NL2028262B1 - Device for disinfecting leaf-shaped products - Google Patents

Abstract

The invention relates to a device for disinfecting leaf-shaped products such as leaves of leafy vegetables and/or herbs, wherein the device is provided with a housing as well as at least one transport device with the aid of which the leaf-shaped products are transported between an entrance and an exit of the can be transported in a housing, wherein one or more UV-C light sources are arranged above the transport device at a height relative to the transport device, viewed from a surface on which the device can be positioned.

Description

Short description: Device for disinfecting leaf-shaped products Description: The invention relates to a device for disinfecting leaf-shaped products, such as for instance leaves of leafy vegetables and/or herbs.

US2015/0305396 shows a device for sanitizing and packaging foodstuffs such as blueberries. The foodstuffs to be treated with the known device include fruit and vegetables, but the device known from them is not or in any case less suitable for disinfecting leaf-shaped products such as leaves of leafy vegetables and/or herbs.

Leaf-shaped products such as leaves of leafy vegetables and/or herbs have a surface area per weight unit that is a multiple of most vegetables such as tubers or fruiting vegetables, but also in relation to fruit, for example, which makes it difficult to predict and/or determine their orientation on the conveyor belt. to arrange.

The device known from US2015/0305396 comprises a disinfection station through which the blueberries are moved in a transport direction by means of a conveyor belt. The sanitizing station has pulsed UV light sources to provide a sanitizing effect on the blueberries transported through the sanitizing station. To maximize the use of pulsed UV light, it is proposed without further details or directions to use reflectors or reflective surfaces in the known decontamination station. Ultraviolet light (abbreviated UV) is electromagnetic radiation just outside the part of the spectrum that is visible to the human eye. The wavelength of ultraviolet is between 100 and 400 nanometers. US2015/0305396 does not describe the use of UV-C light sources. UV-C light has a wavelength between 100 and 280 nm and is also referred to as short-wave radiation with a limited penetration depth. Due to the limited penetration depth in combination with the unknown orientation of leaf-shaped products on a conveyor device, shadow relative to the UV-C light sources plays an important limiting role in achieving a high degree of disinfection and/or a high degree of homogeneous disinfection for leaf-shaped products .

The object of the present invention is to provide a device on which leaf-shaped products can be efficiently and/or effectively disinfected with the aid of UV-C light in an energetically favorable manner and/or in a relatively simple manner.

This object is achieved with the features of a device as defined in claim 1.

The device is provided with a housing as well as at least one transport device with the aid of which the sheet-shaped products can be transported between an entrance and an exit of the housing, wherein, viewed from a surface on which the device can be positioned, above the transport device at a height at one or more UV-C light sources are arranged relative to the transport device, wherein at least a part of the inner wall parts of the housing facing towards the transport device are designed to reflect UV-C light by more than 50%.

In order to be able to carry out an effective disinfection of the sheet-shaped products, which normally have an irregular orientation with respect to the UV-C light source(s), by means of the UV-C light source(s) during operation of the device, at least a part of it has been transported to the transport device. oriented inner wall parts of the housing designed to reflect UV-C light from the UV-C light source(s) by more than 50%. In this way it is achieved that the transport device, in particular the product lying thereon, can be illuminated from several directions with UV-C light, whereby the possible irregular orientation or unfavorable orientation of the product relative to the UV-C light source(s) ) has less or possibly even no influence on the transport device for achieving a desired disinfection result of the leaf-shaped products. With the aid of the UV-C reflecting inner wall parts of the housing, no or at least fewer UV-C light sources need to be positioned next to, along and/or under the transport device, because the UV-C reflecting inner wall parts originate from the UV-C light. of the UV-C light source(s) reflect in such a way that the product lying on the transport device can be disinfected as if it were positioned on the side next to, along and/or under the transport device UV-C light source(s). The use of the inner wall parts of the housing facing the transport device moreover requires no or only a minimal structural adjustment and does not require any additional UV-C reflectors or other components to be fitted in the device with a UV-C reflecting surface, so that a relatively simple and to provide a compact device with which a UV-C disinfection process of leaf-shaped products can be realized in an efficient and effective manner. An additional advantage is that the relatively limited number of UV-C light sources required consumes relatively little energy during operation, so that the device has a relatively favorable energy consumption without this being at the expense of the disinfection result on the leaf-shaped products. In one aspect, the at least one portion and/or another portion of the inner wall portions of the housing facing the conveyor are designed to reflect UV-C by greater than 70% to increase the effectiveness of the UV-C reflection in the UV -C to increase the disinfection process of the leaf-shaped products.

