HK40033751B - Air treatment device for a ventilation air inlet - Google Patents

Description

Air treatment device for ventilation air inlet

Technical Field

The present invention relates generally to air treatment devices, and in particular to an air treatment device for use in combination with a ventilation air intake or an air conditioning device.

Background

Different types of air treatment devices are often used to clean the air of contaminants. Air pollution levels are rising worldwide, especially in urban areas. In large cities where traffic congestion can at times severely degrade air quality, people often find it desirable to purify the air to protect themselves from inhalation of smoke or other forms of air pollutants.

One common method of cleaning air is to use air treatment devices placed in the room. A disadvantage of such an air treatment device is that contaminants from the outside enter the room before being removed by the air treatment device. Furthermore, to keep all the air of a room relatively clean, air treatment devices may consume a lot of energy and may generate noise, which may disturb people in the room.

Another alternative is to provide an air treatment device in the ventilation system or a filter in the ventilation system. However, maintenance of such filters can be difficult and easily forgotten.

US2007275651(Palmer David W) discloses a pneumatic control system comprising a system inlet, a system outlet and a variable speed fan configured to operate at a speed. A motor controller in communication with the fan is configured to control a speed of the fan. The differential pressure sensor is configured to monitor air pressure at the system inlet and air pressure at the system outlet. A closed loop pressure controller is in communication with the motor controller and the differential pressure sensor, wherein the pressure controller is configured to vary the speed of the fan based on a pressure differential between an inlet and an outlet of the system, thereby controlling the pressure within the space. An ultraviolet killing chamber may be disposed between the inlet and the outlet to expose the atmospheric particulate matter to UV radiation. The system may also have a filter located in the airflow path between the system inlet and the system outlet.

Therefore, there is a need for improved air purification of rooms.

Disclosure of Invention

It would be advantageous to achieve an air treatment device for a room that at least alleviates the above-mentioned disadvantages. To better address one or more of these issues, an air treatment device as defined in the independent claim is provided. Preferred embodiments are defined in the dependent claims.

Thus, according to one aspect, an air treatment device is provided. The air treatment device is intended to be arranged at a ventilation air inlet of a room or cabin, at an air inlet or an air outlet of an air conditioning device.

With this air treatment device, treated or cleaned air from the ventilation system of a building structure or vehicle, which is less polluted than the air already in the room, can be supplied to the room or cabin and can be installed and repaired more easily than a ventilation air filter. Furthermore, the air treatment device according to the invention may be used in combination with an air conditioning device arranged to heat or cool air in a room or compartment.

The ventilation air inlet allows air to enter the room from outside the room. Air enters the air treatment device according to the invention from the ventilation air inlet. The air flow generated by the fan in the air handling section is drawn from the space between the ventilation air intake and the air handling device and prevents air from the ventilation system from entering the room. The air flow also passes through a filter means in the air treatment section where the particles are removed before the treated air enters the room via the air outlet, thereby providing the room with treated air having fewer particles and contaminants than directly from the ventilation air inlet. In this way, the air treatment may be more efficient than previous solutions (e.g. air treatment devices arranged separately in a room).

The claimed air treatment device may also be arranged in combination with an air conditioning device. An air treatment device is arranged upstream or downstream of the air conditioning device to remove particles from the conditioned air distributed by the air conditioning device.

If the air treatment device according to the invention is arranged upstream of the air flow through the air conditioning device, the amount of particles settling on different surfaces within the air conditioning device is greatly reduced, which is advantageous in that the efficiency reduction of the conditioning device caused by settling particles on e.g. heat exchanger elements is delayed, i.e. the energy efficiency improves over time.

The control unit of the air treatment device is configured to adjust the speed of the fan based on the detected first and second pressures such that the air flow through the air treatment device corresponds to the air flow into the room or cabin or through the air conditioning device without restricting or reducing the expected and desired air flow.

The air treatment device is configured to measure a pressure difference between the airflow or pressure in the air entering or exiting the air treatment device and a pressure in the room outside the airflow through the air treatment device, and to adjust the speed of the fan based on the detected pressure difference.

