. The inlet of the jet mixer 13 is respectively communicated with the first-stage automatic exhaust valve 11 and the outlet of the high-pressure pump 12 through pipelines.

The inlet of the multi-stage high-efficiency mixer 14 is communicated with the outlet of the jet flow mixer 13, and the outlet of the multi-stage high-efficiency mixer 14 is communicated with an impact mixer 15 in the second chamber of the high-efficiency integrated reaction separation tank 6 through a pipeline.

The second-stage automatic exhaust valve 18 is arranged on the wall of the second chamber of the high-efficiency integrated reaction separation tank 6. The secondary automatic exhaust valve 18 is connected with a tail gas absorber 19.

An ozone electromagnetic valve 2 is arranged on a pipeline between the high-concentration ozone generator 1 and the mixing pump 5.

A water flow switch 3 is arranged on a pipeline which is communicated with the first chamber of the high-efficiency integrated reaction tank 6 by the gas-liquid mixing pump 5.

The first chamber of the high-efficiency integrated reaction separation tank 6 is provided with a primary pressure sensor 9.

A first-stage middle electric valve 10 is arranged on a pipeline between the first chamber of the high-efficiency integrated reaction separation tank 6 and the high-pressure pump 12.

A second-stage pressure sensor 17 is arranged in the second chamber of the high-efficiency integrated reaction separation tank 6.

A second-stage water production electric valve 20 is arranged on a pipeline between the second chamber of the high-efficiency integrated reaction separation tank 6 and the high-concentration ozone water collecting device 21.

The high-concentration ozone generator 1 is electrically connected with the main control unit.

The main control part is respectively and electrically connected with the ozone electromagnetic valve 2, the water flow switch 3, the primary pressure sensor 9, the primary middle electric valve 10, the primary automatic exhaust valve 11, the secondary pressure sensor 17, the secondary automatic exhaust valve 18 and the secondary water production electric valve 20.

The working process of the invention is as follows:

the gas-liquid mixing pump 5 is started, the water source provided by the low-pressure water source providing device 4 flows through the gas-liquid mixing pump 5, when the water source passes through the water flow switch 3, the water flow switch 3 senses that water flow continuously passes through and sends a signal to the main control unit, the main control unit controls the high-concentration ozone generator 1 to start to prepare ozone gas after receiving the signal, and meanwhile, the ozone electromagnetic valve 2 is controlled to be opened. The gas-liquid mixing pump 5 pumps the high-concentration ozone gas generated in the high-concentration ozone generator 1 to mix it with water in the gas-liquid mixing pump 5 for the first time.

The ozone water after the first mixing enters a first chamber of a high-efficiency integrated reaction separation tank 6, and after the ozone water slowly flows through a spherical flow damper 7, primary pressurization is carried out in the first chamber. The pressure is set by the master control unit. When the pressure in the first chamber of the high-efficiency integrated reaction separation tank 6 reaches a set value, the primary pressure sensor 9 transmits a signal to the primary middle electric valve 10 through the main control component to open the primary middle electric valve.

Starting the high-pressure pump 12, stabilizing the flow of the ozone water after the primary pressurization by the flow stabilizer 8, pumping the ozone water into the jet flow mixer 13 by the high-pressure pump 12 at a high speed, simultaneously sucking the residual ozone gas in the first chamber of the high-efficiency integrated reaction separation tank 6 into the jet flow mixer 13 through the primary automatic exhaust valve 11, and respectively mixing the ozone water and the residual ozone gas into the jet flow mixer 13 through the high-pressure pump 12 and the primary automatic exhaust valve 11 for secondary mixing. The ozone water after the second mixing is cut and mixed evenly by a multi-stage high-efficiency mixer 14, enters a second chamber of the high-efficiency integrated reaction separation tank 6 for secondary pressurization, and is sprayed to an impact mixer 15 in a spraying mode.

After the ozone water is impacted, part of ozone gas dissolved in the water escapes again. During the secondary pressurization in the second chamber of the highly efficient integrated reaction tank 6, the escaping ozone gas is re-dissolved in the falling ozone water.

Through twice mixing and pressurized dissolving, ozone water in the high-efficiency integrated reaction separation tank 6 is supersaturated in ozone and oxygen solubility, and in the twice mixing process, the gas-liquid mixing pump 5 and the high-pressure pump 12 enable ozone in water to exist in ozone water in a micron or even nanometer level state under the action of cutting water force, so that the ozone concentration is increased, and the attenuation time of ozone in water is reduced.

The pressure in the second chamber of the high efficiency integrated reaction separation tank 6 is set by the main control unit. When the pressure in the second chamber of the high-efficiency integrated reaction separation tank 6 reaches a set value, the second-stage pressure sensor 17 transmits a signal to the second-stage water production electric valve 20 to open the second-stage water production electric valve, and the high-concentration ozone water can flow out to be directly used or used for preparing ozone water products. The residual gas in the second chamber can enter a tail gas absorber 19 through a secondary automatic exhaust valve 18 to realize tail gas recovery.

Preferably, the activation time of the high-pressure pump 12 is: 15 seconds after the start of the gas-liquid mixing pump 5.

If the water flow switch 3 does not pass water or the water flow is interrupted after the gas-liquid mixing pump 5 is started, the signal given to the main control unit by the water flow switch 3 is interrupted. At this point the master control unit will shut down all devices in operation.