A certain part of the inner wall parts can therefore have a UV-C reflection of at least 50%, while the other part can have a UV-C reflection of at least 70%. The at least one part and/or another part of the inner wall parts can be made of or coated with a highly UV-C light-reflecting material, such as for instance aluminum (UV-C reflection > 70%) and/or polytetrafluoroethylene (PTFE). (UV-C reflection > 90%). It is advantageous to position the UV-C light sources at a height, for example at least 30 cm, above the transport device, so that the risk is reduced or possibly even ruled out that the leaf-shaped products, such as herbs/leaves, which are relatively light in weight and therefore end up in the device may end up on the UV-C light sources around whirling leaf-shaped products and at least partly cover them, which can negatively affect the disinfection process with UV-C light to be carried out in the device.

By choosing a minimum height, such an undesirable shadow effect on the UV-C light sources can be prevented or at least minimized in a relatively simple manner. In this way, the risk can also be reduced, possibly even virtually excluded, that sheet-shaped products lying briefly or for a long time on the UV-C light sources fall back to the transport device and thus form an undesirable contamination in the end product. The device is particularly suitable for disinfecting dry or virtually dry leaf-shaped products or, if the leaf-shaped products have been pre-washed, dried or virtually dried leaf-shaped products.

The at least one part of the inner wall parts of the housing facing the transport device can comprise at least the inner wall parts that are arranged below the one or more UV-C light sources, in particular inner wall parts between the entrance and the exit (of the housing ) extending side walls of the housing. Inner wall parts located below the one or more UV-C light sources are understood to mean the inner wall parts extending from the UV-C light source(s) in the direction of the substrate and possibly inner wall parts of the bottom of the housing. In this way a maximum reflection of UV-C light to the transport device in the device can be achieved. In particular, the side walls of the housing, between which the elongate transport device extends, form the largest surface area of the housing under the UV-C light sources. As a result, inner wall parts of these side walls can make a strong contribution to a maximum UV-C reflection for an effective disinfection process of leaf-shaped products in the device. The at least one part of the inner wall parts of the housing facing the transport device, in particular the side walls thereof, can be designed to maximize the UV-C reflection in operation towards the product on the transport device. For instance, the at least one part of the inner wall parts of the housing directed towards the transport device, in particular the side walls of the housing, can be at least partially curved and/or be designed with at least one kink, so that with the aid of the design of the inner wall parts can reflect UV-C light maximally to the sheet-shaped products on a conveying surface of the conveying device. The inner wall parts of the housing bottom and/or of the housing roof can also comprise a shape, such as at least one bend and/or at least one kink, to prevent reflection of UV-C light towards the sheet-shaped products on a conveying surface of the conveying device in the device. to maximize.

The one or more UV-C light sources can be arranged at a height relative to the transport device which is at least 25% of the width of a substantially longitudinally extending transport surface of the transport device, preferably at least 40% of the width of the conveying surface of the conveying device. Such a height, related to the width of the substantially longitudinally extending conveying surface of the conveying device, guarantees that the UV-C light sources in combination with the inner wall parts of the housing facing the conveying device described above emit UV-C light in a relatively uniform manner. and homogeneously distribute over the width of the conveying surface for performing a relatively effective and efficient disinfection process of the sheet-shaped products located on the conveying surface. Also, due to such a difference in height between the UV-C light sources and the conveying surface of the conveying device, the undesired shadow effect on the UV-C light sources caused by leaf-shaped products, already described above, can be prevented or in any case minimized in a relatively simple manner.

Furthermore, the transport device can be a conveyor belt which is for instance provided with an endless belt turned over on rollers. The conveying device may comprise a conveying surface as well as at least one displacement mechanism for intermittently displacing at least a part of the conveying surface on which the sheet-shaped products are to be conveyed in a direction substantially transverse to the conveying surface in a direction remote from the subsoil in order to achieve the movement of the conveying device. move conveyed sheet-like products away from the conveying surface, mix (toss) and/or turn. By means of the displacement mechanism, the transported product can be set in motion intermittently, substantially vertically. The displacement mechanism can prevent leaf-shaped products lying in bulk on the transport surface, as a result of which many leaves can lie on top of each other, resulting in a strong shadow effect, that not only the upper leaves are treated with (reflected) UV-C light. Due to the intermittent vertical movements of the conveying surface of the conveyor device, the sheet-shaped products are thrown upwards with a frequency, so that the (reflected) UV-C light can treat the sheet-shaped products on all sides during the upward movement.

