DE29610335U1 - Multifunctional ozone and anion generator - Google Patents

Description

MULTIFUNCTIONAL OZONE AND ANION GENERATOR

The present invention relates to a multifunctional ozone and anion generator, in particular to a multifunctional ozone and anion generator which combines the functions of a generator of ozone, of anions and of a mixture of ozone and anions.

Ozone is widely used in industry and healthcare to kill bacteria, eliminate odors, dissolve toxins, purify water, and for beauty and health care. The oxidizing effect of ozone, especially pure ozone dissolved in water, is very strong. This gives ozone the effects of killing bacteria, eliminating odors and dissolving toxins.

Ozone dissolved in water has the following documented effects:
1. Killing of bacteria? Experiments have shown that the killing effect of ozone dissolved in water is 1000 to 3000 times higher than the killing effect of chlorine. Coli bacteria, staphylococci and salmonella can be eliminated in a short time.
2. Elimination of odors: Elimination of bad odors in water as well as the stench of fish, shrimp and crabs.

3. Bleaching: oxidation and decomposition of harmful pigments, removal of color and bleaching. (Natural plants and edible dyes do not suffer any effect.)

4. Removal of insecticides in vegetables and fruits: oxidation, decomposition and neutralization of poisons as well as removal of residual insecticides in vegetables and fruits.

5. Removal of chlorine and purification of water: Ozone oxidizes and breaks down water pollutants such as trichloromethane, benzene, phenol, iron and manganese. In a bath or swimming pool, the water quality improves by killing bacteria, eliminating odors, dissolving toxins and purifying the water.

6. Beauty &idigr; When cleansing the body, ozone water removes inflammation, kills bacteria, bleaches, dissolves toxins, removes pimples, spots and freckles, thus beautifying and revitalizing the skin,

7. Health Care: When ozone is used in body cleansing, ozone water removes inflammation, kills bacteria, dissolves toxins and removes dirt particles from the skin pores, leaving the skin spotlessly clean and able to breathe oxygen. This purifies the blood, vitalizes cells and promotes blood circulation and metabolism.

Other effects of ozone in the air:

1. Ozone effectively kills bacteria in the air, such as coliform bacteria, staphylococci and saliuonella, as well as worms, mold and fi-1 trable viruses.

2, Elimination of bad odors: Ozone effectively eliminates bad odors such as those produced in pet shops, chicken farms, pig farms and fish markets, as well as bad odors in hospitals, sanatoriums, refrigerators, wardrobes, shoe cabinets, toilets, bathrooms and basements.

3. Removal of poisons: Ozone removes all kinds of poisonous gases such as carbon monoxide, sulfides, nitrogen hydrides, exhaust gases, ammonia and benzene.

4. Keeping vegetables and fruit fresh: Ozone protects food from spoiling, prevents the proliferation of mold, cocci and coliform bacteria,

extends the shelf life of food and keeps food and fruit fresh.

5. Increased oxygen supply, beauty and hair care: Under normal conditions at room temperature, ozone molecules (O ₃ ) break down in a short time and form oxygen molecules. Therefore, when ozone comes into contact with the human skin surface in a suitable concentration, it removes dirt particles from skin pores through the oxidizing effect of its oxygen constituents. At the same time, the oxygen supply for the skin's respiration is increased. This promotes metabolism and blood circulation, and the cells are vitalized for health and beauty. When ozone is used for hair care, the scalp breathes oxygen, the cells are vitalized, the hair roots absorb oxygen, and the hair tips are strengthened. The hair thus retains its color and elasticity. This effect is achieved by washing the hair and treating the hair and scalp with ozone for 3-5 minutes.

6. Health care j Inhaling ozone in a low concentration gives a feeling of freshness and increases the oxygen content of the blood, so that cells are vitalized, metabolism is promoted and fatigue disappears. Insomnia, headaches, chronic bronchitis and catarrh are also quickly and effectively combated.

7. Air purification; Ozone eliminates cigarette smoke, musty smell, stench, flying mold, dysentery and tuberculosis bacteria. At the same time, ozone in low concentrations eliminates fatigue and purifies the air.

Despite these advantages, ozone is mainly used in industry and healthcare due to the difficulty of producing it. Only in recent years have ozone generators been released for household use.