In this way, the air flow through the housing can be adapted to the air flow from the ventilation air inlet or through the air conditioning device. The air handling portion may be configured to adjust the speed of the fan such that substantially all air from the ventilation air intake or the air conditioning device is moved into the housing by the fan, i.e., the first pressure and the second pressure may be substantially the same.

In this specification, the term "ventilation air inlet" is to be interpreted as an air ventilation inlet of a room or cabin. It may be a forced air inlet, i.e. air moved into a room or cabin by the air moving means, or it may be an opening. The air entering through the ventilation may be filtered or treated to remove contaminants or particulates, or may be untreated.

By "filtering means" is meant any device for filtering air, i.e. means for removing particles or contaminants from an air stream.

In an embodiment of the air treatment device, the control unit is configured to control the speed and the air flow of the fan such that the first pressure and the second pressure are approximately equal. The first pressure and the second pressure being approximately equal means that the pressure in the air stream or air flowing into or out of the air treatment device is approximately equal to the pressure outside the enclosed space in the room. That is, there is no overpressure or negative pressure in the air stream or air flowing into or out of the air handling device. In this manner, air may be drawn into the housing by the fan at the same speed (pace) as air enters or flows through the air conditioning unit through the ventilation air inlet.

This allows for the treatment of substantially all of the air entering the room or cabin, or conditioned by an air conditioning device, which can provide cleaner air in the room.

In one embodiment of the air treatment device, the air treatment section further comprises an ionization unit at the air inlet to ionize particles in the air flowing into the housing. The ionization unit may ionize the particles so that they may be more effectively filtered from the air flowing through the air treatment device. The provision of an ionization unit at the inlet of the housing to ionize the particles allows for a filter medium having a lower grade while still providing a high filtration efficiency, since the filter filters charged particles more easily than uncharged particles.

In one embodiment of the air treatment device, the ionization unit comprises: a collector electrode disposed around the air inlet; and an emitter disposed at a center of the inlet. The collecting electrodes may be arranged in such a way that all air passing through the inlet passes the collecting electrodes, which allows more efficient ionization of particles in the air flow. The arrangement of the emitter at the center of the inlet may mean that the maximum distance to the collector is minimized, which may result in a more efficient ionization of the gas flow.

In one embodiment of the air treatment device, the ionization unit is arranged upstream of the filter means. This is advantageous, for example, because the ionization unit may charge particles in the gas flow, which may increase the likelihood that the particles are subsequently captured by the filtering means.

In one embodiment of the air treatment device, the filtration means comprises a particulate filter medium, a molecular filter medium, or a combination thereof. This allows filtering out particles and ionized particles (if any) from the air stream passing through the filtering means.

In an embodiment of the air treatment device, the housing comprises a protruding portion extending from the air inlet side around the air inlet of the housing, said protruding portion being adapted to surround the ventilation air inlet of the room or the air outlet of the air conditioning device to form an at least partially enclosed space, such that air from the ventilation air inlet of the room or air from the air outlet of the air conditioning device enters the enclosed space before continuing into the air treatment device, said first pressure sensor being arranged to measure the pressure within the at least partially enclosed space. The "projection" can be understood as a part extending from the inlet side of the housing, so that it can surround the ventilation air inlet of a room or cabin or the outlet of an air conditioning device. It has been recognised that by surrounding the ventilation air inlet, the air can be treated as it enters the room instead of already in the room. By providing a protrusion extending from the back side of the housing, the air treatment device can be used on a variety of ventilation air intakes without having to adapt to the design of the exterior of the ventilation air intake or to be inserted into the ventilation air intake. This makes it easier to install the air treatment device in a room, since no or only little customization is required.

In one embodiment of the air treatment device, the protrusion has at least one opening for allowing air to flow into and out of the enclosed space. The at least one opening in the protrusion allows air to flow into and out of the enclosed space. This may be beneficial in cases where the fan is not calibrated to move the exact amount of air supplied by the ventilation air intake or the adjustment device outlet, which may be very common because such calibration may be difficult to perform and the air flow from the ventilation air intake or the adjustment device outlet may vary over time. In this way, if the ventilation air inlet or the air conditioning device outlet supplies more air than the air treatment device can treat, the air flows out of the enclosed space through the at least one opening, thereby avoiding partially blocking the ventilation air inlet. Similarly, if the ventilation air inlet provides less air than the fan may move, air may be drawn from a room outside the enclosed space through the at least one opening. It has also been realized that by providing openings on the protrusions, the risk of clogging of the ventilation device or overloading an existing ventilation device may be reduced. This allows the air treatment device to be used on any type of ventilation air intake, such as air supply or forced air. Due to the openings, there is no risk of blocking the ventilation air inlet, since air can flow or exit through these openings. This may be beneficial, for example, in the event of a fan failure, or because a user of the air treatment device wants to shut down the fan.