Also, due to this movement provided by the displacement mechanism, the leaves can be reversed, so that both the upper and lower sides of the leaf can be irradiated alternately with UV-C light.

The displacement mechanism may comprise, for example, a longitudinally and intermittently moving beater or a rotating beater or a rotating or longitudinally moving vibration motor, for example, which moves longitudinally and intermittently in a vertical direction or at an angle to the conveying direction of the conveying device, for instance at right angles to the conveying direction.

By adjusting the frequency, amplitude and angle of the displacement mechanism to provide the aforementioned intermittent vertical movement of the sheet-shaped products, mixing of the sheet-shaped products can also take place in such a way that the sheet-shaped products located at the bottom of a bulk flow on the transport surface can move upwards in the bulk flow and vice versa, in such a way that uniform mixing takes place and homogeneous treatment by (reflected) UV-C light is promoted.

A displacement of the sheet-shaped products to be provided with the displacement mechanism in a direction substantially transverse to the conveying surface in a direction remote from the substrate and/or the frequency of the displacement mechanism for intermittent displacement can be controllable with the aid of a controller, wherein the controller can be set manually and/or can be connected in a communicative manner with at least one sensor for, at least partly, automatic control of the displacement mechanism.

For example, the sensor can visually recognize the type of leaf-shaped products, such as type of herbs or type of leaves, and/or visually recognize the distribution and/or quantity and/or concentrations on the conveying surface and/or orientation of the product on the conveying surface of the conveying device and pass it on to the controller for automatically adjusting the displacement mechanism.

In one aspect, a maximum displacement of the sheet-shaped products to be provided with the displacement mechanism is substantially transversely of the conveying surface in a direction remote from the substrate relative to the conveying surface, and is at most 40% of the width of the substantially longitudinally extending transport surface, preferably a maximum of 25% of the width of the transport surface.

By limiting the maximum displacement in height relative to the transport surface, the process of the vertical displacement of the leaf-shaped products can be better controlled and predicted, so that a maximum surface area of each leaf-shaped product can be effectively disinfected by means of UV-C. Also, by limiting the substantially vertical displacement of the sheet-shaped products related to the width during operation, the UV-C light sources can be prevented from being reached by the sheet-shaped products and/or the risk can be reduced that at least a part of the sheet-shaped products falls next to the conveying surface, which is of course undesirable. Finally, by limiting the displacement of the sheet-shaped products in a vertical direction relative to the conveying surface, the device can be made relatively compact by limiting the movement of the sheet-shaped products provided by means of the displacement mechanism.

In a further aspect, a conveying surface of the conveying device is provided with perforations and/or meshes so that UV-C light can pass through the conveying surface, in particular the conveying surface is formed by a mesh belt. UV-C light passing through the perforations and/or meshes can be reflected by, for example, UV-C reflective parts of the housing bottom in the direction of the sheet-shaped products carried on the conveying surface. In this way, a larger surface of the leaf-shaped products can be disinfected by means of UV-C light. The reflection of UV-C falling through the transport surface can be further maximized by providing a reflector between the substrate and a transport surface of the transport device with which UV-C light can be reflected directly or indirectly via the UV-C reflecting inner wall parts in the direction of the transport surface. Such a reflector can be provided at a short distance below the conveying surface, as well as have a shape, such as at least one kink or at least one curved reflection surface for directing UV-C light (directly or indirectly) to the leaf-shaped surface located on the conveying surface. Products. Instead of the displacement mechanism described above or in addition thereto, in the housing of the device the transport device can be provided with transport device sections lying in line with each other, whereby an end of a first transport device section of the transport device sections is higher with respect to of the ground, then a start of a second conveyor device section of the conveyor device sections for conveying the sheet-like products transported in a conveying direction by means of the first conveyor device section to the second conveyor device section under the influence of gravity. In this way, the falling leaf-shaped products can turn between the transport sections so that all sides of the product are treated with UV-C light while falling. Due to the rotation, another surface of the sheet-shaped products can also come to lie on the conveying surface of the further conveying section, as a result of which a relatively effective further UV-C treatment of another surface of the sheet-shaped products can be carried out. In this way, an advantageous mixing, already described above, can also be provided in a bulk flow.

