DE202020106640U1 - Ozone sterilizer with air regeneration - Google Patents

Abstract

Ozone sterilizer with air regeneration, consisting of a housing (1), an air blower (3) at least one suction inlet (4) and a discharge outlet (10), a dust filter (5), an electrostatic filter (6), a UV emitter (7) , a catalytic filter (8), a gas filter (9), a switching flap (16) with servo drive (11), a sensor (15) of the regulated air, a display element (13), an operating control unit (12) connected to the power supply Inlet (17) and a router (14) for remote management, characterized in that a fan (3) is mounted in an airtight housing, which is electrically connected to the operating control unit (12) and the display element (13) that is below of the inlet part of the fan (3) in the housing (1) above the electric filter (6) at least one ultraviolet emitter (7) is attached and below the electric filter (6) behind at least one of the suction inlets (4) a dust filter (5) is arranged, that in the outlet part of the fan (3) in the housing (1) behind at least one discharge outlet (10), the sensor (15) and the gas filter (9) there is a catalytic filter (8) with a switching flap (16) with servo drive (11) is installed, and that the sensor (15) is electrically connected separately to the fan (3), the electrostatic filter (6), the UV emitter (7) and the servo drive (11) via the operating control unit (12) .

Description

The technical solution concerns ventilation systems for the sterilization of air, the environment and objects with ozone with subsequent automatic regeneration of the air depreciated by ozone by means of sensors, filtration and catalytic reaction.

The polluted atmosphere has a significant impact on public health. It causes a sudden onset of diseases such as cancer, asthma, allergies or irritation, rhinitis, COVID viruses, SARS and MERS. With a person spending up to 70% of their time indoors (in homes, at work, in schools, etc.), atmospheric pollution is a serious threat to human health. The human immune system defends itself when it encounters these harmful elements and produces an excessive amount of white blood cells. As a result, the human body becomes exhausted, and health is endangered. The consequences of an overloaded immune system are usually fatigue, allergies and illnesses. Indoor air pollution is usually caused by large, small, and gaseous particles.

Large particles are transferred indoors, especially on clothing and shoes, or get there through open doors or windows, possibly also through the decomposition of building materials, carpets, clothing and sewn materials. They can also be a by-product of humans, animals, and plants from falling off pieces of dead skin, hair, pollen, etc. They are also found indoors and arise from human activities such as vacuuming, cutting, grinding, cooking, baking, powdering, and the like .

Small particles are sprayed in the form of smoke, pollen, bacteria, viruses, spores, fungi and the like. They are also caused by smoking, cooking, burning wood in the fireplace and fireplace, by candles, etc.

Gas particles are in the air in the form of molecules (formaldehyde, odors, benzenes, phthalates ...) that are carried by the flow of people, changes in temperature or pressure. They arise from the release of materials and from human activity.

Filter devices are known which can filter out coarse impurities when using a filter cloth. However, they cannot filter out live pathogens, very small mechanical particles, and gaseous contaminants.

Other known devices based on activated carbon absorption filters remove harmful gaseous particles from the air, but cannot absorb fine particles and viruses or only inadequately.

Devices are also known that use ultraviolet radiation to destroy living fine particles such as viruses and bacteria in the air and on the surfaces of various objects, but do not affect other large, small and gaseous particles.

Also known are ozone sterilizers which use high electrical voltage to transport the ozone into the interior in order to remove viruses, bacteria and spores from the surfaces of objects. However, since ozone is dangerous above a certain concentration, the area must be ventilated for a long time after use.

Various devices, described below, are also known which combine several of the aforementioned methods.

It is a technical solution according to DE19902825 known, which relates to a reactor for the decomposition of ozone (O ₃ ), the z. B. is formed in photocopiers, UV sterilizers and similar electrical equipment. The solution is also intended to remove O ₃ from room air (e.g. from O ₃ -disinfected pools) by introducing manganese dioxide (MnO ₂ ) and / or lead oxide (PbO ₂ ) and / or a similar catalyst, which is suitable for the catalytic conversion of O ₃ to oxygen (O ₂ ) in air conditioning and ventilation systems. The disadvantage of the technical solution is that mechanical air pollutants and gases cannot be removed from the air.