There are also many air purifiers on the market that clean the air by electrostatic precipitation of dirt particles. They generate ions with electrical discharges in the air. During operation, the air in the room continuously passes through an electrostatic filter so that dirt particles are effectively removed. Many devices also generate ozone to assist in air purification.

Conventional air treatment devices are mostly pure ozone generators or pure anion generators, not a combination of the two.

Common household ozone generators are usually used to clean the air in a room. In practice, however, there are often small, enclosed spaces in a household, such as shoe, wardrobe or refrigerator closets, in which an ozone generator can be used to advantage to kill bacteria, combat musty smells and remove toxins. Conventional ozone generators, however, cannot normally be used in small rooms for these purposes.

Some air purifiers produce ozone and anions at the same time, so you don't have to buy two devices for producing ozone and anions. In such air purifiers, the ozone generator has an outlet that is separate from the outlet of the anion generator. This allows ozone to be produced separately and fed into a small room via a separate hose to effectively kill bacteria, eliminate odors, or purify water and remove insecticides from vegetables and fruit.

In such air purifiers, however, the ozone outlet pressure is

very high {typically 0.5 - 0.9 kp/cm ² . Therefore, ozone is emitted in a high concentration and does not spread easily. The specific density of ozone is 1.7 times the specific density of oxygen. As a result, the emitted ozone sinks to the ground immediately and spreads only slowly. The ozone concentration is therefore too high near the ozone outlet, and people who inhale too much ozone feel dizzy.

Conventional household ozone generators usually work with a gas discharge in which ozone is formed from oxygen in the air. However, due to the limited volume between the electrodes of the discharge, too little ozone is produced to effectively kill bacteria or eliminate odors. After prolonged use, dust, moisture and grease impair the production of ozone.

The main aim of the present invention is to create a multifunctional ozone and anion generator with separate outputs for ozone and anions and a common output for ozone and anions.

Another object of the present invention is to provide a multifunctional ozone and anion generator that evenly distributes ozone in the room to prevent people from inhaling ozone of too high a concentration and to effectively kill bacteria or eliminate odor.

Another aim of the present invention is to create a multifunctional ozone and anion generator to increase the oxygen supply for beauty

··· ···· ·· ·* *· *■
health and hair care.

Another object of the present invention is to provide a multifunctional ozone and anion generator with increased production capacity and downtime operation.

Further advantages, features and possible applications of the present invention will become apparent from the following description of embodiments in conjunction with the drawings.

Fig. 1 is a three-dimensional view of the device

of the present invention.
15

Fig. 2 is a three-dimensional exploded view

of the present invention,

Fig. 3 is a sectional view of the present invention taken along line B-B' in Fig. 1.

Fig. 4 is an enlarged sectional view of the ozone output distributor of the present invention,

Fig. 5 and 6 are schematic views of the movement

of the ozone output manifold of the present invention.

Fig. 7 is a side sectional view of the ozone generating device of the present invention

dung,

Fig. 8 is a cross-sectional view of the ozone generating device of the present invention taken along line C-C in Fig. 7.

Fig. 9 is a three-dimensional view of the hair care cap of the present invention.

Fig. 10 is a three-dimensional view of the gas distribution system of the hair care cap of

present invention.

Fig. 11 is a schematic view of an embodiment of the hair care cap of the present invention,

Fig. 12 is a circuit diagram of the high voltage high frequency generator of the present invention,
15

Fig. 1 and 2 show the housing system of the multifunctional ozone and anion generator of the present invention. It has a housing 10 with a foot 11 on the bottom thereof, whereby the housing 10 stands vertically.

There is a collecting grille 12 and 13 on the front and back of the housing 10. An inlet grille 14 and 15 is attached to the outside of the collecting grilles 12 and 13. Between each collecting grille and inlet grille there is a filter unit 16 and 17, which is made up of a fiber layer, an activated carbon layer and an electrostatic layer. This mechanically, chemically and electrostatically retains harmful particles and chemical substances that are in the air sucked into the device.

An outlet grille 18 is mounted on the top of the housing 10, through which treated air is released into the open air.

A fan 20 is installed near the exhaust grille in the housing 10. The fan rotors 21 rotate by the drive of a motor 22. The space between the fan 20 and the exhaust grille 18 is formed as an exhaust duct 30. A plurality of discharge seats 31 protrude into the exhaust duct.