Similarly, due to the openings, there is no risk of a negative pressure being generated in the enclosed space defined by the wall and the protruding part, since air can enter through these openings. Thereby reducing the risk of overloading the fan, ventilation system or air conditioning device, for example by drawing in too much air from the ventilation facility and thereby impairing the ventilation of other rooms also connected to the ventilation facility.

In one embodiment of the air treatment device, the control unit is configured to adjust the speed of the air flow such that the first pressure is lower than the second pressure, thereby causing air to be drawn from the room through the at least one opening in the protrusion. In this way, air from the room may be drawn into the housing and air treatment section and thereby treated prior to entering the room. In addition to the air entering the room through the ventilation air inlet, air from the room may also be treated. This may reduce the amount of contaminants or particles in the air already present in the room.

In an embodiment of the air treatment device, the housing further comprises at least one housing side wall (130) arranged between the front side and the inlet side, and wherein the air outlet is arranged in the housing side wall. The housing sidewall may be disposed between the front side and the rear side. In this way, the housing may have a relatively large outlet. Furthermore, by providing outlets on or around the side walls of the housing, furniture or other items can be placed in front of the air treatment device without compromising its function or ventilation.

In one embodiment of the air treatment device, the filter means is arranged in at least one side wall of the housing and/or in a front side of the housing. This may allow for a larger filtering area or a larger air flow, i.e. the air treatment device may have a large capacity, since the air flow may leave the housing at the side walls of the housing, and the side walls of the housing may have a larger area than e.g. the front side of the housing. Having a larger area allows it to place larger filtering means. This further allows for a flatter air treatment device, which can be more easily installed in a room. Furthermore, by removing air from the sides of the housing, furniture or other items can be placed at the air treatment device without affecting its function or ventilation.

In one embodiment of the air treatment device, the housing is box-shaped with six side walls, and the air inlet and the air outlet are arranged in opposite side walls of the housing. This embodiment is advantageous when the air treatment device is used in combination with an air conditioning device, since the air flow flows directly through the air treatment device and the air conditioning device.

In one embodiment of the air treatment device, one side wall of the housing is intended to face a wall of a room or cabin, and the air flow through the air treatment device is substantially parallel to the wall of the room. This embodiment is advantageous when the air treatment device is used in combination with an air conditioning device, since one side of the housing may be mounted to a supporting wall upstream of the air conditioning device, and the air flow through the air treatment device and the air conditioning device is substantially parallel to this wall.

In one embodiment of the air treatment device, a first sensor is arranged in the air outlet side, which is intended to face the air inlet of the air conditioning device to measure the air pressure in the space between the air outlet side and the air inlet of the air conditioning device. This embodiment is advantageous when the air treatment device is arranged upstream of the air conditioning device to ensure that the control unit operates the fan at the required speed to provide the same air flow through the air treatment device as the air conditioning device.

In an embodiment of the air treatment device, the housing comprises a protrusion extending from the air outlet side around the air outlet in the housing, the protrusion being intended to surround the air outlet of the air treatment device to form an at least partially enclosed space such that air from the air treatment device enters the at least partially enclosed space before it continues into the air conditioning device, the first pressure sensor being arranged to measure the pressure within the at least partially enclosed space between the air treatment device and the air conditioning device.

Further objects, features and advantages of the present invention will become apparent when studying the following detailed disclosure, the drawings and the appended claims. Those skilled in the art realize that different features of the present invention can be combined to create embodiments other than those described in the following.

Drawings

The invention will be better understood from the following illustrative and non-limiting detailed description of preferred embodiments with reference to the attached drawings, in which:

fig. 1 shows a cross-sectional view of an air treatment device according to a first embodiment.