Further, at least the first conveyor section may be disposed at an angle α with respect to a horizontal plane, so that the end of the first conveyor section is disposed higher than a beginning of the first conveyor section, preferably the angle α is located between 10-30 degrees, even more preferably between 15-20 degrees. With such an embodiment, the falling of the leaf-shaped products can be achieved with a compact design of the device, because the required (built-in) height of such an arrangement of the conveyor device sections in the housing is limited. The end of the first conveyor section of the conveyor sections can be positioned 20-70 cm higher in relation to the ground than the beginning of the second conveyor section, preferably 30-60 cm higher. Tests have shown that such a height is particularly suitable for allowing the leaf-shaped products to rotate during the fall and for achieving effective mixing, so that the surface of each leaf-shaped product can be effectively and efficiently disinfected with UV-C light. is.

In a special aspect, the entrance is formed by an input funnel and/or the exit is formed by an output funnel, whereby the inner wall parts of the input funnel and/or the output funnel are designed to absorb UV-C light at least 60%, for example by manufacturing the inner wall parts. or to cover with a UV-C light absorbing material such as stainless steel and/or glass. In such a manner, a safe environment for operators can be provided around the device, since UV-C light cannot or hardly escape outside the device due to the UV-C absorbing inner wall parts of the input funnel and/or the output funnel. The design of the input funnel and/or the output funnel can also contribute to preventing UV-C light that is harmful to humans from escaping from the device.

In a further aspect, the UV-C light sources can be elongate and/or point-shaped UV-C light sources located at a distance from each other, the horizontal distance extending in the width direction of the elongate transport device between two UV-C light sources is equal to or greater than the width of the transport device. With the aid of such an arrangement, a homogeneous UV-C illumination over the entire width of a transport surface of the transport device extending substantially in the length can be achieved. The two UV-C light sources located furthest outside can be arranged at a lower height with respect to the substrate than UV-C light sources positioned centrally between the two UV-C light sources located furthest outside. The UV-C light sources located at a distance from each other can generally form a pattern in the form of a part of a cylinder wall profile with respect to the transport device. Such a pattern in combination with the UV-C reflecting inner wall parts or other properties of the device described above provides a device with which a relatively high yield of sheet-shaped products can be produced that are completely or almost completely disinfected with UV-C light. By means of the pattern and the UV-C reflecting inner wall parts, the irradiation dose can be distributed more homogeneously over the total surface of the transport surface as well as over the sheet-shaped product. In a constructionally relatively simple embodiment, elongate, spaced apart UV-C light sources extend substantially in the direction of transport. With such an arrangement, the advantageous pattern mentioned above is relatively easy to achieve from a constructive point of view.

Finally, the invention also relates to the use of a device described and shown herein for disinfecting leaf-shaped products, such as for instance leaves of leafy vegetables and/or herbs.

The aspects described in this document will be explained below on the basis of exemplary embodiments in combination with the figures. However, the invention is not limited to the exemplary embodiments described below. Much more, a number of variants and modifications are possible, which also make use of the idea of the invention and therefore fall within the scope of protection. In particular, the possibility is mentioned to combine the features/aspects only mentioned in the description and/or shown in the figures with the features of the claims or features shown in other figures as far as compatible. Reference is made to the following figures, in which: FIG. 1A schematically shows a longitudinal section of a part of a first embodiment of the device for disinfecting leaf-shaped products such as leaves of leafy vegetables and/or herbs; fig. 1B schematically shows a front view of the device shown in figure 1A; fig. 2A schematically shows a longitudinal section of part of a second embodiment of the device; fig. Figure 2B schematically shows a front view of the device shown in figure 2A; Figs. 3A-C show different cross-sections of different shapes for a housing of different embodiments of the device; fig. 4 shows a perspective view of part of a fifth embodiment of the device; fig. 5 schematically shows a longitudinal section of a portion of a sixth embodiment of the device. In the figures, the same parts are provided with the same reference characters.

