DE202021101450U1 - Floor lamp with UV light source - Google Patents

Abstract

Having floor lamp (2)
- A lamp unit (3) for receiving at least one illuminant (4);
- A stand device (5) which has a body with a cavity (6), an air inlet opening (7) and an air outlet opening (8);
- A UV light source (10) which is arranged between the air inlet opening (7) and the air outlet opening (8) in the cavity (6) and is set up to generate UV radiation and emit it into the cavity (6).

Description

The present invention relates to a floor lamp and a furniture arrangement having a desk and such a floor lamp.

Many pathogens that can lead to infectious diseases spread through the indoor air. It is therefore desirable, for example at private or professional office workplaces, to free the room air from pathogens, i.e. to disinfect the room air.

The disinfecting effect of UV radiation is well known. However, UV radiation has a harmful effect on the human body and can damage the skin and eyes in particular. In addition, dedicated devices are usually used for disinfection, which leads to a corresponding space requirement that is not necessarily guaranteed in various situations.

There are also known lighting devices that use visible violet light with a wavelength of about 405 nm. However, such light is far less efficient than UV radiation for disinfection, so that effective air disinfection is not possible in an energy-efficient manner, especially in larger rooms.

It is an object of the present invention to provide a space-saving concept for disinfecting air by means of UV radiation.

This object is achieved by the respective subject matter of the independent claims. Advantageous developments and preferred embodiments are the subject of the dependent claims.

The invention is based on the idea of integrating a UV light source between an air inlet opening and an air outlet opening in a cavity of a standing device of a floor lamp.

According to the invention, a floor lamp, also referred to as a floor lamp, is specified. The floor lamp contains a lamp unit for receiving at least one illuminant and a stand device, also referred to as a stand device, which has a body with a cavity, an air inlet opening and an air outlet opening. The floor lamp also has a UV light source which is arranged between the air inlet opening and the air outlet opening in the cavity and is set up to generate UV radiation and is arranged to emit it into the cavity.

The at least one lighting means can be set up or configured, for example, to emit visible light. Here and in the following, the term “light” can be understood to include electromagnetic waves in the visible range, in the ultraviolet range and / or in the infrared range. The abbreviation “UV” stands for ultraviolet here and in the following.

Visible light can be understood to mean light with a wavelength of 380 to 780 nm. Light with a wavelength of more than 780 nm is called infrared light, whereas UV radiation, which is also called ultraviolet light, has a wavelength of less than 380 nm. The UV radiation is therefore light with a wavelength of less than 380 nm, for example radiation from the UV-C spectral range, in order to achieve the highest possible disinfection effect.

A floor lamp or floor lamp can be understood to mean a lamp which is set up to be set up on a level surface for ambient lighting.

The visible light can be used for direct and / or indirect room lighting. The lamp unit is arranged outside the cavity, in particular the at least one lighting means is arranged outside the cavity. The cavity and the body with the cavity are therefore in particular not a reflector or the like or a screen for the visible light of the at least one illuminant. In particular, the lamp unit is designed in such a way that the at least one lighting means can generate the visible light outside the cavity and, in particular, does not emit the visible light into the cavity.

The air inlet opening enables air from the area around the floor lamp to flow into the cavity and leave the cavity through the air outlet opening. The direction of flow of the air from the air inlet opening to the air outlet opening can be predetermined by the geometric design of the body with the cavity and in particular by its alignment in the room and / or by an optional ventilator or ventilator. Since the UV light source is located between the air inlet opening and the air outlet opening, the waste heat from the UV light source heats the surrounding air in the cavity during operation. This can lead to a suction effect, which can suck air from the environment into the cavity via the air inlet opening and transport it in the direction of the air outlet opening, where the air can leave the cavity again. This suction effect can be caused by the Fan or fan are supported. The terms fan and fan are used interchangeably here and in the following.

In this way, the ambient air can be disinfected by the action of UV radiation and distributed as evenly as possible in the room. The fact that the UV light source is integrated in the standing device of a standing person, which can also be used to illuminate the surroundings with visible light, results in a particularly space-saving solution, since ambient lighting, for example in the office environment, is required anyway and is often provided by a floor lamp .

