WO2024229491A1 - Disinfection system for the interior of closed containers - Google Patents

Abstract

The invention proposes a modular system based on LEDs (3) that emit blue-violet light for disinfecting the interior of containers, especially refrigerated van bodies. The individual modules (10) are constructed from LEDs (3) and (3a), electronic components (3b) and lines, cast into a profile (2) with transparent polymers and optionally additionally provided with LEDs (3a) that emit light in the white range of the spectrum in order to illuminate the interior, and this enables the creation of a disinfection and illumination strip of any desired length.

Description

Disinfection system for the interior of closed containers

The invention relates to a disinfection system for the interior of closed containers, in particular truck box bodies, according to the preamble of claim 1.

A "closed container" in the sense of the invention also includes the interior of buses and motor vehicles, gondolas, containers and transport containers of all sizes, including waste containers, even if the invention is explained in more detail below using a refrigerated truck box. It should also be noted that closed containers in which people, whether short or long, are located can be equipped according to the invention with a design that has a combined lighting and disinfection system. This is also one reason why a refrigerated truck box is used as an embodiment.

There is therefore a need for an intrinsically safe device for disinfecting the interior of containers that is simple and inexpensive to manufacture, assemble and operate. The aim and object of the invention is to provide such a device, wherein in one embodiment it should also be possible to illuminate the interior.

In the following, the truck (refrigerator) box body is usually referred to simply as the body. The aim of the invention is to achieve a significantly better hygienic and lighting situation inside such a body compared to previous solutions.

The hygienically safe handling of refrigerated goods inside a structure is an essential requirement in modern refrigerated transport, and the operator must ensure that this is met. Poor hygiene, caused by insufficient cleaning processes or careless handling of the transported goods, usually leads to the loss of the refrigerated goods due to "not being placed on the market" (i.e. disposal) and, in the worst case (e.g. if botulism pathogens are formed), can be considered negligent behavior and thus punishable by law. Current, commonly used procedures to ensure a necessary, hygienically sufficient transport situation inside a structure mostly use steam jet processes or jet processes with the addition of disinfectants to clean the interior walls, whereby the cleaning and disinfection effects can be significantly reduced depending on the superstructures and fittings inside the structure. In addition, cleaning and disinfection are carried out at different, sometimes longer intervals, and in any case not continuously. Continuously effective disinfection cannot be achieved with these methods.

The KR20220072651A proposes the use of LEDs inside the body that emit ultraviolet light (UV light) that is switched on or off depending on who enters the case. Complex electronics with sensors for the closed state of the doors and the presence of people are provided for this purpose. Regardless of this effort, the inner surface of the body in the areas where no refrigerated goods are placed is attacked and destroyed by the UV light in a relatively short time, releasing undesirable substances that are just as harmful as the germs being combated.

A similar device is known from US 2022/0409754 Al, which additionally includes the control of the visible light inside the structure, the interior lighting, which can be activated as an alternative to UV light. The device suffers from the same disadvantages as the first one.

From a completely different field, namely the treatment of wastewater, it is known from WO201 1/139758 A2 to mount several LEDs on a common strip.

The present invention aims to avoid the deficiencies mentioned above and those of the known solutions and to ensure a continuous disinfection option even during use of the structure in combination with cost-effective and long-lasting interior lighting. The basis of the invention is the use of embedded LEDs (Light Emitting Diodes) that emit a specific wavelength spectrum, as described in WO 2018/020527 Al, namely in ranges between 405nm and 420nm; called blue-violet.

These LEDs are preferably arranged in a special, innovative fastening system. This system can be integrated into a wall rail and, due to the structural design and sealing of the LEDs using transparent polymers, can be designed to be so resistant that it can be cleaned in the usual way like the walls of the structure, without being susceptible to errors due to moisture penetrating.

It is well known that lasers, lamps or LEDs that emit intense blue-violet light (“mid and near UV”) are used in hospitals to reduce microbial and bacterial loads. However, frequent exposure of human skin to light of these wavelengths, particularly when larger portions of shorter wavelengths are also emitted, can lead to undesirable effects such as melanomas or other skin irritations. It must therefore be ensured that exposure of human skin is avoided as far as possible when light of these wavelengths is used, or the wavelength range of the light must be selected so that it has a bacteria-killing effect but causes as little damage to human skin as possible and does not corrode the surface of the structure. This is achieved to a large extent with the wavelength range stated.

