DE102020007210A1 - Air disinfection device with a vertical flow mechanism for sterilizing the air and preventing horizontal flows at medium room height indoors - Google Patents

Abstract

Multi-person offices, event rooms, classrooms, etc., which are not equipped with air conditioning systems, cannot meet today's requirements for indoor air quality with regard to air disinfection. Ventilation systems with air outlets in the ceiling or floor, which are equipped with appropriate filters and UV lamps for disinfection, are based on the most homogeneous possible exchange of air masses, which lead to horizontal air currents at head height and mixing in the room. As a result, while air quality is improved, the risk of pathogens spreading from person to person is increased. Even decentralized air sterilizers with UV lamps or filters cannot sufficiently reduce the risk of transmission of pathogens through air movements between several people in closed rooms. The invention relates to an air disinfection device that can be retrofitted in rooms, which uses UV-C light (1) room air in a Circulatory system in the room sterilized and disinfected, creating a zoning disinfection system to create a protective and disinfecting personal air circuit. Due to the vertical alignment of the device and the air inlets (3) and air outlets (4) close to the floor and ceiling with adjustable nozzles or other air throwing or air guiding elements (5) in the air outlet (4), the air can be directed to the floor or to the ceiling Apply the ceiling with an impulse adjustable by a blower (2) so that the reversal point of the horizontal flow into the vertical flow can be set to suit the room situation. This avoids the usual horizontal air currents at head height.

Description

The invention relates to an air disinfection device with a vertical flow mechanism for sterilizing the air and for preventing horizontal flows at medium room height indoors according to the preamble of claim 1.

Through the pamphlet U.S. 6,939,397 B2 a UV-C based air sterilizer for indoor use is known. Similar products available on the market can be placed anywhere in the room and, with air volume flows of approx. 50-200 m ³ /h, are suitable for rooms with individual use with an area of approx. 15 m ² . Due to the low air velocities in the outlet and the function based purely on air circulation, such devices are only suitable to a limited extent for the disinfection of room air with pathogenic viruses and bacteria. The ejected air mixes with the room air and leads to horizontal air mixing at head height of people who are sitting or standing, so that if there are several people in the room, the risk of transmission of pathogens between these people is even increased.

Central air conditioning systems can be equipped with appropriate hygiene modules such as filters and UV lamps for air purification and disinfection. However, such systems can only be retrofitted in existing buildings with considerable effort and, in open rooms with several people, carry the risk of horizontal air currents forming between the people, which lead to the transmission of diseases, due to the air ducting using ceiling or floor outlets.

In office buildings in particular, adequate thermal and hygienic conditioning of the indoor air is a major challenge due to the increasing surface area density. Because of the well-known problems with pathogens, especially indoors in the winter months, especially in hospitals and medical practices, but also in offices, event rooms and classrooms as well as with the Occurrence of pathogens that are new to humans, the disinfection of indoor air is becoming increasingly important. Only a protective mechanism against the usual horizontal air currents generated by a vertical flow, ideally in combination with vertical control elements, enables the safe disinfection of the indoor air. The risk of disease transmission between people in the room is significantly reduced by horizontal air currents that may be contaminated with pathogens.

According to the current state of the art, neither decentralized air sterilizers with UV lamps or filters (cf. 1a) , 1b) ) nor central air conditioning systems with additional hygiene modules can sufficiently reduce the risk of transmission of pathogens through air movements between several people in closed rooms.

Conventional window ventilation is due to the low air exchange rates and predominantly horizontal air flows (cf. 2a) , 2 B) ) does not adequately reduce the risk of transmission of pathogens between individuals.

The disinfection device according to the invention with the features of claim 1 pursues the purpose of preventing the usual transmission of bacteria and viruses between people who are together in rooms or in room zones by a specifically adjusted air flow in connection with an additional air disinfection. The disinfection device for disinfecting air that may be contaminated with pathogens includes a blow-out system at the bottom and an extraction system at the top, as well as an additional air disinfection unit with UV-C light.