By integrating the UV light source in the cavity of the body, which consists in particular of a material that is impermeable or substantially impermeable to UV radiation, the risk of damage to the eyes or skin of people in the vicinity of the floor lamp is also minimized. The standing device can contain, for example, a stand pipe, a standing mast or some other stand for the floor lamp.

In various embodiments, the at least one lighting means can have one or more light-emitting diodes, LEDs.

The UV light source can for example have one or more LEDs for emitting the ultraviolet light and / or one or more gas discharge lamps. The gas discharge lamps can be designed, for example, as low-pressure gas discharge lamps or as medium-pressure gas discharge lamps.

In preferred embodiments, the at least one lighting means, in particular the corresponding emission spectrum, can be controlled as a function of time in order to generate light with a different color spectrum in the course of the day. In this way, particularly ergonomic lighting of the environment, also referred to as Human Centric Lighting, HCL, can be achieved. The natural course of daylight can be simulated over the course of a day by adjusting the white point or the color temperature of the emitted light, for example through variable combinations of several LEDs with different emission spectra. In addition to the spectral adaptation, the illuminance can also be controlled accordingly.

According to at least one embodiment of the floor lamp, the UV light source is designed to emit the UV radiation with a wavelength, in particular a peak wavelength, in a range between 200 nm and 300 nm. The wavelength, in particular the peak wavelength, is preferably less than or equal to 280 nm, for example in a range between 200 nm and 280 nm, in particular between 250 nm and 260 nm or between 210 nm and 230 nm.

The wavelength range below 280 nm is also referred to as the UV-C spectral range. Radiation in this area is very rich in energy and is therefore also referred to as hard UV radiation. Accordingly, such radiation can be used particularly efficiently to inactivate pathogens such as viruses or bacteria.

Using light in the range between 250 and 260 nm has the advantage that UV-C light sources are established for this range and can therefore be obtained relatively inexpensively, in particular light sources with an emission wavelength of 254 nm.

Recent studies show that light in the range between 210 nm and 230 nm, in particular light with a wavelength of 220 nm, is even more efficient in terms of disinfecting effect than light with a wavelength of 254 nm. Radiation with a wavelength of 210 nm to 230 nm is particularly advantageous.

According to at least one embodiment, the floor lamp has an absorption element with a surface that absorbs the UV radiation, the absorption element being arranged in the cavity or on an inner wall of the cavity between the air outlet opening and the UV light source. Alternatively or additionally, the absorption element or a further absorption element can be arranged between the air inlet opening and the UV light source.

The absorption element can for example be made of a material that absorbs the UV radiation or have a corresponding coating that absorbs the UV radiation. By using the absorption element, the risk of escaping UV radiation can be further reduced.

In particular, the absorption element is as close as possible to the air inlet opening and / or a further absorption element is as close as possible to the air outlet opening. In the area of the UV light source, the inner wall of the cavity is preferably free of materials that absorb UV radiation. The resulting interflexion in this area achieves a particularly high disinfection performance.

According to at least one embodiment, at least one lighting means is set up to generate additional visible light and to emit it into the vicinity of the floor lamp, the additional visible light having a wavelength in a range between 380 nm and 420 nm, in particular in a range between 400 nm and 410 nm, for example 405 nm.

The further visible light can be emitted alternatively or simultaneously with the visible light. The other visible light can emit directly or indirectly into the area around the floor lamp, so that additional disinfection of the area, for example a work surface or a desk top, can be achieved without the risk of skin or eye damage.

For example, the at least one light source can contain a first module for generating the visible light and a second module for generating the further visible light.

According to at least one embodiment, at least one lamp is set up to generate further UV radiation and to emit it into the vicinity of the floor lamp, the further UV radiation having a wavelength in a range between 315 nm and 380 nm.

The further UV radiation is therefore in particular UV radiation from the UV-A spectral range. Such radiation can lead to skin aging and damage to the skin. Therefore, the further UV radiation is preferably only generated when there is no person in the radiation area. To ensure this, a time control or a motion sensor can be used, for example. Since the damaging effect of UV-A radiation is considerably less than that of UV-C radiation, this results in a possibly acceptable risk while at the same time improving the disinfection of work surfaces.

For example, the at least one light source can contain a third module for generating the further UV radiation.

According to at least one embodiment, the body has a tubular section and an inner region of the tubular section forms at least part of the cavity.