In operation, the fan 20 draws in ambient air through the inlet grilles 14 and 15 and the filters 16 and 17, as shown in Figs. 1 and 4. The drawn-in air flows through the interior of the housing 10 to the outlet duct 30. As the air flows through the outlet duct 30, the electric field at the charged discharge tips induces negative electric charges in the passing air. The air finally leaves the housing 10 through the outlet grille 18 and returns to the environment.

Continuous operation of the fan 20 ensures that the ionized air is drawn back into the interior of the housing 10 in a circuit. When drawn back in, the ionized air comes into contact with the positively charged filters 16 and 17, the positive charge being induced by the collector grids 12 and 13. The collector grids are electrically connected to the circuit of the device of the present invention and carry a positive charge. The filters 16 and 17 are in mechanical contact with the collector grids 16 and 17, respectively. As a result, the filters 16 and 17 precipitate electrostatically negatively charged particles that pass through. Harmful chemical substances in the air are absorbed by the activated carbon layers of the filters 16 and 17. In this way, the filters 16 and 17 have a mechanical, chemical and electrostatic filtering effect at the same time.

* 9

The ability of the present invention to generate ozone is achieved by an ozone generating device 50. As shown in Figs. 2 and 3, a gas pump 40 is installed in the housing 10. The gas pump 40 draws air in through an air inlet and expels air through a pump outlet line 41. The pump outlet line 41 is connected to the ozone generating device 50. A filter 42 is inserted in the pump outlet line 41 to remove moisture, dust and grease from the air before it enters the ozone generating device 50 to ensure its operation. The air pressure generated by the gas pump is typically 0.1 - 0.9 kgf/cm ² . Once air has entered the ozone generating device 50, it is exposed to an electric field inside an ozone mixing chamber and oxygen is decomposed to form ozone. The mixture of air and ozone is then passed through an ozone outlet line 51 into an ozone distributor 60.

The most important feature of the present invention is that the ozone distributor 60 selectively directs the ozone gas either into the outlet duct 30 where it mixes with ionized air or into a separate ozone outlet 70 mounted on the housing 10.

When set to flow ozone through the ozone outlet 70, the ozone is supplied through an extension hose 71 connected to the ozone outlet 70 into an enclosed space or into water to kill bacteria therein, eliminate odor, purify water, or remove insecticides from vegetables and fruits. In addition, ozone can also be supplied into a hair care cap worn by the user to increase oxygen supply for beauty and hair care.

As shown in Figs. 3 and 4, the ozone distributor 60 includes a three-way valve 61 attached to the housing 10. The three-way valve 61 is provided with an inlet 62 connected to the ozone outlet line 51, a first outlet 63 connected to the outlet channel 30 via a line 64, and a second outlet 65 connected to the ozone outlet 70 on the housing 10 via a line 66. A spindle 67 is rotatably fitted into the three-way valve 61 to selectively switch between the first outlet 63 and the second outlet 65 as the ozone outlet path. A knob 68 accessible from the outside of the housing 10 is connected to the spindle 67 and is used to rotate it.

As shown in Fig. 4, the inlet 62 has a through-bore 621 through which ozone enters the three-way valve 61. The core axis of the bore 621 coincides with the axis of symmetry of the spindle 67. The bore 621 opens into a gas channel 671 within the spindle 67. The gas channel 671 is drilled into the spindle 67 from the side of the inlet 62 along its longitudinal axis, but not through.

In the first outlet 63 and in the second outlet 65 there are through holes 631 and 651, the core axes of which intersect the axis of symmetry of the spindle 67. The spindle 67 also has two connecting holes 672 and 673 to establish the connection to the holes 631 and 651. The connecting holes 672 and 673 are connected to the gas channel 671. When, as shown in Fig. 5, the user turns the spindle 67 to a position in which the connecting hole 672 is in line with the hole 631, the ozone flows from the pump outlet line 51 through the first outlet 63 and the

Line 64 into the ionized air outlet channel 30, mixes with the ionized air and thus passes outside. As shown in Fig. 6, when the user rotates the spindle 67 to a position in which the connecting hole 673 forms a line with the hole 651, the ozone flows from the pump outlet line 51 through the second outlet 65 and the line 66 and passes outside through the ozone outlet 70.