The inventive design of the arrangement of the LEDs and their circuitry means that the problem described above can be solved by selecting wavelength ranges that are largely harmless to people and the surfaces of the body, but sufficiently active for germs. Further improvements are made by preferably only switching on the blue-emitting LEDs when the doors of the refrigerated box body are closed, which is made possible by a single, inexpensive sensor.

The invention is explained in more detail below with reference to the drawing. Fig. 1 is a 3D representation of the cross-section and the top view of a module with the profile clipped (snapped) into a mounting strip 1, with a circuit board, with LEDs and cable ducts, Fig. 2 is an enlarged cross-section through a module in the area of the arrangement of the LEDs with the profile clipped (snapped) into the mounting strip, the circuit board and a casting compound and Fig. 3 is an enlarged cross-section through a module in the area of the cable ducts with the profile clipped (snapped) into the mounting strip.

The LEDs 3 essential for disinfection according to the invention operate, as mentioned, in a blue-violet wavelength range with emission peaks between 405 nm and 420 nm. In addition, any number of LEDs 3a can be installed in a module 10 for lighting purposes, which emit white light with a color temperature between 1000 and 20000K.

Fig. 1 shows a 3D representation of an embodiment in section. The mounting strip 1 designed according to the invention with a flat middle part and side roundings, which are designed in such a way that they have a certain elasticity for the profile 2 to snap into place, is attached to the inside of the structure (not shown) along the length at any height, with attachment by means of an adhesive connection being preferred. However, all other force-fitting connection techniques are also possible.

A profile 2 designed according to the invention is inserted into this mounting strip 1 and is secured by clipping (snapping in). The dimensions of the mounting strip 1 vary in cross-section with a width of between 40mm and 100mm, whereby widths of the mounting strip 1 between 70mm and 45mm are preferred according to the invention. The height of the mounting strip 1 varies between 5mm and 15mm depending on the width, whereby a height between 7mm and 12mm is preferred according to the invention. The flat middle part preferably has a width between 20mm and 40mm and a depth between 2mm and 15mm, preferably between 3mm and 12mm. These dimensions can be adapted accordingly depending on the width and depth of the profile 2, whereby the dimensions of the LEDs 3 and 3a used and the circuit board 4 must also be taken into account. The dimensions of the profile 2, which contains the circuit board 4 and the LEDs 3 and 3a as well as the electronic components and control elements 3b and the necessary cables for the power supply 5 and which is covered with a polymer, transparent casting compound, are adapted to the respective dimensions of the mounting strip 1 and are preferably designed in such a height that after clipping in (snapping in), the upper edge of the profile 2 runs flush with the upper edge of the mounting strip 1. The dimensions of the circuit board 4 (printed circuit board) arranged inside the profile 2 are preferably designed in such a way that the circuit board 4 can be inserted flush into the rectangular recess 12 facing the interior of the box body.

The mounting strip 1 with the snapped-in modules 10, consisting of the profile 2, the LEDs 3 and 3a, the circuit board 4, the side cover 9 and a rectangular recess 12, which are laterally defined by the width of the profile 2, is closed at the longitudinal ends with end caps 11. The modules 10 can be clipped into the mounting strip 1 in various lengths between 100mm and 500mm, preferably with lengths between 250mm and 350mm. In this way, a continuously operating disinfection strip can be installed over the entire length of a structure (up to lengths of more than 15m), which can also be supplied with energy from the vehicle battery when the vehicle is stationary due to the low energy consumption of the LEDs.

The mounting strip 1, like the profile 2, is made of metallic materials, preferably high-strength aluminum. In principle, polymeric, fiber-reinforced materials are also conceivable for the profile production. To ensure sufficient reflection of the LED radiation, the mounting strips 1 and the profile strips 2 made of aluminum can be anodized or, for example, plasma-oxidized, but other types of surface finishing are also possible; preferably, a powder coating in white provides particularly suitable reflection values.