Figures 1-5 schematically show the parts of the device for a person skilled in the art to illustrate the operation of device 1; 101; 201; 301; 401; 501 for the disinfection of leaf-shaped products. The device 1; 101; 201; 301; 401; 501 is an industrial device for disinfecting leaf-shaped products on an industrial scale. The device 1; 101; 201; 301; 401; 501 is provided with a housing 5; 205; 305; 405; 505 as well as at least one conveyor device, which in the figures is formed (not limited to) by a conveyor belt 7; 407; 507, with the help of which the sheet-shaped products between an entrance 9; 409; 509 and an output 11; 511 of the housing can be transported in a transport direction P1, wherein viewed from a surface (not shown) on which the device can be positioned above the conveyor belt 7; 407; 507 at a height relative to the conveyor belt 7; 407; 507 different UV-C light sources 13; 113 are arranged, with at least a part of the conveyor belt 7; 407; 507 oriented inner wall parts 15; 215; 315; 415; 515 of the housing is designed to reflect UV-C light by more than 50%.

The conveyor belt 7; 407; 507 is provided with a rollers 8, 8; 506a, 508a beaten endless belt 10; 5104, 510b, 510c.

Instead of the conveyor belt shown, a suitable other conveyor device can also be selected.

Using the UV-C reflective inner wall parts 15; 215; 315; 415; 515 of the housing are next to, along and/or under the conveyor belt 7; 407; 507 no UV-C light sources positioned.

Using such inner wall parts 15; 215; 315; 415; Moreover, 515 requires no or only a minimal constructive adjustment, as a result of which a relatively simple and compact device can be provided with which a UV-C disinfection process of leaf-shaped products can be carried out in an efficient and effective manner.

The UV-C disinfection process can be further promoted if at least one part and/or another part of the conveyor belt 7; 407; 507 oriented inner wall parts 15; 215; 315; 415; 515 of the housing is designed to reflect UV-C by more than 70%.

The at least one part and/or another part of the inner wall parts can be made of or coated with a highly UV-C light-reflecting material, such as for instance aluminum (UV-C reflection > 70%) and/or polytetrafluoroethylene (PTFE). (UV-C reflection > 90%). The UV-C light sources 13; 113 are only at a height, for example at least 30 cm, above the conveyor belt 7; 407; 507 drafted.

The UV-C light sources 13; 113 can advantageously be arranged as described herein at a height H1 relative to the conveyor belt 7; 407; 507 which is at least 25% of the width B1 of a transport surface 18 extending substantially in the length (direction indicated by arrow P1); 418; 518a-c of the conveyor belt 7; 407; 507, preferably at least 40% of the width B1. The device 1 shown in Figures 1A,B and 3A differs from the device 101 shown in Figures 2A,B only in that the UV-C light sources are elongated 13 or point-shaped 113 spaced apart UV-C light sources.

Point-shaped in this document means a UV-C light source with relatively small dimensions and the point-shaped UV-C light sources 113 are shown herein only as an alternative to the elongated UV-C light sources 13. Elongated UV-C light sources 13 are also shown in the device 401 is shown in Figure 4. In Figure 5 elongated UV-C light sources are also arranged similar to Figure 4, but these UV-C light sources are not shown in Figure 5.

In the figures

2A, 2B, a pattern of the UV-C light sources 113 is shown similar to the pattern of the elongated UV-C light sources 13 shown. The elongated UV-C light sources

For example, 13 may be known fluorescent tubes that emit UV-C.

However, it is also possible that the elongated UV-C light sources 13 are formed by UV-C LEDs.

The UV-C light sources 113 may also be UV-C LEDs.

It is furthermore possible to position the elongated UV-C light sources transverse to the transport direction P1

(not shown), so that a similar pattern as in figures 2A and 2B can be achieved, but then with at least one elongated UV-C light source that extends as shown by the arrow A1 in figure 2B, where viewed in the direction of transport at a distance therefrom. at least a second and a third elongated UV-C light source can be arranged to simulate a UV-C exposure similar to the arrangement shown in Figures 2A, 2B.

The UV-C light sources described in this document further comprise reflectors known per se to direct the UV-C light downwards, in this document more particularly in the direction of the conveyor belt 7;

407; 507. The horizontal distance A1 extending in the width direction of the elongate conveyor belt between two UV-C light sources 13 located furthest outwards as seen from the direction of transport P1; 113 is equal to or greater than the width of the conveyor belt 7; 407. Using such an arrangement of the UV-C light sources 13; 113, a homogeneous UV-C illumination over the full width of the substantially longitudinally extending conveying surface 18; 418; 518a-

c of the conveyor belt are reached.