In addition, two sealing rings 69 are located on the spindle 67 on both sides of the outlets 63 and 65 to seal the gap between the spindle 67 and the body of the three-way valve 61. This prevents ozone from passing through the gap between the spindle 67 and the body of the three-way valve 61.

When the multifunctional ozone and anion generator of the present invention is used to purify the air in a room, the spindle 67 is rotated to a position where the connecting hole 672 is aligned with the hole 631, and ozone gas flows through the pipe 64. The outlet of the pipe 64 is in the ionized air outlet duct 30. There, ozone gas mixes with ionized air and then flows outside at a reduced concentration. The ozone gas is carried along by the air flow of the fan 20. It therefore spreads evenly in the room and does not remain confined to a small volume at a high concentration, so that on the one hand an uncomfortable effect on people is avoided, and on the other hand bacteria are effectively killed and toxins are eliminated throughout the room.

When the ozone generated in the device of this invention is used to kill bacteria in a small room,

To eliminate odor, purify water, or remove insecticides from vegetables and fruits, the three-way valve 61 is set so that ozone flows from the ozone outlet 70. An extension hose 71 is connected to the ozone outlet 70, the free end of which opens into a gas sprinkler head 72. This free end can be inserted into a closet, shoe closet, refrigerator, or other small enclosed space. It can also be immersed in water. Thus, the ozone in a small space is effective in killing bacteria, eliminating stench and musty odors, and oxidizing bacteria and harmful chemical substances under water.

Another feature of the present invention is the generation of a large amount of ozone gas by the ozone generating device 50, compared with conventional ozone generating devices. At the same time, the generation of ozone gas is not affected by dust, moisture or grease in the air.

As shown in Fig. 7 and 8, the ozone generating device 50 has an outer tube 52 and an inner tube 53 concentric with it. Between the outer tube 52 and the inner tube 53 there is a gap 54. Both ends are closed off by end pieces 56a and 56b so that a mixing chamber for gas is formed. A net-like discharge electrode 55 is inserted into the gap 54 and surrounds the inner tube 53. The outer tube 52 is enclosed by an induction electrode 57.

The net-like discharge electrode 55 forms one electrical pole and the induction electrode 57 forms the other pole. Both poles are connected to the terminals W and B of a high-voltage high-frequency generator 80.

closed.

The outer tube 52 and the inner tube 53 are made of heat-resistant, electrically insulating material, e.g., glass or quartz, to withstand the high temperature of an electrical discharge. The outer tube 52 also serves as insulation between the reticulated discharge electrode 55 and the induction electrode 57.

The end pieces 56a and 56b each have an inlet tube 91 and an outlet tube 92, respectively. The inlet tube 91 is connected to the pump outlet line 41 of the gas pump 40 and forms the path through which the compressed air enters the space 54. The outlet tube 92 is connected to the ozone outlet line 51 to allow ozone gas to flow into the ozone distributor 60.

Compressed air that has entered the space 54 mixes with the generated ozone gas through the circular path to the outlet pipe 92. Due to the narrowness of the space 54, the mixing is very effective. Due to the small volume of the mixing chamber and the high gas pressure therein, a large amount of ozone is generated. This arrangement is more effective than one in which the ozone is generated in a comparatively large volume and mixed with the air.

When the high-voltage high-frequency generator 80 is switched on, an electrical discharge occurs between the net-like discharge electrode 55 and the induction electrode 57. After air compressed by the gas pump 40 has passed through the inlet tube 91 into the intermediate space 54, oxygen molecules (O ₂ ) are broken down into oxygen atoms (0) in the electric field, then

Oxygen atoms (0) and oxygen molecules (O ₂ ) react to form ozone molecules (O ₃ ). The ozone molecules flow through the outlet tube 92 into the ozone distributor 60, then, depending on the setting of the ozone distributor 60, they reach the anion outlet channel 30 to serve for air purification in a room, or they reach the ozone outlet 70 for another purpose.

In the exemplary embodiment of the present invention, the induction electrode 57 is made of aluminum or another metal. It has cooling fins for dissipating heat from the ozone generating device 50.