A well-known technical solution is the patent KR200399653 represents, which is a sterilizer for air purification or air. The air flows through this sterilizer to the outside, through a photocatalytic filter and a UV lamp, for the purpose of its sterilization and removal of odors. When the ozone is absent, the sterilizer sterilizes and purifies the air or the air e.g. B. in a motor vehicle. He is able to use ozone to sterilize the bacteria that adhere to the objects. The sterilizer consists of an ozone generation module with a safety device located on one side of the air outlet, an anion generation module located on the other side of it, and a button unit that electrically connects the ozone generation module and the ozone sensor. It contains a large capacity battery, which can be carried in a vehicle, for example, and a motor-driven fan. The The disadvantage of this technical solution is its structural complexity and the impossibility of removing mechanical impurities and gases from the air.

According to US2005207951 discloses an apparatus for efficiently deodorizing or sterilizing a room contaminated by a virus, bacteria, fungi and the like above a reference value without adversely affecting the human body. The present invention comprises an ozone generation unit that is subjected to ON / OFF control, a control unit for controlling a variety of safety devices that affect the effective control of the ozone concentration in the target room, a functional air filter unit with air purification and residual ozone removal function, and a circulation fan of the air in the Target area. According to the present invention, viruses, bacteria and fungi floating in the air and odors can be removed more efficiently than with a conventional air purifier. The disadvantage of this technical solution is that it does not allow the purification of gases from the air.

Next is according to JP2013188447 In conventional factories of food or similar products, sterilization using organic acids is known in the factory. In such long-term operation, however, resistant bacteria or similar substances as well as dust and bacteria occur in the atmosphere deposited on the air filter, which circulate in the air in the room, whereby such bacteria grow and lead to secondary contamination. An air filter for solid dust particles is built into the sterilizer, which also has a sterilizing effect. Dust and bacteria from the atmosphere settle on the air filter. The settled bacteria are further sterilized by the sterilizing effect of an air filter. The clean air, which is passed through the air filter, is mixed with ozone and sprayed by rotating the outlet opening 360 degrees to sterilize the bacteria and adhesive bacteria in the air. The disadvantage of this technical solution as well is that it does not allow gases to be cleaned from the air.

The common disadvantage of all the above technical solutions is that they do not allow the removal of coarse and fine particles and at the same time do not remove the viruses, bacteria and spores from the air and from the surfaces of materials without the need for ventilation.

These deficiencies are eliminated by an ozone sterilizer with air regeneration according to this technical solution. The ozone sterilizer consists of a housing, an air blower, at least one inlet and outlet, a dust filter, an electrostatic filter, a UV emitter, a catalytic filter, a gas filter, a switching valve with servo drive, a sensor of the regulated air, a display element, an operational control unit with a power inlet and a router for remote management.

The principle of the technical solution is that a fan is mounted in an airtight housing, which is electrically connected to the operating control unit with the inlet connected to the power supply and the display element. Below the inlet part of the fan, at least one ultraviolet emitter is attached in the housing above the electrostatic filter, and a dust filter is arranged below the electrostatic filter behind at least one of the suction inlets. In the outlet part of the fan there is a catalytic filter in the housing behind at least one discharge outlet, a sensor and a gas filter, in which a switching flap with servo drive is installed. The sensor is electrically connected separately to the fan, the electrostatic filter, the UV emitter and the servo drive via the operating control unit.

It is advantageous if the housing is equipped with at least one rotary knob. It is also advantageous if the dust filter is equipped with at least one suction inlet in the form of a block.

At the same time, it is advantageous if the operating control unit with the display element is attached to one side of the housing.

