DE102020116262A1 - Device with a surface and a method for disinfecting the surface - Google Patents

Abstract

Touchable device (10) comprising a touchable surface (20) with a frame (15), and a plurality of light sources (30) for radiation of blue, violet or ultraviolet light into the surface (20). The light disinfects the touchable surface (20).

Description

The invention relates to a device with a surface and a method for disinfecting the surface.

It is generally known that the surface of touch-sensitive display devices such as smartphones or tablet computers often contain pathogens and other germs, as Hirsch et al. in the publication "Surface Microbiology of the iPad Tablet Computer and the Potential to Serve as a Fomite in Both Inpatient Practice Settings as Well as Outside of the Hospital Environment" PLOS ONE, October 31, 2014 (available at https://doi.org/ 10.1371 / journal.pone.0111250). The authors report an attempt to remove germs from the display surface with a damp cloth and state that some germs still remain on the surface even after cleaning. They recommend developing strategies to remove the germs and disinfect the display devices.

Pathogens are also known on other surfaces. The Stuttgarter Nachrichten of August 5, 2016, for example, reported on pathogens in public transport (buses, trains and planes) - available at https://www.stuttgarter-nachrichten.de/inhalt.keime-in-oefflichen-verkehrsmittelwenn-das -norovirus-mitfaehre.e77c9733-096a-4109-a836-14c624cd479d.html.

Methods for disinfecting the pane or display surface of a tous screen are disclosed, for example, in US Patent No. 8,999,237 (Turmanov / Microsoft) known. This patent discloses an automatic disinfection method for the touch screen with the following steps: Detection of a so-called “predetermined event” in order to trigger the disinfection of a touch-sensitive screen (touch screen); Activating a UV light source, which is located on an edge of a transparent film material with a thickness of less than 1 mm, which covers a display surface of the touchscreen; and radiating UV light through the transparent film material to disinfect the transparent film material. The UV light is introduced into the film material from the side and transmitted through total reflection within the film material.

The so-called “predetermined event” from this patent can be a touch of the display surface, a timer expiration, a number of touches and a user session between login and logout from the device. The method or system is able to automatically disinfect the touchscreen or an outer surface of the transparent film material, which is attached to a display surface of the touchscreen, in order to prevent the spread of pathogens and germs such as bacteria and viruses.

The UV light is emitted by one or more light sources from the side through the edge into a transparent film material, such as quartz glass, UV-transparent plastic or the like. The UV light sources can be LEDs or mercury-filled gas discharge lamps and generate UV light with a wavelength in the range from 200 nm to 300 nm.

In the publication "Potential self-disinfection capacity of touch screen displays", J. Biophotonics, 2019 ; e 201900118 (https://doi.org/10.1002/jbio.201900118) has Hessling et al. above all the need to disinfect touchscreens in clinical and healthcare settings. As the authors point out in the publication, the use of chemical disinfectants on the display surface of common devices such as iPads or Galaxy tablets is not recommended. The authors then examined the effectiveness of disinfecting the display surface of a Samsung Galaxy tablet with different color samples and came to the conclusion that the exposure of the display surface with white light generated by the "High Brightness Mode" app was most effective in disinfecting the display surface.

The lack of effective disinfection of display surfaces on business and private devices is a serious source of the spread of infections, especially in immunocompromised patients, of which the users of the devices are unfortunately insufficiently aware. In addition, the usual methods of disinfecting devices, e.g. cleaning with ethanol, are expressly prohibited by the device manufacturers, which can void the guarantee. There is therefore a need to develop an improved method for disinfecting display devices and such a display device.

• 1 eine Übersicht des berührungsempfindlichen Anzeigegeräts mit Lichtquellen hinter einer Anzeigefläche;
• 2 ein Anzeigegerät mit Lichtquellen hinter der Anzeigefläche und Farbfilter;
• 3A ein Anzeigegerät mit Lichtquellen, die seitlich an dem Rand der Anzeigefläche angebracht sind;
• 3B ein Anzeigegerät mit Lichtquellen, die in einer Scheibe integriert sind.
• 4 ein Anzeigegerät mit Reflektoren an der hinteren Fläche; und
• 5 den Verfahrensablauf.