Fig. 2A shows a perspective view of an air treatment device to be mounted on a wall according to a first embodiment, and fig. 2B is a perspective view of an air treatment device mounted on a wall according to a first embodiment.

Fig. 3A illustrates a perspective view of a second embodiment of an air treatment device arranged on the downstream side of an air conditioning device, and fig. 3B illustrates an alternative housing design for this embodiment.

Fig. 4A illustrates a perspective view of a third embodiment of an air treatment device arranged on the upstream side of an air conditioning device, and fig. 4B illustrates an alternative housing design for this embodiment.

All the figures are schematic and not necessarily to scale, and are generally shown only as parts necessary for the clarity of the invention, wherein other parts may be omitted or merely suggested.

Detailed Description

Fig. 1 shows a cross-section of an air treatment device according to a first embodiment.

The air treatment device 100 includes a housing 104 having a front side 110, a rear side 120, and four housing sidewalls 130 disposed between the front side 110 and the rear side 120. The rear side contains the air inlet 121 and is also referred to as the inlet side of the housing. The housing sidewall contains an air outlet 131 and is also referred to as the outlet side of the housing.

The housing also includes a projection 140 extending from the inlet side 120. The protrusion 140 is arranged to form an enclosed space 180 with the wall 190 when the air treatment device 100 is arranged against the wall 190. The protrusion 140 has at least one opening 141 for allowing air to flow into the enclosed space 180 and out of the enclosed space 180.

The housing may contain different types of materials. Preferably, at least one side comprises a rigid material, such as a hard plastic, to support the air treatment section. Some of the sides may comprise a softer material. For example, in some instances, the front side 110 may comprise a fabric. The protrusion 140 may comprise a rigid material and/or a flexible material to enable the formation of the enclosure portion 180 with the wall 190 even if the wall 190 is not flat.

The air treatment device 100 is adapted to be arranged at a ventilation air inlet 160 provided in a wall of a room or vehicle cabin, such that the protrusion 140 is arranged at the wall 190 to form an enclosed space 180 surrounding the ventilation air inlet 160. The ventilation air inlet 160 may be any type of ventilation air inlet. Air entering the room via the ventilation air inlet 160 enters the enclosed space 180 formed by the wall 190, the inlet side 120 and the projection 140.

The air treatment device 100 further includes an air treatment unit 150. The air treatment section 150 includes a fan 152 configured to generate an air flow from the inlet 121 to the outlet 131. The air treatment device 100 also comprises a filtering means 159 for filtering particles from the air flow generated by the fan 152. In this example, the filtering means 159 is arranged at the outlet 131 of the housing side wall 130, but the filtering means 159 may be arranged in any manner such that the air flow passes through the filtering means 159. For example, the filtering means 159 may be arranged at the inlet 121.

The filtration means 159 may comprise a particulate filter media, a molecular filter media, or a combination thereof.

Optionally, the air treatment section 150 may further include an ionization unit 155. The ionization unit 155 includes an emitter electrode 157 disposed at the center of the air inlet 121 and a collector electrode 156 disposed around the air inlet 121. The emitter 157 may be disposed on the support portion 158 at the center of the inlet. The support portion 158 may be disposed on the inlet side of the housing. The ionization unit 155 may ionize particles in the air flow generated by the fan 152 so that they may be more easily filtered by the filtering means 159.

In this example, the ionization unit 155 is arranged upstream of the fan 152, which fan 152 is arranged in the housing. However, the ionization unit 155 may alternatively be arranged downstream of the fan 152.

The air treatment device 100 may function as follows. The air flow enters the enclosed space 180 through the ventilation air inlet 160. At least some air is drawn into the housing by the fan 152 and through the air treatment section 150. The air flow generated by the fan passes through an ionization unit 155, which in this example is arranged at the air inlet 121. The ionization unit 155 ionizes particles. The air flow passes through a filter means 159 in which the particles are filtered. The treated air exits the housing into the room through outlet 131.

