NL1032593C2 - Air cleaning device with UV lamp. - Google Patents

Abstract

The present invention relates to an air cleaning device, comprising a housing formed with an air duct and having an air inlet and an air outlet, so that air containing contaminants can flow through the air duct to the air outlet via the air inlet, and at least one UV lamp disposed in the air duct for destroying at least part of the contaminants in the air that flows through the air duct past said at least one UV lamp, wherein at least one retardation element is provided in the air duct, which prolongs the residence time of air flowing through the air duct near said at least one UV lamp.

Description

Short indication: Air cleaning device with UV lamp.

DESCRIPTION

The present invention relates to an air cleaning device comprising a housing in which an air channel is formed with an air inlet and an air outlet, so that air with contaminating particles can flow through the air inlet through the air channel to the air outlet and at least one UV lamp which the air channel is provided for destroying at least a part of the contaminating particles in the air that flows through the air channel along the at least one UV lamp.

Such an air cleaning device is used as an extractor hood in kitchens, in particular large kitchens. The known extractor hood comprises a housing with an air inlet through which air can be drawn from a kitchen into the housing by means of a fan. The interior of the housing forms an air duct through which air drawn in in the housing flows to an air outlet. A number of UV lamps are provided in the air duct for destroying fats and the like. Air that passes through the UV lamps is then returned to the environment via the air outlet. The air outlet opens into the kitchen from which the air 20 is extracted via the air inlet, or into a building in which the kitchen is located.

The hygiene requirements, especially in professional kitchens for restaurants and institutions, are becoming increasingly strict. Therefore, the required effectiveness for extractor hoods that are used in such an environment is constantly increasing. A drawback of the known extractor hood is that although the extractor hood filters and destroys a large part of the fats and the like present in the air flowing in through the air duct, a considerable amount of fats and the like still passes through the UV lamps and through the air outlet from the air duct is steaming. The after-connection of additional filters or UV lamps increases the effectiveness of the extractor hood relatively little compared to the additional costs for the relevant adaptation of the air-cleaning device and possibly the thereby increasing energy consumption.

The present invention therefore has for its object to provide an air cleaning device according to the introduction with which fats and the like can be removed in a more effective manner from the air flowing through the air duct 1032593 2. This object is achieved by the present invention in that at least one delay member is provided in the air duct which extends the residence time of air flowing through the air duct in the vicinity of the at least one UV lamp. As a result, the air is exposed to the at least one UV lamp 5 for longer than in an air cleaning device without a delay member, whereby a larger part of the fats and the like passing through the air channel will be destroyed by the at least one UV lamp. The embodiment of the at least one delay member can be selected from a variety of embodiments, including relatively simple, inexpensive solutions and more complex solutions that may provide higher effectiveness.

It is preferable that the at least one delay member is provided downstream of the at least one UV lamp in the air duct. As a result, the air flow is partially blocked in such a way that an accumulation of air for the at least one delay member is created. This leads to a delay in the speed at which the air flow and thus the fat particles and the like carried by the air flow pass through the at least one UV lamp, which increases the chance that a fat particle or the like is exposed to the UV radiation for a sufficient time to thereby being destroyed. An additional effect is a compaction of the air, and therefore again of fat particles and the like, around the at least one UV lamp, because the air flow downstream of the at least one UV lamp is partially blocked. This increases the number of fat particles and the like in the vicinity of the at least one UV lamp, which also increases the chance of destruction thereof.

In a preferred embodiment of the present invention, the delay member comprises a bulkhead partially blocking the air duct. A baffle is easy to provide in the air duct and can effectively retard air flowing through the air duct.

The delay member preferably comprises a wall which largely encloses the air duct 30. Because the wall largely closes off the air duct, the air flow is delayed to a large extent and the direction of the air flow at the location of the wall is partly reversed. This increases the chance that a fat particle or the like present in the air stream is exposed to the at least one UV lamp for a sufficient time to be destroyed.

3

In order to prevent air flow through the air duct being completely or excessively blocked, the air duct is partially blocking bulkhead or the wall that largely closes off the air duct is provided with throughflow openings. The size of the flow openings can be selected depending on the application of the air cleaning device.

For a further increase in the effectiveness of the at least one UV lamp, the delay member comprises at least one swirl means for causing turbulence in the air flowing through the air duct near the UV lamp. The turbulence caused in the air stream increases the chance that fat particles and the like present in the air stream are exposed to the at least one UV lamp for a sufficient period of time, so that they are destroyed.