Because the net-like discharge electrode 55, the induction electrode 57, the outer tube 52 and the inner tube 53 are concentrically placed one inside the other, the effective electrode area in the ozone generating device 50 is very large. The outer tube 52 and the inner tube 53 are designed to have a long length so that the compressed air in the space 54 is exposed to the electric discharge by the net-like discharge electrode 55 for a sufficiently long time. Therefore, the ozone generating device 50 generates more ozone gas in a smaller volume compared with conventional ozone generating devices = a larger amount of ozone is emitted, with the success of killing bacteria, eliminating odor, dissolving poisons, purifying water or removing insecticides from vegetables and fruits.

Since the effective electrode surface in the ozone generating device 50 is very large, the function is still guaranteed even if the surface is partially deactivated by dust, moisture or grease. This means that the ozone generating device 50 remains effective even over a long period of time

stable in the production of large amounts of ozone.

Furthermore, an extension line can be connected to the ozone outlet 70, which leads to a hair care cap 73 to increase the oxygen supply for beauty and hair care.

As shown in Fig. 9, the hair care hood 73 comprises: a hood 74 worn by the user and covering his hair; a gas distribution system 75 within the hood 74; and a gas supply line 76 having one end connected to the ozone emitter 70 and the other end connected to the gas distribution system 75.

The ozone that flows out of the ozone outlet 70 is guided under the hood 74 through the gas supply line 76 and the gas distribution system 75. The decomposition of ozone there allows the scalp and hair to breathe oxygen to promote health and beauty.

As shown in Fig. 9, the hood 74 is made of airtight textile material or plastic. Its size fits the head of most users. The hood 74 has an opening 741 into which the user puts his head. At the edge of the opening 741 an elastic band 742 ensures a tight fit of the hood 74 without gas escaping through the opening 741.

On the inside of the hood 74, in the middle, there is a fastening device 77 for fastening the gas distribution system 75 to the hood 74. The fastening device 77 can be implemented in many different ways. Fig. 9 shows a comparatively simple embodiment in which the fastening device 77 consists of two adhesive tapes 771 which are attached to the inside

side of the hood 74, thereby securing the gas distribution system 75 to the hood 74. The two adhesive tapes 771 are attached crosswise and can be repeatedly peeled off and re-attached. When the two adhesive tapes 771 are peeled off, the gas distribution system 75 can be removed from the inside of the hood 74.

The gas distribution system 75 serves to evenly distribute ozone gas inside the hood 74. The gas distribution system 75 in the embodiment of Fig. 10 has a gas ring line 751 that has a plurality of holes 752 for the gas to flow out. The two open ends of the gas ring line 751 are connected to one another by a T-piece 753.

The T-piece 753 consists of three converging tubes. It connects the two open ends of the gas ring line 751 with the gas supply line 76, so that gas from the gas supply line 76 enters the gas ring line 751 and is evenly distributed inside the hood 74 through the holes 752. It should be noted that various designs of the shape of the gas distribution system 75 can be implemented with equal effect to evenly distribute ozone gas inside the hood 74. If the gas distribution system 75 is not used, ozone can also simply be fed into the interior of the hood 74 through the gas supply line 76. Although this method is less effective, it still achieves the goal of beauty and hair care.

The hood 74 also has a hole 743 for the passage of the gas supply line 76. As shown in Fig. 11, the gas supply line 76, after being inserted through the hole 743, is connected at its free end to

connected to the ozone outlet 70.

A suggested use of the hair care cap 73 of the present invention is to put on the hair care cap 73 after washing and drying the hair, turn on the multifunctional ozone and anion generator so that ozone is supplied under the cap 74, and let it operate for about 3-5 minutes. Since inhaling too much ozone causes a feeling of dizziness, and on the other hand, too little ozone concentration has no effect on hair care, the ozone generation rate should be set to about 120-150 mg/hour.

Ozone molecules (O ₃ ) are unstable. At a temperature of 18°C - 30 ^° C they break down into oxygen molecules (O ₂ ) and oxygen atoms (O 2 ) within 10 - 15 seconds. The oxygen atoms (O 2 ) are then reduced to oxygen molecules (O ₃ ). The oxygen atoms (O 3 ) formed during this process have unstable chemical properties with a high reactivity, so that they quickly become effective in killing bacteria and removing dirt particles.