As can be seen in the figures, the two outermost UV-C light sources (between which the distance A1 is shown in the figures) are positioned at a lower height in relation to the substrate/transport surface than centrally between the two outermost ones. UV-C light sources installed UV-C light sources.

The spaced apart UV-C light sources 13; 113 generally form a pattern (crescent moon) in the form of a part of a cylinder wall profile with respect to the conveyor belt 7; 407. This half-moon pattern is clearly visible in figures 1B, 2B, 3A-C and 4. With the aid of such a pattern in combination with the UV-C reflective inner wall parts, leaf-shaped products can be treated efficiently and effectively by means of UV-C light. to disinfect.

With the aid of the elongated, preferably regularly spaced, UV-C light sources 13, the pattern shown can be realized in a relatively simple constructional manner and the maintenance of the device is minimal due to the relatively limited number of UV-C light sources 13 .

The conveyor belt 7; 407; 507, the conveying surface includes 18; 418; 518a-c on which the sheet-shaped products lie in operation, as well as at least one displacement mechanism 20A-D; 420A,B for intermittently displacing at least a portion of the conveying surface on which the sheet-shaped products are to be conveyed in a direction substantially transverse to the conveying surface 18; 418; 518a-c in a vertical direction away from the substrate about the conveyed sheet products of the conveying surface 18; 418; 518a-c to move, mix (scramble), and/or flip.

In Figures 1A and 2A, four displacement mechanisms 20A-D and three displacement mechanisms 20A-D are shown, respectively, only to show that the number of displacement mechanisms may be variable.

To obtain a uniform (vertical) displacement of the sheet-shaped products on the conveying surface 18; 418 to provide a uniform irradiation dose of UV-C to the sheet products in operation, the displacement mechanisms can be spaced at a regular distance from each other below the conveying surface 18; 418 in housing 5; 205; 305; 405; 505 are arranged as shown in Figures 1A and 4. Although not shown in Figure 5, the conveyor belt, more specifically each conveyor belt section 507a-c, may be provided with displacement mechanisms.

By means of the displacement mechanisms, the transported product can be set in motion substantially vertically, intermittently.

The displacement mechanisms can prevent leaf-shaped products lying in bulk on the transport surface, as a result of which many leaves can lie on top of each other, resulting in a strong shadow effect, that not only the upper leaves are treated with (reflected) UV-C light.

Due to the intermittent vertical movements of the conveying surface, the sheet-shaped products are thrown upwards with a frequency, so that the (reflected) UV-C light can treat the sheet-shaped products on all sides during the upward movement.

Also, these with the displacement mechanisms 20A-D; 420A,B, the leaf-shaped products are reversed, so that both the top and bottom of the product to be treated can be irradiated alternately with UV-C light.

By adjusting the frequency, amplitude and angle of the displacement mechanisms 20A-D; 420A,B for providing the aforementioned intermittent vertical movement on the sheet-shaped products, a mixing of the sheet-shaped products can also take place such that the sheet-shaped products located at the bottom of a bulk flow on the conveying surface 18; 418; 518a-c are able to move upwards in the bulk stream and vice versa, in such a way that uniform mixing takes place and homogeneous treatment by UV-C light is promoted.

The displacement mechanisms can be controllable with the aid of a controller 425. Such a controller is only shown in Figure 4, but can be used in any device 1; 101; 201; 301; 401; 501 are provided.

The controller 425 can communicate with at least one sensor 430, again only shown in Figure 4, but such a sensor can be present in any of the devices shown.

For example, the sensor 430 can visually recognize the type of herbs or leaves and/or visually recognize the distribution and/or quantity and/or concentrations on the conveying surface and/or orientation of the product on the conveying surface of the conveying device and transmit it to the controller for the automatic adjustment of the displacement mechanism 20A-D;

420A,B.

In Figures 3B, 3C and 4 it is shown that to the conveying surface 18; 418 facing inner wall parts of the housing 205; 305; 405 may be configured to operate the UV-C reflection toward the product on the conveying surface 18; 418 to maximize.