In a preferred embodiment according to the present invention, the at least one swirl element is attached to the wall which is substantially blocking the air duct. As a result, it is simply possible to arrange the swirling element in one operation with the wall channel blocking the air duct substantially oriented in one operation. However, it is also possible to provide separate swirling members if, as a result, a more desired turbulence can be produced in an air flow through the air duct.

In a preferred embodiment according to the present invention, a filter device is provided in the air duct upstream of the at least one UV lamp. In such an embodiment of the air-cleaning device, the filter device can filter a first important part of fat particles and the like present in the air, after which the at least one UV lamp is used for destroying the fat particles and the like passing through the filter have been allowed through. The combination of a mechanical grease filter and downstream UV lamps has proven to be very effective in practice. Due to the more effective manner in which the UV lamps can do their destructive work, a highly effective filter is also provided for the aforementioned combination of filter and at least one UV lamp, for example for professional kitchens.

The present invention will now be explained with reference to Figure 1 and only by way of example with reference to a description of an embodiment of the present invention.

Figure 1 shows a schematic view of a hood 4 according to the present invention with a housing 2, an air inlet 3 and an air outlet 4. A (mechanical) filter 5 is provided in the hood. A number of UV lamps 6 are also provided in the housing 2 within a cabinet 7, which is provided with a barrier wall 9 with through-flow openings 8 downstream of an air flow flowing through the extractor hood from the air inlet 4 to the air outlet 5. 7, provision is made for delaying and / or turbulence the air flow. These features include a curvature 10 in the barrier wall 9 at flow openings 8, a ribbed surface 11 of the barrier wall 9 between flow openings 8 and a conical protrusion 12a, 12b, 12c that extends between flow openings 8 from the barrier wall 9 against the direction of the air flow the barrier wall 9 protrudes. In the diagrammatic representation of figure 1, the measures taken at different places in the extractor hood 2 are included, but each said measure can contribute separately to the intended effect of air turbulence in the housing 2 near the UV lamps.

The operation of the extractor hood in figure 1 is as follows. When the extractor hood 1 is switched on, a fan (not shown) draws air from outside the extractor hood 2 through the air inlet 3 in the extractor hood, through the (mechanical) filter, past the UV lamps 6 through the flow openings 8 to the air outlet 4. It In this example, (mechanical) filter 5 is a so-called labyrinth filter in which air flowing through the labyrinth filter is deflected through curved channels in the labyrinth filter. Dirt or fat particles present in the air have a heavier specific gravity than the air in which they are located, so that they will experience a greater centrifugal force and, due to their slow deceleration, experience a greater deflection, as a result of which a part of the dirt and fat particles collide with walls of the labyrinth filter and the dirt and grease particles remain on the walls of the labyrinth filter. Dirt and fat are drained by gravity from the labyrinth filter, for example to a fat drawer (not shown).

In practice, the efficiency of existing mechanical filter devices proves insufficient for purifying air in, for example, professional kitchens of restaurants and institutions. Therefore, a number of UV lamps 6 are provided upstream with respect to the (mechanical) filter 5. The UV lamps expose the air flowing through cabinet 7 to UV radiation with the aim of still destroying dirt and grease particles that have passed the (mechanical) filter 5. The efficiency of destroying these dirt and grease particles depends, among other things, on the duration of irradiation, the distance at which the dirt and grease particles pass through the UV lamps and the intensity of the UV lamps. In order to positively influence a number of factors that influence the effectiveness of the UV lamps 6, a barrier wall 9 is provided close to the UV lamps upstream of said UV lamps, which barrier wall 9 comprises flow openings 8. The barrier wall 9 delays the flow rate of the air that flows through the cabinet 7, so that dirt and grease particles are on average exposed to the UV radiation of the UV lamps for longer than if the barrier wall 9 were not present. The barrier wall 9 is provided with a number of turbulence-generating measures, which cause a part of the air flowing through the cabinet 7 to be brought into turbulence, as a result of which the air will on average remain in the cabinet 7 for an even longer exposure of dirt. and fat particles on the UV lamps. In the exemplary embodiment shown in Figure 1, a number of such measures are shown. Although different turbulence-generating measures are provided for at the extraction hood 1 of Fig. 1 at different locations between flow openings 8, one type or only a few different types of turbulence-generating elements will probably be chosen in practice. The variety of measures in Figure 1 only serves to illustrate 20 different measures in a figure.