The water source is a stable low-pressure sufficient water source, no impurities and no bubbles exist in the water source, and the water temperature is normal temperature or lower than the normal temperature.

Claims (5)

1. High concentration ozone water all-in-one, including main control unit, high concentration ozone generator (1), low pressure water source provide device (4), gas-liquid mixing pump (5), high-efficient integrated reaction-separation jar (6), high-pressure pump (12), tail gas absorber (19) and high concentration ozone water collection device (21), its characterized in that: also comprises a jet flow mixer (13) and a multi-stage efficient mixer (14); wherein,

the high-concentration ozone generator (1) is internally provided with a positive reaction electrode and a negative reaction electrode, the positive electrode is an ultrathin high borosilicate glass tube (24), and the surface of the ultrathin high borosilicate glass tube (24) is coated with a conductive layer of graphene conductive coating; the negative electrode is a precision stainless steel tube (23); the precision stainless steel pipe (23) penetrates through the ultrathin high borosilicate glass pipe (24), and a gas channel is formed between the precision stainless steel pipe and the ultrathin high borosilicate glass pipe; both ends of the ultrathin high borosilicate glass tube (24) are provided with fixed ventilating gaskets (25);

the inlet of the gas-liquid mixing pump (5) is respectively communicated with the high-concentration ozone generator (1) and the low-pressure water source supply device (4) through pipelines;

the inside of the high-efficiency integrated reaction separation tank (6) is divided into a first chamber and a second chamber by a partition plate (22);

a spherical flow damper (7) and a flow stabilizer (8) are arranged on the side wall in the first chamber of the high-efficiency integrated reaction separation tank (6); a water inlet of a first chamber of the high-efficiency integrated reaction separation tank 6 is communicated with an outlet of a gas-liquid mixing pump (5) through a pipeline, and the spherical flow damper (7) is arranged below the water inlet; the flow stabilizer (8) is arranged below the spherical flow damper (7);

an impact mixer bracket (16) and an impact mixer (15) are arranged in the second chamber of the high-efficiency integrated reaction separation tank (6); the impact mixer bracket (16) is fixed on the inner wall of the top end of the second chamber of the high-efficiency integrated reaction separation tank (6), and the impact mixer (15) is installed and fixed on the impact mixer bracket (16);

the bottom of the second chamber of the high-efficiency integrated reaction separation tank (6) is communicated with a high-concentration ozone water collecting device (21) through a pipeline;

the inlet of the high-pressure pump (12) is communicated with the bottom of the first chamber of the high-efficiency integrated reaction separation tank (6) through a pipeline;

a first-stage automatic exhaust valve (11) is arranged on the outer tank wall of the first chamber of the high-efficiency integrated reaction separation tank (6); the inlet of the jet flow mixer (13) is respectively communicated with the first-stage automatic exhaust valve (11) and the outlet of the high-pressure pump (12) through pipelines;

the inlet of the multi-stage high-efficiency mixer (14) is communicated with the outlet of the jet flow mixer (13), and the outlet of the multi-stage high-efficiency mixer (14) is communicated with an impact mixer (15) in a second chamber of the high-efficiency integrated reaction separation tank (6) through a pipeline;

a secondary automatic exhaust valve (18) is arranged on the outer tank wall of the second chamber of the high-efficiency integrated reaction separation tank (6); the secondary automatic exhaust valve 18 is connected with a tail gas absorber (19);

an ozone electromagnetic valve (2) is arranged on a pipeline between the high-concentration ozone generator (1) and the mixing pump (5);

a water flow switch (3) is arranged on a pipeline which is communicated with the first chamber of the high-efficiency integrated reaction tank (6) by the gas-liquid mixing pump (5);

a first chamber of the high-efficiency integrated reaction separation tank (6) is provided with a first-stage pressure sensor (9);

a first-stage middle electric valve (10) is arranged on a pipeline between the first chamber of the high-efficiency integrated reaction separation tank (6) and the high-pressure pump (12);

a second-stage pressure sensor (17) is arranged in a second chamber of the high-efficiency integrated reaction separation tank (6);

a second-stage water production electric valve (20) is arranged on a pipeline between the second chamber of the high-efficiency integrated reaction separation tank (6) and the high-concentration ozone water collecting device (21);

the high-concentration ozone generator (1) is electrically connected with the main control unit;

the main control part is respectively and electrically connected with the ozone electromagnetic valve (2), the water flow switch (3), the primary pressure sensor (9), the primary middle electric valve (10), the primary automatic exhaust valve (11), the secondary pressure sensor (17), the secondary automatic exhaust valve (18) and the secondary water production electric valve (20).

2. The high concentration ozonated water all-in-one of claim 1, wherein: the distance between the ultrathin high borosilicate glass tube (24) and the precision stainless steel tube (23) is 1.5 mm.

3. The high concentration ozonated water all-in-one of claim 1 or 2, wherein: the material of the fixed ventilation gasket (25) is polytetrafluoroethylene.

4. The high concentration ozonated water all-in-one of claim 1 or 2, wherein: the flow stabilizer (8) has a working section identical to the cross section of the first chamber.

5. The high concentration ozonated water all-in-one of claim 1 or 2, wherein: the direction of the partition plate (22) for separating the high-efficiency integrated reaction separation tank (6) is vertical.