Therefore, when the ozone hair care cap of the present invention is used for hair care, dirt particles are removed from the pores of the scalp, the hair roots absorb oxygen, and the hair tips are strengthened. The hair thus retains its color and elasticity. At the same time, the scalp breathes oxygen, the cells are vitalized, blood circulation is promoted, and a feeling of relief and refreshment is created.

As shown in Fig. 12, the high voltage high

frequency generator 80 of the present invention has as its essential components a transistor Q1, which oscillates at a high frequency, and a transformer T2. The power supply is standard. The circuit generates a pulsating DC voltage in the range of 10 kV and 25 kHz.

By means of the diode D5 and the capacitor C7 on the secondary side of the transformer T2, the high-frequency oscillations are converted into pulses of positive charge, which are taken from the terminal W. By means of the diode D6 and the capacitor C6, the high-frequency oscillations are converted into pulses of negative charge, which are taken from the terminal B. Pole 58 is connected to the terminal W and pole 59 to the terminal B. This supplies the ozone generating device 50 with high voltage for the generation of ozone gas.

The ozone gas pressure generated by the apparatus of the present invention is 0.5 - 0.9 kgf/cm ² . It is determined by the output pressure of the gas pump 40. The ozone generation rate of the apparatus of the present invention is 0 - 750 mg/hr. By means of a variable resistor VR8 in the high voltage high frequency generator 80, its output frequency is adjusted, whereby the ozone generation rate can be determined according to the application. A rotary knob 82 is used to adjust the variable resistor VR8.

The multifunctional ozone and anion generator of the present invention can be operated to generate only ozone gas for killing bacteria, dissolving toxins, eliminating odors, purifying water, keeping vegetables and fruits fresh, and for beauty and hair care.

It can also be operated in such a way that it only produces anions.

to purify the air, or it can be operated to produce a mixture of ozone gas and anions to kill bacteria, eliminate odors and purify the air in a room. The present invention thus combines three modes of operation in one device, which is a great advantage in terms of functionality.

Claims (16)