For example, the inner wall parts of the housing can be of curved design as shown in figure 3C and/or be designed with kinks as shown in figures 3B and 4 so that UV-C light can be reflected maximally to the leaf-shaped surface by means of the design of the inner wall parts. products on the conveying surface 18; 418. Also, the inner wall parts of the housing bottom (not shown) and/or of the housing roof (Figures 3B, 3C and 5) may include a similar design to maximize reflection of UV-C light to the sheet-like products on a conveying surface. In the devices shown in the figures, a special design of the housing bottom has minimal effect, because the distance between the transport surface 18; 418 and the inner wall parts is minimal, in the device shown in figure 4 even nil, as a result of which only a small part or even no UV-C light will reach the bottom of the housing. If this distance is greater, the housing bottom can be provided with a suitable design to more effectively reflect UV-C light to the conveyor belt directly or indirectly via the UV-C reflective inner wall parts.

As shown in Figures 1B and 2B, a conveying surface 18 may be provided with schematically illustrated perforations/openings 30 to allow UV-C light to pass through the conveying surface. UV-C light passing through the perforations can be reflected by, for example, UV-C reflective parts of the housing bottom towards the sheet-shaped products carried on the conveying surface. The reflection of UV-C falling through the transport surface can possibly be further maximized by providing a reflector (not shown) between the substrate and a transport surface of the transport device, with which UV-C light can be reflected in the direction of the transport surface.

Instead of the displacement mechanism described above or in addition thereto, in the housing of the device 501, the conveyor device 507 may be provided with conveyor belt sections 507a-c which are located in line with each other in the conveying direction P1. In this case, an end 5144, 514b of a first/second conveyor belt section 507a,b is positioned higher with respect to the ground than a beginning 516b, 5186c of a second/third conveyor belt section 507b,c in order to achieve the means of the preceding conveyor belt section. 507a,b under the influence of gravity (represented by arrow P2) under the influence of gravity (represented by arrow P2), sheet-shaped products transported in a conveying direction P1 to the following conveyor belt section 507b,c. In this way, between the conveyor belt sections 507a-c, the falling leaf-shaped products will be treated with UV-C light and rotate so that another surface of the leaf-shaped products can come to rest on the conveying surface 518b, 518c, resulting in a relatively effective UV -C treatment of the surface of the sheet-shaped products can be carried out. In this way, an advantageous mixing, already described above, can also be provided in a bulk flow. The conveying surfaces 518a, 518b, 518c extend substantially vertically. The height difference between the end and the beginning of the next conveyor belt section 507b,c is 20-70 cm, preferably 30-60 cm.

Although not shown in the figures, at least a first conveyor section may be disposed at an angle α with respect to a horizontal plane so that the end of the first conveyor section is disposed higher than a beginning of the first conveyor section, when preferably the angle α is between 10-30 degrees, even more preferably between 15-20 degrees. Each start of a conveyor section can in this way be positioned at substantially the same height with respect to a horizontal surface.

In a particular aspect shown only in Figure 5, but that in each device 1 shown; 101; 201; 301; 401; 501 can be applied, the entrance to the housing is formed by an input funnel 509 and the exit is formed by an output funnel 511, the inner wall parts of the input funnel and the output funnel being designed to absorb UV-C light at least 60%, for example by the to manufacture or cover inner wall parts with a UV-C light absorbing material such as, for example, stainless steel and/or glass. In such a way a safe environment for operators can be provided around the device.

The design of the input funnel and the output funnel can also contribute to preventing UV-C light that is harmful to humans from escaping from the device.

Claims (20)