The invention will now be explained in more detail with reference to the following drawing. Show it:

• 1 an overview of the touch-sensitive display device with light sources behind a display surface;
• 2 a display device with light sources behind the display surface and color filters;
• 3A a display device with light sources which are attached laterally to the edge of the display surface;
• 3B a display device with light sources that are integrated in a disc.
• 4th a display device with reflectors on the rear surface; and
• 5 the process flow.

1 Figure 3 shows an example of a device with a surface according to a first aspect of the invention. The device is a touch-sensitive display device 10 with a touchable surface. The touch-sensitive display device 10 includes a display area 20th (or touchscreen) with a border 15th or frames and a variety of light sources 30th for the radiation of light from the light sources 30th in the display area 20th . In this first aspect are the light sources 30th behind a transparent display area 20th attached and shine through the display area 20th through. The irradiation 35 takes place with large beam angles so that the light is behind the display area 20th spreads and thus no high irradiance for a user of the display device 10 are to be feared.

The light sources 30th emit visible violet or ultraviolet light, for example. In one aspect, violet light with a wavelength of 400 nm is emitted, which is difficult for the user of the display device 10 is visible. The light sensitivity at the wavelength around 400 nm is known to be by the factor 200 reduced compared to green light with a wavelength of 550 nm. Alternatively, light can be emitted in the ultraviolet wavelength ranges of 200-280 nm (UV-C), 280-315 (UV-B) or 315-380 (UV-A). The use of blue light (wavelength of 450-485 nm) is basically also possible, whereby the use of light in this wavelength range results in a higher radiation dose for disinfecting the display surface 20th requires.

The emission of the (ultra) violet or blue light is used to disinfect the surface of the display area 20th . However, the light can be disruptive or harmful to the human eye of the user. The light sources 30th can therefore always remain switched on or after a determined touch of the display surface 20th be switched on. After touching the display surface 20th can use the light sources 30th switched on after a waiting period and then switched off after a sufficient exposure time. In a further aspect of the invention, the light sources 30th only switched on when the user is using the display device 10 not looked directly. This requires the installation of a corresponding sensor, e.g. a camera 40 with face recognition software required in the display device.

In a further aspect, visible light of a different wavelength (extraneous light) can be switched in addition to the (ultra) violet light in order to prevent the (ultra) violet disinfecting light from reaching the human eye or undesired impurities such as potentially fluorescent fingerprints on the display surface 20th be perceived. The violet / ultraviolet light is thus faded and largely invisible. At the same time, due to the large amount of white, the external light reduces the pupil diameter of the human eye and thus possible stresses on the retina in the eye.

In another aspect, the light sources 30th as purple or ultraviolet pixels in a normal RGB display 200 recorded. This is done either through the use of additional LEDs or organic LEDs or through the use of an (ultra) violet filter 210 and a corresponding display and background lighting 220 , as in a side view in 2 shown. This backlight 220 mostly done with white LEDs 30th that are directly behind the "pixels" (combination of color filters, polarizers and liquid crystals) or that are coupled in from the side.

Here it would be possible either to use white LEDs, which are based on a violet or UV LED, or to integrate UV LEDs in addition to white LEDs. A disadvantage of such a display device 10 would be, for example, the reduced resolution and a presumably slightly higher energy consumption, whereby the energy consumption in the health sector plays a subordinate role, since the display devices 10 are almost always connected to a power supply unit and thus supplied with electricity as an energy source.

In a further aspect, an (ultra) violet backlight can be used 220 eg through UV LEDs in the display device 20th can be installed without additional color pixels. Instead, the color filters in front of each pixel are designed in such a way that the pixels only let through one color in the visible spectrum, but also for the (ultra) violet light from the light sources 30th in the backlight 220 is transparent.

In a further aspect of the invention, the light sources 30th in the frame 15th of the display device 10 be built in, as in 3A shown. In this aspect, the (ultra) violet or blue light comes from the light sources 30th into the transparent display area 20th coupled, which behaves like a light guide. This means that the coupled-in light is reflected back and forth due to the "total reflection" effect. As a rule, no radiation reaches the user.

Germs and pathogens on the surface 22nd however, are irradiated anyway for two reasons. On the one hand, the light is not really rays, but waves, which means that the “light beam” 35 is on the surface 22nd the display area 20th changes direction, but part of the wave protrudes above the surface 22nd and thus also irradiates any germs and pathogens on this surface 22nd . In addition, deposits such as fingerprints / grease stains prevent total reflection. The grease stain and its surface 22nd are irradiated.