It is also advantageous if the operating control unit is remotely connected to the display element and the router.

It is also advantageous if the housing consists of at least two parts which are coaxially connected to one another in an airtight manner.

It is also advantageous if an additional housing with at least one suction inlet or discharge outlet is mounted on at least one outside of the housing. In this case, an operating control unit with a display element can be attached in the additional housing.

The aim of the technical solution is to remove large and small harmful particles from the indoor air and at the same time viruses, bacteria, spores, etc. from the surfaces with an air-conditioning device and in the shortest possible time intervals without people present and without a necessary ventilation process. At the same time it should be prevented that humans and animals are threatened by residual gases from ozonization.

• 1 einen Ozonsterilisator mit Luftregeneration in einer grundlegenden Ausführungsform in der Axonometrie,
• 2 einen Ozonsterilisator mit Luftregeneration gemäß 1 im Querschnitt,
• 3 die Strömungsrichtung der gereinigten Luft in dem Ozonsterilisator mit Luftregeneration gemäß 2 mit offener Schaltklappe,
• 4 ein Detail des oberen Teils des Ozonsterilisators mit Luftregeneration gemäß 3 mit offener Schaltklappe,
• 5 die Strömungsrichtung der gereinigten Luft in dem Ozonsterilisator mit Luftregeneration gemäß 2 mit geschlossener Schaltklappe,
• 6 ein Detail des oberen Teils des Ozonsterilisators mit Luftregeneration gemäß 5 mit geschlossener Schaltklappe,
• 7 die funktionelle elektrische Luftverteilung eines Ozonsterilisators mit Luftregeneration,
• 8 ein Funktionsdiagramm der Luftreinigungsverteilung eines Ozonsterilisators mit Luftregeneration und
• 9 einen Ozonsterilisator mit Luftregeneration, dessen Gehäuse mit Drehrädern ausgestattet ist und aus zwei Teilen besteht, die luftdicht miteinander koaxial und mit den angebrachten zusätzlichen Gehäusen verbunden sind.

Concrete examples of embodiments of an ozone sterilizer with air regeneration according to the technical solution are given in the accompanying drawings. Show it:

• 1 an ozone sterilizer with air regeneration in a basic embodiment in axonometry,
• 2 an ozone sterilizer with air regeneration according to 1 in cross section,
• 3 the direction of flow of the purified air in the ozone sterilizer with air regeneration according to FIG 2 with open switching flap,
• 4th a detail of the upper part of the ozone sterilizer with air regeneration according to FIG 3 with open switching flap,
• 5 the direction of flow of the purified air in the ozone sterilizer with air regeneration according to FIG 2 with closed switching flap,
• 6th a detail of the upper part of the ozone sterilizer with air regeneration according to FIG 5 with closed switching flap,
• 7th the functional electrical air distribution of an ozone sterilizer with air regeneration,
• 8th a functional diagram of the air cleaning distribution of an ozone sterilizer with air regeneration and
• 9 an ozone sterilizer with air regeneration, the housing of which is equipped with rotating wheels and consists of two parts which are airtightly connected to each other, coaxially and with the attached additional housings.

The drawings, which show the technical solution presented and the examples of a specific embodiment described below, do not in any way restrict the scope of protection specified in the claims, but only explain the essentials of the technical solution.