PROTECTION CLAIMS 1. A multifunctional ozone and anion generator, comprising: a housing provided with at least one air inlet and at least one air outlet duct? a filter unit attached to the air inlet and having at least one electrostatic filter and a dust filter? a fan mounted within the housing and forcing air through the air outlet duct, and at least one anion generating device located in the air outlet duct and generating an ionizing electric field so that air passing through the air outlet duct carries anions with it? an ozone generation system for producing ozone? and
a distribution device which selectively directs ozone generated by the ozone generation system either through an ozone outlet attached to the enclosure or into the air outlet duct so that the ozone mixes with ionized air and is then discharged to the exterior of the enclosure. 2. A multifunctional ozone and anion generator according to claim 1, wherein the distribution device further comprises; a three-way tap? an inlet connected to the ozone generation system to direct ozone into the interior of the three-way valve? a spindle which is rotatably inserted into the three-way valve and whose interior has a gas channel which is connected to the inlet? a first outlet attached to the three-way valve and connected to the air outlet channel via a line; a second outlet attached to the three-way valve and connected to the ozone outlet; „ and at least one connecting hole in the spindle, which is connected to the gas channel and, by rotating the spindle, is aligned with either the first outlet or the second outlet, so that ozone flows out of the gas channel either through the first outlet or the second outlet, as desired, 3, A multifunctional ozone and anion generator according to claim 1, wherein the ozone generating system further comprises;
a gas pump;
an ozone generating device, further comprising: an outer tube made of heat-resistant material; an inner tube which is mounted concentrically within the outer tube, whereby between the inner and outer tubes a space is left; a first end piece sealingly mounted to one end of the inner and outer tubes and connected to the gas pump for directing air compressed by the gas pump into to guide the space between the inner and outer tubes; a second end piece, which is sealingly mounted on the other end of the inner and outer tubes and which is connected to the three-way valve. ♦"♦. is connected to direct ozone generated by the ozone generating device into the three-way valve; a net-like discharge electrode which is inserted into the gap and the inner , tube surrounds; and an induction electrode surrounding the outer tube; and a high-voltage, high-frequency generator to which the reticulated discharge electrode and the induction electrode are connected and which generates high-voltage, high-frequency pulses which cause discharges between the reticulated discharge electrode and the induction electrode; wherein, after compressed air discharged by the gas pump has entered the space, a reaction in the electric field between the electrodes generates ozone which is discharged through the second end piece, 4. A multifunctional ozone and enion generator according to claim 3, wherein the induction electrode is provided with a plurality of cooling fins. 5. A multifunctional ozone and anion generator according to claim 1, further comprising: a hair care cap, further comprising: a hood that fits over the user’s head is set up? a gas supply line, one end of which connected to the ozone outlet and whose other end leads into the interior of the hood so that ozone can flow into the interior of the hood; and a gas distribution system installed inside the hood and connected to the gas supply line ₇ to distribute ozone evenly inside the hood; , whereby the combination of the parts allows the user's hair roots to breathe oxygen, strengthens the hair ends, removes dirt particles from the hair pores and thus promotes beauty and hair care, 6. A hair care cap according to claim 5, wherein the gas distribution system comprises an annular gas line connected to the gas supply line and a plurality of holes for the outflow of gas. 7. An ozone generation system for use in a multifunctional ozone and anion generator, comprising: an outer tube made of heat-resistant material;
an inner tube disposed concentrically within the outer tube, with a space left between the inner and outer tubes, the inner and outer tubes being sealingly connected at both ends to form a sealed mixing chamber; an inlet attached to one end of the inner and outer tubes and connected to the gas pump for supplying compressed air into the space between the inner and outer tubes; an outlet attached to the other end of the inner and outer tubes for directing ozone generated by the ozone generation system to the outside; 1 · · 9
» ■ * a net-like discharge electrode, which is inserted into the space and surrounds the inner tube; and an induction electrode surrounding the outer tube; and , a high-voltage, high-frequency generator to which the reticulated discharge electrode and the induction electrode are connected and which generates high-voltage pulses of high frequency which cause discharges between the reticulated discharge electrode and the induction electrode; where, after the grain discharged by the gas pump W primed air has entered the gap, a reaction in the electric field between the electrodes produces ozone, which is discharged through the outlet. 8. An ozone generating system according to claim 7, wherein the induction electrode is provided with a plurality of is provided with cooling fins. 9. An ozone generating system according to claim 7, further comprising a gas pump for compressing air and for supplying compressed air through the inlet into the space between the inner and outer tubes. 10. An ozone generating system according to claim 9, wherein a filter is installed between the gas pump and the inner and outer tubes to filter out moisture, dust and grease. 11. An ozone generation system for use in an ozone generator, the ozone generator being provided with at least one air outlet channel for outlet treatment. purified air and an ozone generation system for generating ozone, comprising:
an ozone outlet attached to the ozone generator; and a three-way tap, further comprising: an inlet connected to the ozone generation system for supplying ozone to the interior of the three-way valve; a spindle that rotates into the three-way valve and whose interior has a gas channel connected to the inlet? a first outlet, which is attached to the three-way valve and is connected via a line to the air exhaust channel; a second outlet attached to the three-way valve and connected to the ozone outlet? at least one connecting hole in the spindle which is connected to the gas channel and is aligned with either the first outlet or the second outlet by rotating the spindle, so that ozone can be discharged from the gas channel either through the first outlet or the second outlet;
wherein ozone generated by the ozone generation system is selectively directed either through the ozone outlet or into the air outlet duct to mix with air and then be discharged to the exterior of the ozone generator. 12. An ozone generation system according to claim 11, wherein an extension line is connected to the ozone outlet for supplying ozone to a separate 25 •5 enclosed space or into water. 13. An ozone generating system according to claim 11, wherein two sealing rings are pulled onto the spindle on both sides of the connecting bore to seal the gap between the spindle and the body of the three-way valve. 14. An oxygen hair care cap comprising: a hood that is placed on the user’s head; and a gas supply line, one end of which leads into the interior of the hood so that ozone can flow into the interior of the hood; The combination of parts allows the user's hair roots to breathe oxygen, strengthens the hair ends, removes dirt particles from the hair pores and thus promotes beauty and hair care. 15. An oxygen hair care hood according to claim 14, further comprising a gas distribution system installed inside the hood and connected to the gas supply line for evenly distributing ozone inside the hood. 16. A hair care cap according to claim 15, wherein the gas distribution system comprises an annular gas line connected to the gas supply line and a plurality of holes for the outflow of gas.