One of the measures to cause turbulence in the air flow through cabinet 7 is that the barrier wall 9 is slightly curled around through-flow openings 8, i.e. around the flow-through openings 8 there is a profile which is opposed to the direction of flow of air flowing through the cabinet 7 25 is directed. In addition to the relevant air being decelerated, air flows around the flow openings 8 against the air flow, so that again a part of that "fresh" air flow is counteracted. This results in swirls in the cabinet 7 which result in air being exposed to UV radiation from the UV lamps for longer than without the said measure.

Another example of turbulence-generating measures is a ribbed surface 11 of, at least a part of, the barrier wall. This ribbed surface 11 has the result that air colliding with this surface 11 is reflected back in different directions, which produces the same effect as described in the previous paragraph, albeit with a smaller local effect 6, but due to the size of the barrier wall 9 with sufficient effect to disrupt the air flow through the cabinet 7 such that air in the cabinet will be exposed to the UV lamps longer.

Yet another measure is a cone-shaped projection 12a, 12b, 12c which projects between flow openings 8 against the flow direction of the air through the casing 7 from barrier wall 9 against the air flow. These cone-shaped projections can vary in size as well as in shape and also contribute to the generation of turbulence in cabinet 7. Thus, the air flowing through the cabinet 7 is also exposed to the UV lamps for a longer time by means of such a measure.

The more often and the longer dirt and grease particles that are present in the air flowing through the cabinet 7 are exposed to the UV lamps, the greater the chance that the dirt and grease particles are exposed to the UV lamps in such a way that they thereby be destroyed. It will be clear that as a result of these measures the air which flows through the flow openings 8 in barrier wall 9 towards the air outlet 4 of the extractor hood 1 has a greater degree of purity than if such a barrier wall would not have been present with such measures . The delay and turbulence in the cabinet 7 thus contribute to cleaner air, without a noticeable increase in operational costs (read energy consumption) being necessary. A further advantage is that the measures in question can easily be arranged in existing extraction hoods, certainly when the relevant extraction hood is already provided with UV light lamps for destroying dirt and grease parts.

Above only one embodiment of the present invention has been discussed by way of example with reference to only a specific exemplary embodiment shown in Figure 1. It will be understood, however, that a person skilled in the art can easily devise equivalent or comparable measures for providing the same effect. . For example, there are many obvious ways for the average person skilled in the art to delay the air flow in the air duct. In the figures and the description, means for swirling the airflow are always connected to other means that slow down the airflow. Vertebral members can in themselves already cause a delay in the air flow and as such fall under the delay members mentioned in this document. The description and the figure are thus not to be interpreted as 7 limiting the scope of the present invention. The scope of the present invention is defined by the following claims.

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Claims (8)

An air cleaning device comprising a housing in which an air channel is formed with an air inlet and an air outlet, so that air with contaminating particles can flow through the air inlet through the air channel to the air outlet and at least one UV lamp provided in the air channel for the air outlet. destroying at least a part of the contaminating particles in the air that flows through the air channel past the at least one UV lamp, characterized in that at least one retarding member is provided in the air channel which reduces the residence time of the air in extends the vicinity of the at least one UV lamp. Air cleaning device according to claim 1, characterized in that at least one delay member is provided in the air channel downstream of the at least one UV lamp. 3. Air cleaning device as claimed in claim 1 or 2, characterized in that the delay member comprises a baffle blocking the air channel. 4. Air cleaning device as claimed in claim 1 or 2, characterized in that the delay member comprises a wall substantially closing off the air duct. 5. Air cleaning device as claimed in claim 3 or 4, characterized in that the partition partially blocking the air duct or the wall largely closing off the air duct is provided with throughflow openings. Air cleaning device according to one or more of the preceding claims, characterized in that the delay member comprises at least one swirl means for causing turbulence in the air flowing through the air duct near the at least one UV lamp. Air-cleaning device according to one or more of claims 4 to 6, characterized in that the at least one swirling element is attached to the wall which is substantially blocking the air duct. 8. Air cleaning device according to one or more of the preceding claims, characterized in that a filter device is provided in the air duct upstream of the at least one UV lamp. 1032593