In the basic version, the technical solution is in the 1 - 6th pictured. The ozone sterilizer with air regeneration in this basic embodiment shown consists of a housing 1 , a radial fan 3 with side suction and an outlet to the top, a suction inlet 4th and an outlet 10 which are closed by an unmarked, commonly used wall grille. Furthermore, the ozone sterilizer consists of a frame-mounted, electrostatic filter 6th , an ultraviolet emitter 7th , e.g. B. formed from a product of the UV-FAN type series, from a catalytic filter 8th , e.g. B. formed from a catalyst based on MnO ₂ + CuO in a frame mesh, a gas filter 9 , e.g. B. formed by activated carbon in the form of pellets with larger dimensions than the mounted mesh openings of the filter, from a remote gas filter in the frame 9 , a switching flap 16 with servo drive 11 , from a combined sensor 15th for temperature, humidity, CO ₂ content and ozone content of the treated air, from a display part 13th , an operation control unit 12 with inlet connected to the power supply 17th , preferably e.g. B. to a standard 230V / 50Hz alternating current and a router for remote management 14th . In the airtight case 1 is a fan 3 mounted according to 9 electrically with an operating control unit 12 and one on the side of the wall of the housing 1 attached display element 13th connected is. It is located below the suction fan 3 in the case 1 a UV emitter 7th and above the electrostatic filter 6th is a dust filter 5 behind the at least one of the suction inlets 4th arranged. In the outlet part of the fan 3 in the case 1 is located behind the discharge outlet 10 , the sensor 15th and the gas filter 9 also a catalytic filter 8th , in which a switching flap 16 with a servo drive 11 is appropriate. According to 9 is the sensor 15th via the operation control unit 12 electrically with the fan 3 , the electrostatic precipitator 6th , the ultraviolet emitter 7th and the servo drive 11 connected.

According to 7th and 8th the ozone sterilizer with air regeneration is put into operation on command of the operating control unit 12 after their connection to the power supply and after mechanical adjustment of their operation by the operating personnel. The ozone sterilizer is started in either one automatic full or one of two shortened air cleaning cycles, which are controlled by control signals from the combined sensor 15th be controlled, ie if the sensor 15th determines that a value in the external environment of an ozone sterilizer with air regeneration is outside the set reference safety concentration, e.g. B. temperature, humidity, CO ₂ content and ozone content.

In the case of a connection in the operating control unit 12 in the automatically complete cleaning cycle according to 2 and 5 to 8th activates the operation control unit 12 by an electrical command (current) simultaneously the fan 3 , the electrostatic filter 6th , the ultraviolet emitter 7th and the servo drive 11 . The servo drive 11 the switching flap works 16 on in the direction of the catalytic filter 8th away - see 5 and 6th . The air is cleaned by sucking the air into the fan 3 through an air inlet 4th and a dust filter 5 which catches the large dirt particles from the cleaned air. The air is then passed through an electrostatic filter 6th cleaned in which the small particles with high electrical voltage are negatively charged and then stick to the grounded tubular frame, the frame preferably being made of stainless steel. The cleaned air then moves through the UV emitter 7th where the next level of virus, bacteria and spore elimination takes place. The air, which has been freed from large and small particles as well as viruses, bacteria and spores, continues to flow through the fan 3 passing them through an oxygen-modifying catalytic filter 8th and a gas filter with activated carbon 9 presses. This removes the gaseous pollutants contained in the air through a mechanically adjustable directed ventilation outlet 10 back to the outside. During the entire filtration cycle, the sensor 15th the values such as temperature, humidity, CO ₂ content and ozone content in the air are measured. The measured values are taken simultaneously from the display element 13th and evaluated with their set reference value in the form of a recommendation from the control program for the operating personnel.