For example, the stand device can have a tube and part of the tube forms the tubular section. The tube can be designed as a round tube or as a tube with a polygonal, rectangular or square cross-section.

According to at least one embodiment, the cavity or the tubular section has a channel with a constant cross section.

Such tubes or hollow profiles can be manufactured very easily, which can lead to cost savings.

According to at least one embodiment, the cavity has a channel which tapers from the air inlet opening towards the air outlet opening.

The operation of the UV light source dissipates energy that can be given off to the cavity in the form of waste heat. Due to the lower density of the correspondingly heated air, an air flow is created in the duct from the air inlet opening to the air outlet opening.

In embodiments in which the channel is tapered, the cross-sectional area of the channel decreases from the air inlet opening towards the air outlet opening. This reduction in the cross-sectional area can take place continuously in sections or continuously. However, the reduction can also include one or more gradual reductions in the cross-sectional area. Since the mass flow of the air flowing through the channel is independent of the cross-section of the channel, as required by the law of continuity, the tapering of the channel results in an acceleration of the air, i.e. the so-called Venturi effect. This means that the air is accelerated and exits the air outlet opening at a comparatively high speed. As the air exits the standing device at high speed, the disinfected air can be distributed particularly well in the environment.

According to at least one embodiment, the floor lamp has a control device for controlling the at least one illuminant and / or the UV light source. The control device is arranged in the cavity.

The control device can also contain a ballast for the at least one lamp and / or the UV light source. In such embodiments, a particularly space-saving arrangement of the control device is achieved.

According to at least one embodiment, the floor lamp has a fan which is arranged in the cavity and is set up to transport air from the air inlet opening to the air outlet opening.

The fan can in particular also be arranged between the air inlet opening and the air outlet opening. However, another arrangement is also possible, for example on a side of the air inlet opening opposite the UV light source.

The air flow from the air inlet opening to the air outlet opening can be generated or possibly increased by the fan, so that the air throughput can be increased further.

The fan can be designed as a radial fan, for example. A drive axis of the radial fan is in particular perpendicular to a longitudinal direction of the tubular section. By means of the radial fan, air is sucked in essentially parallel to the drive axis, which corresponds, for example, to a motor axis of the radial fan. By rotating an impeller of the radial fan, the air can be deflected by 90 degrees and then blown out in the radial direction with respect to the drive axis.

According to at least one embodiment, the fan is designed as an axial fan. A drive axis of the axial fan is aligned in particular parallel to the longitudinal direction of the tubular section. The axial fan draws in the air parallel to its drive axis. The air is also blown out in the axial direction.

This can be particularly advantageous if the air inlet opening and / or the air outlet opening are formed on the basis of one or more slots in the tubular section. For example, aerosols that are exhaled by a user in the vicinity of the floor lamp can be captured particularly well by the axial fan and transported to the UV radiation through the slotted air inlet opening. The effectiveness and efficiency of air disinfection can thus be increased.

According to at least one embodiment, the stand device has a stand for placing the floor lamp on a flat surface.

The longitudinal direction of the tubular section can be perpendicular or approximately perpendicular to the plane of the flat surface, in particular if the floor lamp is placed with the base on the surface.

In alternative embodiments, the longitudinal direction of the tubular section can enclose an angle with the normal direction of the level ground, the amount of which is less than or equal to 45 degrees, in particular less than or equal to 30 degrees.

A distance of a contact surface of the base from the air inlet opening, i.e. in particular a distance between the flat surface and the air inlet opening, is greater than or equal to 0.5 m in various embodiments, for example greater than or equal to 0.7 m, in particular greater than or equal to 0.8 m The distance corresponds in particular to a distance from the contact surface or the flat surface to a lower edge of the air inlet opening.

The distance between the contact surface and the air inlet opening is limited in particular by a total height of the floor lamp or the standing device and by a minimum distance between the air inlet opening and the air outlet opening.

For example, the distance between the contact surface of the base and the air inlet opening can be less than or equal to 1.3 m, for example less than or equal to 1 m.

In such embodiments, the air inlet opening is arranged approximately at the level of a table top of a desk, so that aerosols exhaled by a user of the desk can be detected and irradiated by the UV radiation. The minimum distance can also reduce the penetration of dust from the area of the floor.