In profile 2, the LEDs 3 (blue-violet wavelength range) and 3a (white wavelength range) are mounted as well as the electronic components and control elements 3b required for controlling the LEDs on a printed circuit board (PCB) 4. Both the LEDs 3 and 3a as well as the electronic control elements 3b with the circuit board 4 and the necessary lines 5 for the voltage supply of the LEDs and the cable ducts 6 are embedded in a transparent polymeric potting material 7, preferably consisting of thermally stable, curable polymers, such as transparent polyurethanes.

In principle, other transparently curing or permanently elastic polymeric casting materials can also be used. According to the invention, transparent polyurethane or silicone-based materials are preferred, which can be applied in a thickness of between 1 mm and 10 mm without bubbles, preferably in a thickness of between 2 and 5 mm, and which are closed by a side cover 9 at both ends of the module 10 flush with the upper edge of the profile 2 and have feedthroughs for the cables 6.

The potting material 7 covers the entire electronic arrangement (LEDs 3 and 3a, control elements 3b, circuit board 4 and the cables 5 as well as the cable ducts 6) and a flat surface is formed between the lateral longitudinal regions of the profile 2.

In addition, a cover profile 8 can be used for the spaces between the individual locked modules 10, consisting of the LED arrangements 3 and 3a embedded in the profile 2 on the circuit board 4 with the electronic components cast in the casting compound. This cover profile 8 can be used in different lengths and thus enables the realization of different distances between the modules 10.

The cross-section of the cover profile 8 corresponds to the cross-section of the profile 2 used and can also be clipped (snapped) into the mounting strip 1 like the profile 2.

With the modules 10 manufactured according to the invention, disinfection and lighting units of different lengths can be produced, depending on the customer's requirements. An end cap 11 closes the entire arrangement of the modules 10 in the mounting strip 1 on both sides of the front sides of the mounting strip 1. The profile of the end caps 11 in cross section corresponds to the cross section of the profile 2 used and can therefore also be clipped into the mounting strip 1. In another variant, the end cap 11 can be inserted into the lateral curves of the mounting strip 1.

According to the invention, the cable ducts 6 with the cables 5 are designed in such a way that the individual modules 10 can be coupled by simply plugging them together or by soldering the cables.

By clipping (snapping in) the profile 2 with the cast-in LED arrangements 3 with the circuit board 4 and the cables 5 (module 10) into the mounting strip 1, flexible installation and easy replaceability of the LEDs for service and repair is ensured.

An essential use of the disinfection unit that is relevant to the invention is that the additionally integrated white light emitting LEDs are used for normal lighting purposes and the ultraviolet emitting LEDs are only switched on automatically after the doors of the box body are closed. This is achieved either by a direct electrical circuit or via a radio connection. Preferably, microswitches are integrated into the respective door elements of the refrigerated box body, which enable this control modality and, in combination with the control system of the LEDs, ensure the necessary safety in handling.

Fig. 2 shows an enlarged cross-section through a module 10 in the area of the arrangement of the LEDs 3 with circuit board 4 and the potting compound 7 with profile 2 clipped (locked) into the mounting profile 1 as a carrier unit for the circuit board 4, the LEDs 3 and 3a and the electrical and electronic components necessary for their control.

Fig. 3 shows an enlarged cross-section through a module 10 in the area of the cable ducts 6 and the casting compound 7, again with the profile 2 clipped (locked) into the mounting profile. In summary, in other words, it can be stated that the invention relates to a lighting and disinfection system consisting of modules 10 for the interior of closed containers, for example box bodies and in particular refrigerated box bodies. It is preferably provided that at least one light-emitting module 10 is clipped into a mounting strip (1) with the aid of a profile 2. The profile has a rectangular recess in which a circuit board 4 with LEDs 3 and optionally LEDs 3a placed on it is cast. The LEDs 3a emit light in the white range of the spectrum and are only provided if the closed container is intended to accommodate people at least for a short time. The LEDs 3 emit light in the blue-violet range of the spectrum with emission peaks between 405nm and 420nm. If both LEDs 3 and LEDs 3a are provided, they are specifically controlled differently.

The above explanation allows the application of the invention to the interior of buses, aircraft and other means of transport immediately and without consideration; no further explanation is required.