In the case of connection in the control unit 12 to the 1st stage of the shortened automatic cleaning cycle according to 3 , 4th , 7th and 8th , which is only intended for the need to ozonize air and / or surfaces of things, are controlled by means of the operation control unit 12 by electrical command (current) of the fan 3 , the electrostatic filter 6th , the ultraviolet emitter 7th and the servo drive 11 activated simultaneously. The servo drive 11 folds the switching flaps in the direction of the catalytic filter 8th down - see 3 and 4th . The servo drive 11 changes the ventilation path in the ozone sterilizer with air regeneration. The oxygen-containing intake air passes through mechanically adjustable, directional air supply inlets 4th and through the dust filter 5 further where the large particles are in the electrostatic precipitator 6th are recorded. Here, so-called corona discharges are generated by high electrical voltage, which converts oxygen into ozone. Furthermore, the purified air runs in the ozone sterilizer with air regeneration by the ultraviolet emitter 7th , in which another stage of virus, bacteria and spore elimination takes place. The air, which is free of large and small particles including viruses, bacteria and spores, is then passed on via a mechanically adjustable directional ventilation outlet 10 returned to the outside. Temperature, humidity, CO ₂ content and ozone content are measured during the entire oxygen-ozone conversion cycle. The values are from the display element 13th and from the control program in the operating control unit 12 evaluated with a set reference value. On this basis, the air cleaning cycle in the ozone sterilizer continues with the air regeneration until the set reference concentration is reached, which is required for ozonizing the surfaces in the closed space. In order to avoid endangering people and animals from ozone poisoning, this cleaning phase is carried out without their presence. Then the device in the ozone sterilizer with air regeneration automatically switches the air path through the servo drive 11 around by the switching flap 16 towards the catalytic filter 8th tips away and the previously described automatic cleaning cycle according to 1 and 6th to 9 is carried out. After the ozone concentration in the room has been reduced to a specified reference value that does not endanger people or animals, the ozone sterilizer with air regeneration in the control unit 12 switched off.

In the case of connection in the control unit 12 to the 2nd stage of the shortened automatic cleaning cycle according to 3 , 4th , 7th and 8th If, in case of need of quick air cleaning with low elimination of viruses, bacteria and spores, the use of the electrostatic filter 6th is not required, and the so-called corona discharges, which decompose the oxygen to ozone, are generated by high electrical voltage, and the use of the ultraviolet emitter 7th where the next stage of liquidation of viruses, bacteria and spores takes place, are carried out simultaneously by means of the operation control unit 12 by electrical command (current) of the fan 3 and the servo drive 11 actuated. The servo drive 11 folds the switching flaps 16 towards the catalytic filter 8th down- see 3 and 4th . The servo drive 11 changes the ventilation path in the ozone sterilizer with air regeneration. The oxygen-containing intake air passes through mechanically adjustable, directional air supply inlets 4th and through the dust filter 5 further where the large particles are captured. The air is then discharged through a mechanically adjustable directional ventilation outlet 10 returned to the outside. Temperature, humidity, CO ₂ content and ozone content are measured during the entire oxygen-ozone conversion cycle. The values are from the display element 13th and from the control program in the operating control unit 12 evaluated with a set reference value. On this basis, the air cleaning cycle in the ozone sterilizer continues with the air regeneration until the set reference concentration is reached, which is required for ozonizing the surfaces in the closed space. In order to avoid endangering people and animals from ozone poisoning, this cleaning phase is carried out without their presence. Then the device in the ozone sterilizer with air regeneration automatically switches the air path through the servo drive 11 around by the switching flap 16 in the direction of the catalytic filter 8th tips away and the previously described automatic cleaning cycle according to 2 and 5 to 8th is carried out. After the ozone concentration in the room has been reduced to a specified reference value that does not endanger people or animals, the ozone sterilizer is activated with air regeneration in the control unit 12 switched off.

Another embodiment of the technical solution presented in 9 is shown, shows an ozone sterilizer with air regeneration, on the lower part of the housing 1 Turning wheels 2 are mounted and of two airtight coaxially connected parts with the attached additional housings 18th is formed. The internal structure and operation of this ozone sterilizer with air regeneration is identical to its basic embodiment already described.

The described and illustrated embodiments are not the only possible embodiments of the technical solution, since the number of suction points and the housing differ from those shown 1 with a different number of rotating wheels 2 (not shown) and the dust filter 5 with several suction inlets 4th formed in the form of a block. The operational control unit 12 can also use the display element 13th and the router 14th be connected. Alternatively, the operation control unit 12 outside the case 1 in an additional housing 18th to be assembled. The fan 3 may have a different construction, and its discharge part and its switching flap 16 can have different shapes and positions. The central suction pipe of the production machines can also be led directly into the air and the like through an ozone sterilizer with air regeneration.