According to the invention, a furniture arrangement having a desk and a floor lamp according to the invention are also specified.

The desk in particular has a table top, a distance between an upper edge of the table top and the contact surface of the base being less than or equal to the distance between the contact surface of the base and the air inlet opening.

In other words, the air inlet opening is above the top edge of the table top. A particularly good recording of the aerosols exhaled by the user can thus be achieved.

If the desk is a table with an adjustable table top height, the distance between the top edge of the table top can, for example, correspond to a distance between the top edge of the table top when the table top is positioned in a lowermost position, i.e. at a minimal distance from the floor is located.

• Fig. eine schematische Darstellung einer Möbelanordnung mit einer erfindungsgemäßen Stehleuchte und einem Schreibtisch.

The invention is explained in more detail below with the aid of specific exemplary embodiments and an associated schematic drawing. It shows:

• FIG. 1 shows a schematic representation of a furniture arrangement with a floor lamp according to the invention and a desk.

In the figure is a furniture arrangement 1 with a desk 3 and a floor lamp according to the invention 2 shown.

The floor lamp 2 has a stand device 5 on, for example, a mast or a standpipe, which is a pipe with a cavity 6th contains. The floor lamp 2 has a UV light source 10 on that in the cavity 6th is arranged. In the z-direction below the UV light source 10 there is an opening in the tube that acts as the air inlet opening 7th serves. In the z-direction above the UV light source 10 there is another opening in the tube, which is used as an air outlet opening 8th serves. The z-direction corresponds in particular to a direction perpendicular to a substrate 13th on which the floor lamp 2 is set up, for example by means of an optional stand 12th the floor lamp 2 .

Through the air inlet opening 7th can air 9 from the area around the floor lamp 2 into the cavity 6th penetrate where they are caused by UV radiation by means of the UV light source 10 is generated, irradiated and can thus be disinfected. The UV light source can in particular emit UV-C radiation, for example with a wavelength of 254 nm or 220 nm. The UV light source 10 can for example be designed to be elongated, with a longitudinal direction of the UV light source 10 approximately the longitudinal direction of the tube of the stand device 5 corresponds to. The UV light source can be designed, for example, as an elongated LED module or as a gas discharge lamp.

In addition, the floor lamp has 2 a lamp unit 3 on, for example at an upper end of the stand device 5 , being in the lamp unit 3 at least one lamp 4th for generating and emitting visible light in the vicinity of the floor lamp 2 , especially in the direction of the desk 3 , contains. So can the desk 3 and / or the area around the floor lamp 2 be illuminated directly and / or indirectly.

A control unit can advantageously 11 , for example a ballast for the at least one lamp 4th or the UV light source 10 , also in the tube of the stand device to save space 5 be arranged.

The airflow from the air inlet opening 7th to the air outlet opening 8th can be achieved by heating the air using the waste heat from the UV light source 10 to get promoted.

Optionally, the floor lamp 2 also a fan, which is also in the cavity 6th is arranged. A higher air speed and thus both a higher air throughput for disinfection and a more homogeneous distribution of the air can be achieved 9 attached to the air outlet 8th from the stand 5 emerges. An advantageous embodiment provides an axial fan in the cavity 6th in front and one or more slots as an air inlet opening 7th .

A table top 14th of the desk 3 , especially a top edge 15th the table top 14th , can for example in the z-direction below the air inlet opening 7th be arranged. In this way, aerosols prepared by a user can effectively enter the cavity 6th be sucked in and thus fed to the disinfection by the UV radiation.

List of reference symbols

1

Furniture arrangement

2

Floor lamp

3

Lamp unit

4th

Bulbs

5

Stand device

6th

cavity

7th

Air inlet opening

8th

Air outlet opening

9

air

10

UV light source

11

Control unit

12th

Stand

13th

Underground

14th

Tabletop

15th

Top edge

Claims (25)