The device can be configured with nozzles or other air throwing or air guiding elements and an adjustable fan overpressure in such a way that the blown air is thrown close to the floor to the relevant workplaces. The low-density air flowing close to the ground, which has been heated by the irradiation with UV-C light compared to the room air, rises along the flow path at the reversal point after momentum has been lost, at which the air mass loses its horizontal momentum. This inevitably leads to a vertical flow in a precisely adjustable range. The aerosols and pathogens emitted by the people in the area of the reversal point are transported away to the disinfection device near the ceiling via the vertical flow. At the same time, the vertical flow effectively prevents the usual spatial horizontal flows at head height between the people in the room. By extracting the air through the element close to the ceiling, it enters the return circuit of the device for renewed disinfection, so that an adjustable, zoning disinfection system is created to create an air circuit that is both protective and sterilizing.

The element is designed as a compact component in such a way that it can either be attached to a wall or positioned freely in the room. In this way, a spatially and fluidically separating system can be used to achieve significantly improved infection protection against viruses and bacteria for group and team workplaces as well as other indoor applications with several people can be achieved.

A high, concentrated radiation intensity can be applied to the air through the flat flow channel (typically 50-300 mm) using germicidal lighting, such as UV-C light from LED or mercury lamps. The flow rate, which can be adjusted using the controllable blower, enables the exposure time of the UV-C radiation to be set in a targeted manner. The number of tubes in the flow channel can be selected to match the size of the room, the room occupancy and the required volume flow.

According to the invention, the object described above is achieved by the features specified in claim 1. Advantageous developments of the invention are specified in the subclaims.

The sectional drawing in 3 illustrates the structure and the mode of operation of the disinfection device according to the invention with the internal air duct listed according to claim 1, with one or more sterilizing lamps (1), an internal blower (2) and nozzles or other air throwing or air guiding elements (5) in the air ejection (4 ). The room air is drawn in by the fan (2) through the inlet ducts near the ceiling (3), cleaned in the disinfection unit and finally blown back into the room through the exhaust ducts (4) near the floor. All components of the disinfection device, in particular the blower (2), are designed so flat that the entire element does not exceed the thickness of a conventional system partition of approx. 80-300 mm. The housing consists of the intake and exhaust ducts (3, 4), in which optional silencers (6) and all other components of the device are integrated. This arrangement creates a compact component that can either be positioned in the room as a vertical room divider and flow-guiding element or attached to a wall.

4a) and 4b) show embodiments of the room disinfection device in which the air can be ejected on both sides. Such a design can be particularly advantageously combined with room-high, transparent or translucent elements in offices, which largely maintain the open structure, but specifically interrupt the airflow between the workplaces and allow decentralized, workplace-related disinfection of the air. By creating workplace-related supply and exhaust air zones with disinfected air using the dividing elements and the formation of personal vertical flows, the risk of pathogens spreading between workplaces can be significantly improved compared to the prior art.

Embodiments of the disinfection device as a sound absorber and sound screen with an absorbent surface are particularly advantageous indoors, because in this case the acoustic comfort of the room increases or the space requirement does not increase through the use of the disinfection devices, since no other absorbent surfaces have to be provided. Especially in multi-person offices, the noise level and the low level of acoustic privacy contribute to employee dissatisfaction and health risks. Without the acoustic design of the disinfection devices, the acoustic conditioning in other room positions could even accommodate fewer users in the same area, which would reduce the profitability of the property.

The large-area, internal silencers (6), which greatly dampen the flow noise in the air duct as well as the fan noise, and the encapsulation of mechanical components, result in low noise emission levels despite high volume flows, so that the device meets the acoustic comfort requirements for interior spaces. The silencers can be designed in different ways (for example as flat, porous absorber mats made of mineral wool or polyester wool).

A personal air flow adapted to the room conditions can be adjusted by appropriate nozzles or other air throwing or air guiding elements (5). The impulse required for the desired range can be controlled by the size and positioning of the nozzles and/or air guide elements (5) and the speed of the fan (2). 5a) and 5b) show two workplace constellations with different throw distance and direction requirements for a two-person office. 6a) and 6b) show comparable workplace constellations in which the embodiment of the room disinfection device with air ejection on both sides is used.