CONCLUSIONS CLAIMS 1. Device for disinfecting leaf-shaped products, such as for instance leaves of leafy vegetables and/or herbs, wherein the device is provided with a housing as well as at least one conveyor belt with the aid of which the leaf-shaped products can be transported between an entrance and an exit of the housing in which, viewed from a surface on which the device can be positioned, one or more UV-C light sources are arranged above the conveyor belt at a height relative to the conveyor belt, in which at least a part of the inner wall parts of the housing facing the conveyor belt are designed to reflect UV-C light by more than 50%. 2. Device as claimed in claim 1, wherein the at least one part and/or at least one other part of the inner wall parts of the housing facing the conveyor belt are designed to reflect UV-C by more than 70%. 3. Device as claimed in claim 1 or 2, wherein the at least one part of the inner wall parts is manufactured from or coated with a highly UV-C light-reflecting material, such as for instance aluminum and/or polytetrafluoroethylene (PTFE). 4. Device as claimed in any of the foregoing claims, wherein the at least one part of the inner wall parts of the housing facing the conveyor belt comprises at least inner wall parts that are arranged below the one or more UV-C light sources, in particular the inner wall parts of the housing located between the entrance and exit extending side walls of the enclosure. 5. Device as claimed in any of the foregoing claims, wherein the at least one part of the inner wall parts of the housing facing the conveyor belt is at least partially bent and/or designed with at least one kink. 6. Device as claimed in any of the foregoing claims, wherein the one or more UV-C light sources are arranged at a height relative to the conveyor belt which is at least 25% of the width of a substantially longitudinally extending conveying surface of the conveyor belt, preferably at least 40% of the width of the conveying surface of the conveyor belt. 7. Device as claimed in any of the foregoing claims, wherein the conveyor belt comprises a conveying surface as well as a displacement mechanism which is provided for intermittently displacing at least a part of the conveying surface on which the sheet-shaped products are to be conveyed in a direction substantially transverse to the conveying surface in a direction away from the surface in order to move, mix and/or turn the sheet-shaped products transported with the conveyor belt away from the transport surface. 8. Device as claimed in claim 7, wherein a displacement of the sheet-shaped products to be provided with the displacement mechanism in a direction substantially transverse to the conveying surface in a direction remote from the subsoil and/or a frequency of the displacement mechanism for intermittent displacement can be controlled with with the aid of a controller, wherein the controller can be set manually and/or can communicate with at least one sensor for at least partly automatic control of the displacement mechanism. 9. Device as claimed in claim 7 or 8, wherein a maximum displacement of the sheet-shaped products to be provided with the displacement mechanism substantially transversely of the conveying surface in a direction remote from the substrate relative to the conveying surface is a maximum of 40% of the width of the conveying surface. transport surface extending substantially in the length, is preferably a maximum of 25% of the width of the transport surface. 10. Device as claimed in any of the foregoing claims, wherein a transport surface of the conveyor belt is provided with perforations and/or meshes so that UV-C light can pass through the transport surface and can be reflected, in particular the transport surface is formed by a gauze belt. 11. Device as claimed in any of the foregoing claims, wherein a reflector is provided between the substrate and a transport surface of the conveyor belt on which the sheet-shaped products to be transported lie, with which UV-C light can be reflected in the direction of the transport surface. 12. Device as claimed in any of the foregoing claims, wherein the conveyor belt in the housing of the device is provided with conveyor belt sections lying in line with each other, wherein an end of a first conveyor belt section of the conveyor belt sections is higher with respect to the is arranged on the ground, then a start of a second conveyor belt section of the conveyor belt sections for conveying the sheet-like products conveyed in a conveying direction by means of the first conveyor belt section to the second conveyor belt section under the influence of gravity. An apparatus according to claim 12, wherein at least the first conveyor belt section is disposed at an angle α with respect to a horizontal plane, such that the end of the first conveyor belt section is disposed higher than a start of the first conveyor belt section, preferably the angle α is between 10-30 degrees, even more preferably between 15-20 degrees. 14. Device according to claim 12 or 13, wherein the end of the first conveyor belt section of the conveyor belt sections is positioned 20-70 cm higher with respect to the ground than the beginning of the second conveyor belt section, preferably 30-60 cm. cm higher. 15. Device as claimed in any of the foregoing claims, wherein the entrance is formed by an input funnel and/or the exit is formed by an output funnel, wherein the inner wall parts of the input funnel and/or the output funnel are designed to absorb UV-C light at least 60%, for instance by manufacturing or covering the inner wall parts with a UV-C light absorbing material such as for instance stainless steel and/or glass. 16. Device as claimed in any of the foregoing claims, wherein the UV-C light sources are elongate and/or point-shaped UV-C light sources located at a distance from each other, wherein the horizontal distance extending in the width of the elongate conveyor belt between two outermost UV-C light sources equal to or greater than the width of the conveyor belt. An apparatus according to claim 16, wherein the elongated, spaced-apart UV-C light sources extend substantially in the direction of transport. 18. Device as claimed in claim 16 or 17, wherein the two outermost UV-C light sources are arranged at a lower height with respect to the substrate than UV-C light sources positioned centrally between the two outermost UV-C light sources, An apparatus according to claim 16, 17 or 18, wherein the UV-C light sources located at a distance from each other substantially follow a pattern in the form of a part of a cylinder wall profile with respect to the conveyor belt. 20. Use of a device according to any one of the preceding claims for disinfecting leaf-shaped products, such as for instance leaves of leafy vegetables and/or herbs.