Having floor lamp (2) - A lamp unit (3) for receiving at least one illuminant (4); - A stand device (5) which has a body with a cavity (6), an air inlet opening (7) and an air outlet opening (8); - A UV light source (10) which is arranged between the air inlet opening (7) and the air outlet opening (8) in the cavity (6) and is set up to generate UV radiation and emit it into the cavity (6). Floor lamp (2) Claim 1 wherein the body has a tubular portion, and an inner region of the tubular portion forms at least part of the cavity (6). Floor lamp (2) according to one of the preceding claims, wherein the cavity (6) has a channel with a constant cross section. Floor lamp (2) according to one of the Claims 1 or 2 wherein the cavity (6) has a channel tapering from the air inlet opening (7) to the air outlet opening (8). Floor lamp (2) according to one of the preceding claims, wherein the floor lamp (2) has a control device (11) for controlling the at least one illuminant (4) and / or the UV light source (10), which is arranged in the cavity (6) is. Floor lamp (2) according to one of the preceding claims, wherein the lamp unit (3) contains the at least one lighting means (4). Floor lamp (2) Claim 6 , wherein the at least one lighting means (4) is set up to generate visible light and to emit it directly or indirectly into the surroundings of the floor lamp (2). Floor lamp (2) Claim 7 , wherein the at least one lighting means (4) contains a light-emitting diode. Floor lamp according to one of the Claims 6 to 8th , wherein the at least one lighting means (4) is set up to generate further visible light and to emit it into the surroundings of the floor lamp (2), the further visible light having a wavelength in a range between 380 nm and 420 nm, in particular in a range between 400 nm and 410 nm, for example from 405 nm. Floor lamp according to one of the Claims 6 to 9 , wherein the at least one lighting means (4) is set up to generate further UV radiation and to emit it into the vicinity of the floor lamp (2), the further UV radiation having a wavelength in a range between 315 nm and 380 nm. Floor lamp (2) according to one of the preceding claims, wherein the floor lamp (2) has a fan which is arranged in the cavity (6) and is set up to transport air from the air inlet opening (7) to the air outlet opening (8). Floor lamp (2) Claim 11 , wherein the fan has a radial fan. Floor lamp (2) Claim 12 , wherein a drive axis of the radial fan is aligned perpendicular to a longitudinal direction of the tubular section. Floor lamp (2) Claim 11 , wherein the fan comprises an axial fan. Floor lamp (2) Claim 14 , wherein a drive axis of the axial fan is aligned parallel to a longitudinal direction of the tubular section. Floor lamp (2) according to one of the preceding claims, wherein the tubular section has at least one slot which forms the air inlet opening (7). Floor lamp (2) Claim 16 wherein the at least one slot is parallel to the longitudinal direction. Floor lamp (2) according to one of the preceding claims, the UV light source (10) is designed to emit the UV radiation with a wavelength in a range between 200 nm and 380 nm, in particular with a wavelength less than or equal to 280 nm, for example in a range between 200 nm and 280 nm, in particular between 250 nm and 260 nm or between 210 nm and 230 nm. Floor lamp (2) according to one of the preceding claims, wherein the floor lamp (2) has an absorption element with a surface absorbing the UV radiation, which is located in the cavity (6) or on an inner wall of the cavity (6) between the air outlet opening and the UV -Light source (10) or between the air inlet opening and the UV light source (10) is arranged. Floor lamp (2) according to one of the preceding claims, wherein the UV light source (10) for emitting the UV radiation has one or more LEDs and / or one or more gas discharge lamps. Floor lamp (2) according to one of the preceding claims, wherein the standing device (5) has a stand (12) for placing the floor lamp (2) on a flat surface (13). Floor lamp (2) Claim 21 , the longitudinal direction of the tubular section enclosing an angle with a normal direction (z) of the flat surface (13), the amount of which is less than or equal to 45 °, in particular less than or equal to 30 °. Floor lamp (2) Claim 21 , wherein the longitudinal direction of the tubular section is perpendicular or approximately perpendicular to the flat surface (13). Floor lamp (2) according to one of the Claims 21 to 23 wherein a distance between a contact surface of the foot (12) and the air inlet opening (7) is greater than or equal to 0.5 m, for example greater than or equal to 0.7 m, in particular greater than or equal to 0.8 m. Furniture arrangement (1) comprising a desk (3) with a table top (14) and a floor lamp (2) according to one of the Claims 21 to 24 , wherein a distance of an upper edge (15) of the table top (14) from the contact surface of the base (12) is less than or equal to the distance of the contact surface of the base (12) from the air inlet opening (7).

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