The air treatment device may further comprise: a first pressure sensor 200 adapted to measure a first pressure in the enclosed space 180; and a second pressure sensor 210 adapted to measure a second pressure in the room outside the enclosed space 180. The pressure sensors 200, 210 may be any type of sensor suitable for measuring the air pressure in a room. In some examples, the sensors are arranged in one unit, or there is only one sensor. In some examples, the air treatment device may include a differential pressure sensor capable of measuring a pressure difference between the enclosed space 180 and a room outside the enclosed space 180.

The air treatment device 100 further comprises a control unit (not shown in the figure) for controlling the functions of the air treatment device 100. For example, the control unit may control the speed of the fan 152, or the control unit may process measurements from the sensors 200, 210, or based on a determined pressure difference between the enclosed space 180 and a room outside the enclosed space 180. The control unit may, for example, comprise a processing device, such as a microcontroller.

The air treatment section 150 may be configured to adjust the speed of the fan 152, i.e., how much air is drawn into the housing from the enclosed space 180, based on the detected first pressure and the detected second pressure.

For example, if the second pressure is higher than the first pressure, i.e., if the pressure in the room is higher than the pressure in the enclosed portion, the speed of the fan 152 may be reduced, as this indicates that the airflow generated by the fan may be greater than the flow provided by the ventilation air intake 160, and that air may be drawn in from both the ventilation air intake 160 and the room. In another example, the speed of the fan 152 may be increased if the second pressure is lower than the first pressure, i.e., if the pressure in the room is lower than the pressure in the enclosure portion 180. This may indicate that the ventilation air inlet 160 provides more air than the airflow into the housing generated by the fan 152. To avoid untreated air from entering the room, the speed of the fan 152 may be increased.

However, in some cases it may be beneficial to draw air from the room and treat it. For example, if the air treatment device 100 has been closed for a period of time, the window has been opened, or particles or contaminants have entered the room in another manner. This can be adjusted by the user via the control unit for the air treatment device. This will be described in more detail below with reference to fig. 2A and 2B.

A perspective view of the air treatment device 100 is shown in fig. 2A. FIG. 2B illustrates a perspective view of the air treatment device 100 shown in FIG. 2A disposed at the ventilation air inlet 160.

The air treatment device 100 is arranged to cover the ventilation air inlet 160. As described above, air may exit the air treatment device through the outlet 131.

The air treatment device comprises a control device 250 for controlling the operation of the air treatment device, such as the speed of a fan (not shown in fig. 2A or 2B) or switching the device on or off. The control device may comprise at least one button 251 for allowing a user to operate the air treatment device 100. Alternatively, the control device 250 may be connected to a remote control to allow a user to operate the air treatment device 100.

FIG. 3A illustrates a perspective view of a second embodiment of an air treatment device 300. This embodiment of the air treatment device is adapted to be used in combination with an air conditioning device 252, which air conditioning device 252 is intended to circulate air, for example in a room, to heat or cool the air to a desired temperature. The illustrated second embodiment of the air treatment device 300 is intended to be arranged on the downstream side of the air conditioning device, i.e. the conditioned air discharged from the air conditioning device is directed to the air treatment device 300 to reduce the number of particles in the indoor air.

In this embodiment of the air treatment device, the inlet side 302 of the housing 304 is a side surface facing the air outlet of the air conditioning device 252. An air inlet 306 of the air treatment device 300 is arranged in the inlet side 302 of the housing and an air outlet (8, not visible in fig. 3A) is arranged in the air outlet side 308, on the opposite side of the box-shaped housing as the inlet side. The box-shaped housing can also be embodied with outlets in the remaining two sides, so that it is possible to increase the filter area arranged in the side walls. This embodiment of the air treatment device comprises the same types of air treatment parts and components as the first embodiment described in detail above, arranged within the housing to ensure the desired purification of the air flowing through the air treatment device.

This second embodiment of the air treatment device may comprise a slightly modified housing illustrated in fig. 3B. The housing illustrated in fig. 3B includes a protrusion similar to the first embodiment described above. When the air treatment device 300 is arranged in a desired position adjacent to the air conditioning device 252, the protrusion 320 is arranged to form an at least partially enclosed space together with the outlet housing wall 260 of the air conditioning device 252. In this embodiment, the protrusion 320 may also include at least one opening 322 to more easily allow air to flow in and out of the at least partially enclosed space.