7a) and 7b) show exemplary floor plans of multi-person offices. The typical 4-person workplaces are separated by a central corridor, which creates 2-person workplaces with comparable space requirements. If these workplaces are now zoned by room disinfection devices according to the invention in combination with sound screens (e.g. glass, acoustic absorbers, sheet metal), which are arranged perpendicular to a room boundary surface, the room disinfection devices generate each workplace has a separate personal disinfection air circuit.

8a) and 8b) show photos from a room climate test stand, in which a prototype of the room disinfection device was tested at typical room temperatures at a distance of 1-2 m from the workplace to the disinfection device ( 8a) ) and secondly at a distance of 3-4 m ( 8b) ) is operated. The air is applied from the air outlet through the air nozzles to the floor and in the configured distance rises predominantly vertically to the ceiling, where it is reintroduced via the air inlet of the room disinfection device. The room flow distribution shown, of the air cleaned by the room disinfection device, is achieved by positioning the device perpendicular to a room boundary surface.

Other advantageous versions of the disinfection device include equipping the device with an air filter (8) in the air duct and connecting the device to a fresh air supply.

By integrating the controller for the blower (2) into a building automation system, periods with increased radiation intensity and periods with an increased air exchange rate can be derived to match the room occupancy (room booking or presence sensor). In addition, the air exchange rate can be controlled depending on the measured CO ₂ values.

The room can be additionally cooled in summer and heated in winter by optional conditioning (cooling/heating) of the air by a heat exchanger (9) or cooling meanders to temperatures below/above room temperature. In a cooling application, a design is advantageous in which the air is ejected towards the ceiling and the air is sucked in at the floor. With appropriately cooled air, it will repel itself from the room air and flow horizontally along the ceiling due to the momentum (Coanda effect) until it loses its momentum and sinks. This avoids undefined mixing of the fresh air with turbulence in the area of several people.

A heat exchanger (9) can also be used to cool the UV-C lamps and to prevent the fresh air from being heated by the waste heat from the UV-C lamps in the flow channel.

The wall element promises low operating and maintenance costs. It can be installed anywhere and flexibly without requiring additional space, particularly inexpensive but above all integrated into sound screens or system walls. It can be connected to central ventilation systems, also with the addition of fresh air, provided the building is equipped with the appropriate building services systems. Subsequent installation after a further densification of the workplaces is also easily possible, whereby the advantage of the embodiment with ejection on both sides can come into play here, since fewer elements are required for cleaning the room air.

Reference List

1.

UV lamp disinfection unit

2.

fan

3.

air intake duct

4.

air outlet channel

5.

Air throw or air guiding elements (nozzles)

6.

silencer

7.

sound absorber

8th.

air filter

9.

Heat exchanger (air/water)

10

floor

11.

ceiling

12.

Disinfection device according to the invention

13.

System wall (glass element)

14

sideboard

15

exhaled air

16

Decentralized air sterilizer

17

warm air flow

18

fresh air

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited 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

• US 6939397 B2 [0002]

Claims (8)

Disinfection device with a vertical flow mechanism for sterilizing the air and for preventing horizontal flows at medium room height indoors , characterized in that a) the air in the device is guided past a sterilizing lamp (UV light) in an air duct, b) by an internal fan of the required volume flow, the overpressure in the air ejection and the air speed can be adjusted, c) the direction of the air ejection through nozzles or air-guiding elements can be adjusted depending on the situation, d) the disinfected air is blown out close to the floor and sucked off close to the ceiling. Disinfection device according to the aforementioned claim, characterized in that the device is designed as a room divider in combination with room-high system elements (e.g. glass, sheet metal, wood). Disinfection device according to one of the preceding claims, characterized in that the device is positioned transversely to a space-defining surface. Disinfection device according to one of the preceding claims, characterized in that the device has two separate air inlets and outlets and air-carrying channels. Disinfection device according to one of the preceding claims, characterized in that the blower can be mounted rotated by 180° in order to swap the air inlets and outlets. Disinfection device according to one of the preceding claims, characterized in that the device contains a heat exchanger. Disinfection device according to one of the preceding claims, characterized in that the internal air ducts are lined with absorbent material for soundproofing. Disinfection device according to one of the preceding claims, characterized in that the surface of the device is covered with sound-absorbing elements and the device can thus function as a sound absorber and sound screen.

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