The ozone sterilizer with air regeneration according to the technical solution can be used in various closed spaces, which are intended for cleaning the air of harmful substances, odors, viruses, bacteria and the like, such as. B. in military buildings and means of transport, in rooms, halls, hospitals, waiting rooms, conference and production halls, offices, schools, in passenger transport, such as. B. in airplanes, ships, trucks and cars, public long-distance and urban transport, etc. This technical solution can also be used to clean the surfaces of objects with ozone and then to remove the harmful substances on their surface, without presence and intervention of people and operating personnel.

List of reference symbols

1 -

Housing (of the ventilation system)

2 -

Rotary wheel

3 -

Fan

4 -

Suction inlet (ventilation)

5 -

Dust filter (G3 / G4 according to EN779 with a frame)

6 -

electrostatic filter

7 -

UV emitter

8th -

catalytic filter (based on MnO ₂ + CuO)

9 -

Gas filter (filter media plate with 100% activated carbon)

10-

Discharge outlet (ventilation)

11 -

Servo drive

12 -

Operation control unit

13 -

Display element

14 -

Router (remote management)

15 -

Sensor (CO ₂ content and ozone content, temperature and humidity)

16 -

Switching flap (ventilation route)

17 -

inlet

18 -

additional housing

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 19902825 [0011]
• KR 200399653 [0012]
• US 2005207951 [0013]
• JP 2013188447 [0014]

Claims (8)

Ozone sterilizer with air regeneration, consisting of a housing (1), an air blower (3) at least one suction inlet (4) and a discharge outlet (10), a dust filter (5), an electrostatic filter (6), a UV emitter (7) , a catalytic filter (8), a gas filter (9), a switching flap (16) with servo drive (11), a sensor (15) of the regulated air, a display element (13), an operating control unit (12) connected to the power supply Inlet (17) and a router (14) for remote management, characterized in that a fan (3) is mounted in an airtight housing, which is electrically connected to the operating control unit (12) and the display element (13) that is below of the inlet part of the fan (3) in the housing (1) above the electric filter (6) at least one ultraviolet emitter (7) is attached and a dust filter (5) is arranged below the electric filter (6) behind at least one of the suction inlets (4) i st that in the outlet part of the fan (3) in the housing (1) behind at least one discharge outlet (10), the sensor (15) and the gas filter (9) there is a catalytic filter (8) with a switching flap (16) with servo drive (11) is installed, and that the sensor (15) is electrically separated from the fan (3), the electrostatic filter (6), the UV emitter (7) and the servo drive (11) via the operating control unit (12) connected is. Ozone sterilizer with air regeneration according to Claim 1 , characterized in that the housing (1) is equipped with at least one rotary wheel (2). Ozone sterilizer with subsequent air regeneration according to Claim 1 , characterized in that the dust filter (5) is equipped with at least one suction inlet (4) in the form of a block. Ozone sterilizer with subsequent air regeneration according to Claim 1 to 3 , characterized in that the operating control unit (12) with the display element (13) is attached to one side of the housing (1). Ozone sterilizer with subsequent air regeneration according to Claim 1 or 2 to 4th , characterized in that the operation control unit (12) is remotely connected to the display element (13) and the router (14). Ozone sterilizer with subsequent air regeneration according to Claim 1 to 5 , characterized in that the housing (1) consists of at least two parts which are airtightly connected to one another coaxially. Ozone sterilizer with subsequent air regeneration according to Claim 1 or 6th , characterized in that an additional housing (18) with at least one suction inlet (4) or one discharge outlet (10) is mounted on at least one outside of the housing (1). Ozone sterilizer with subsequent air regeneration according to Claim 7 , characterized in that an operating control unit (12) with a display element (13) is mounted in at least one additional housing (18).

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