If the invention is used, for example, for non-walk-in containers or walk-in containers are not to be equipped with visible light illumination for whatever reason, for example garbage cans, then either LED strips that do not have LEDs 3a are to be used or, if this is not desired, for example for storage reasons, these LEDs 3a are not controlled.

This means that the unpleasant smell that inevitably arises during the biological decomposition of garbage in Colonia bins, especially in the warmer seasons, can be significantly reduced and even avoided. In the case of garbage bins, it is also preferable to have one or more photovoltaic elements (PV elements) on the lid, which supply the electricity required to operate the LED strip and thus enable disinfectant radiation when the bin is closed. The electronics required in this case are small and inexpensive and can be housed on or in the lid, preferably cast in the lid in the case of plastic lids. The invention can therefore actually be used in all cases of closed containers for disinfecting their interior (surfaces).

List of reference symbols:

1 mounting strip

2 clip-on (snap-in) profile

3 LEDs, blue-violet emitting

3a LEDs white emitting

3b electronic control elements

4 Circuit board (printed circuit board) as a carrier for the necessary electrical and electronic components

5 cables for control and electrical

6 cable ducts

7 casting material

8 Cover profile (plate) to cover the space between individual modules 10

9 Lateral cover of the potting material in edge areas of the LEDs

10 modules of different lengths

11 end cap

12 Flat rectangular recess in profile 2

Claims

Patent claims: 1. Disinfection system, consisting of modules (10), for the interior of closed containers, in particular box bodies and very particularly refrigerated box bodies using electromagnetic radiation of a defined wavelength range, characterized in that at least one light-emitting module (10) is clipped into a mounting strip (1) with the aid of a profile (2), in the rectangular recess (12) of which parallel to the flat region of the mounting strip (1) a circuit board (4) with LEDs (3) and (3a) placed thereon is cast, and that LEDs (3) emit light in the blue-violet region of the spectrum with emission peaks between 405nm and 420nm. 2. Disinfection system according to claim 1, characterized in that the module (10) also has LEDs (3a) cast into it, which emit light in the white range of the spectrum, and that the LEDs (3) and the LEDs (3a) are controlled differently by electronic control elements (3b). 3. Disinfection system according to claim 1 or 2, characterized in that the mounting strip (1) and/or the profile (2) are formed independently of one another from metallic or polymeric materials, preferably from high-strength aluminum or fiber-reinforced polymers. 4. Disinfection system according to claim 3, characterized in that the mounting strip (1) and the profiles (2) independently have an anodized surface or a white powder coating. 5. Disinfection system according to one of the preceding claims, characterized in that several modules (10) with a length of 100 mm to 500 mm, preferably with a length between 100 mm and 400 mm, are clipped into the mounting bar (1). 6. Disinfection system according to one of the preceding claims, characterized in that the mounting strip (1) has a width between 40mm and 100mm, preferably between 45mm and 70mm, and a height between 5mm and 15mm, preferably between 7mm and 12mm. 7. Disinfection system according to one of the preceding claims, characterized in that the flat middle part of the mounting strip (1) has a width between 20 mm and 50 mm, preferably a width between 25 mm and 40 mm. 8. Disinfection system according to one of the preceding claims, characterized in that transparent polymeric potting materials, preferably polyurethanes or silicones, are used for embedding the LEDs (3) and (3a) as well as the circuit board (4) and the lines for control and electronics (5). 9. Disinfection system according to claim 3, characterized in that the materials for the mounting strip (1) and the profile (2) have an anodized, plasma-oxidized or powder-coated surface, depending on the material. 10. Disinfection system according to one of the preceding claims, characterized in that by arranging modules (10) in a row, any length of the disinfection system can be realized, preferably up to 16 m, wherein different distances between the modules (10) are realized by a snap-in cover profile (8). 11. Disinfection system according to claim 10, characterized in that the cover profile (8) has the same structure in cross section as the profile (2) used in each case. 12. Disinfection system according to one of the preceding claims, characterized in that end caps (11) are attached to the ends of the mounting strip (1), the internal structure of which is identical in cross-section to the profile (2), so that fastening in the mounting strip (1) is provided by snapping into place. 13. Disinfection system according to one of the preceding claims, characterized in that the circuit board (4) with the LEDs (3,3a) and the electronic control elements (3b) is fitted flush into the rectangular recess of the profile (2).