In a further aspect of the invention ( 4th ) become reflectors or diffusers 24 on the back of the display area 20th upset. The emitted light hits the reflectors or diffusers 24 showing the (ultra-) violet light from the light sources 30th then in the direction of the potentially contaminated surface 22nd redirects.

This principle also applies to (ultra) violet light on curved surfaces 22nd applicable to a disinfecting application of a curved surface 22nd to make possible.

In a further aspect of the invention, the light sources 30th can be integrated into the display area. 3B shows three types of integrated light sources 30r, 30u and 30o. The left light source 30r is at the edge of the display area 20th integrated and shines to the side through the display area 20th . The middle light source 30u is in the rear area of the display area 20th integrated and shines through the display area 20th through to the front. The right light source 30o is in the front area of the display area 20th integrated and radiates to the rear, where the radiation is reflected to the front.

The procedure for performing disinfection of the display surface 20th is in 5 shown. In a first step 510, the display area 20th with light 35 from the light sources 30th irradiated. In one aspect, the light may be turned off when a user approaches in step 520. In one aspect, the light is switched on after a predetermined time or switched off in step 530.

The display device 10 and the method have a multitude of applications, for example in the health sector for medical devices or in the hospitality sector. The procedure can also be used in the household.

The invention can also be used in other areas. For example, surfaces in devices can be disinfected, such as the bars of a shopping cart or the handrails in a bus, tram or train. The display devices and input fields or keyboards / number blocks on ticket machines or ATMs can also be equipped with the method.

In order to save energy, it is also possible to only emit radiation at the touched areas of the touchable surfaces.

List of reference symbols

10

Touch sensitive display device

15th

framework

20th

Display area

22nd

surface

24

Reflector / diffuser

30th

Light sources

35

light

40

camera

200

further light sources

210

filter

220

Backlight

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

• US 8999237 [0004]

Non-patent literature cited

• "Potential self-disinfection capacity of touch screen displays", J. Biophotonics, 2019 [0007]

Claims (21)

A touchable device (10) comprising: a touchable surface (20) having a frame (15); and a plurality of light sources (30) for irradiating blue, violet or ultraviolet light into the surface (20). Device (10) Claim 1 wherein the plurality of light sources (30) are mounted in the frame (30) of the display surface (20). Device (10) Claim 1 wherein the plurality of light sources (20) are integrated in the surface (20). Device (10) Claim 1 wherein the plurality of light sources (30) are mounted behind the display surface (20). Device (10) according to one of the preceding claims, wherein the light sources (30) are sources for light with a wavelength of 315-485 nm. Device (10) according to one of the preceding claims, wherein the light sources (30) are sources for light with a wavelength of 315-1000 nm. Device (10) according to one of the preceding claims, wherein the light sources (30) are sources for light with a wavelength of 390-410 nm. Device (10) according to one of the Claims 2 - 5 with a reflector (24) or diffuser attached to the rear. Device (10) according to one of the preceding claims, further comprising further light sources (200) which emit visible light. Device (10) according to one of the preceding claims, wherein the light sources (30) generate background lighting. Device (10) according to one of the preceding claims, wherein the light sources (30) are LEDs. Device (10) Claim 8 or 9 , wherein the further light sources (200) are LEDs with color filters (210). Device (10) according to one of the preceding claims, wherein the display surface (20) is curved. Device (10) according to one of the preceding claims, wherein the touchable surface is a touch screen. A method for disinfecting a touchable surface (20) of a touchable device (10) comprising: Irradiating (510) the surface (20) with the device (10) switched on with light (35) from a plurality of light sources (30). Procedure according to Claim 12 further comprising the simultaneous irradiation of the display surface (20) with UV light and visible light. Method according to one of the Claims 12 - 13th wherein the irradiating comprises irradiating from behind the surface (20). Method according to one of the Claims 12 - 14th wherein the irradiating comprises a lateral irradiating of the display surface (20). Method according to one of the Claims 12 - 15th , further comprising turning off (520) the irradiation when a user approaches. Method according to one of the Claims 12 - 16 , further comprising switching on and off (530) after a predetermined time.

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