The air treatment device comprises a first pressure sensor 200 adapted to measure a first pressure in the at least partially enclosed space to enable the control unit to adjust the speed of the fan such that the air flow through the air treatment device corresponds to the flow through the air conditioning device.

The protrusion of the air treatment device is preferably arranged close to the outlet housing wall of the air conditioning device to ensure that as much air as possible discharged by the air conditioning device continues into the air treatment device, i.e. the distance between the outer edge of the protrusion and the air conditioning housing should not exceed 30 mm.

Fig. 4A-B show perspective views of a third embodiment of an air treatment device 400 intended to be positioned on the upstream side of an air conditioning device 252, the air conditioning device 252 being arranged to circulate air for conditioning the air temperature. The illustrated third embodiment of the air treatment device is intended to be arranged on the upstream side of the air conditioning device, i.e. first guided through the air treatment device before the air enters the air conditioning device. In this embodiment of the air treatment device, the air outlet and the outlet side of the housing face the air inlet of the air conditioning device. The air outlet 410 is arranged in the outlet side 408 opposite to the inlet side 402 of the box-shaped housing 404. This embodiment of the air treatment device includes the same components as the first and second embodiments described above.

In this embodiment of the air treatment device, the first pressure sensor 200 is adapted to measure a first pressure in the space between the outlet side 408 of the air treatment device and the air inlet wall 262 of the air conditioning device, so that the control unit can adjust the speed of the fan such that the air flow through the air treatment device corresponds to the air flow through the air conditioning device.

This third embodiment may include a projection 420 extending from the outlet side 408 of the housing to direct the flow of air from the air treatment device toward the air intake of the air conditioning device. When the air treatment device 400 is arranged in a desired position adjacent to an air conditioning device, the protrusion 420 is arranged to form an at least partially enclosed space with an inlet housing wall of the air conditioning device. If the housing is provided with a projection, the first pressure is measured in an at least partially closed space defined in the projection and in the outlet side of the housing. In this embodiment, the protrusion may also comprise at least one opening 422 for allowing air to flow in and out from the at least partially enclosed space more easily for the same reasons as described above.

The outlet side of the air treatment device or the edge of the projection of the air treatment device, if the device is provided with a projection, is preferably arranged close to the inlet housing wall of the air conditioning device to ensure that as much purified air as possible from the air treatment device continues into the air conditioning device, i.e. the distance between the outer edge of the outlet side or projection of the housing and the air conditioning housing should not exceed 30 mm.

While the invention has been illustrated and described in detail in the drawings and foregoing description, such illustration and description are to be considered illustrative or exemplary and not restrictive; the present invention is not limited to the disclosed embodiments. The skilled person appreciates that various modifications, changes, and variations are possible within the scope of the present invention as defined by the claims below.

In addition, variations to the disclosed embodiments can be understood and effected by those skilled in the art in practicing the claimed invention, from a study of the drawings, the disclosure, and the appended claims. In the claims, the word "comprising" does not exclude other elements or steps, and the indefinite article "a" or "an" does not exclude a plurality. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage. Any reference signs in the claims shall not be construed as limiting the scope of the claims.

Claims (14)

1. An air treatment device (100; 300; 400) intended to be arranged at a ventilation air inlet (160), at an air inlet or an air outlet of an air conditioning device (253) of a room or cabin, comprising:

a housing (104; 304; 404) having an air inlet side (120; 302; 402) and an air outlet side (110; 308; 408), the housing comprising an air inlet (121; 306; 406) arranged on the air inlet side of the housing and an air outlet (131; 310; 410) arranged on the air outlet side of the housing, such that air from a ventilation air inlet (160) of the room or cabin, or air entering an air inlet of the air conditioning device, or air from an air outlet of the air conditioning device, is directed through the housing;

an air treatment section (150) disposed in the housing, the air treatment section comprising:

a fan (152) for generating an air flow from the air inlet to the air outlet; and

a filtering means (159) arranged such that the air flow passes through the filtering means;

a first pressure sensor (200) adapted to measure a first pressure in the air flow or air flowing into or out of the air handling device;

a second pressure sensor (210) adapted to measure a second pressure around the air treatment device in the room or cabin outside of the airflow or air flowing into or out of the air treatment device; and

a control unit (250);

wherein the control unit is configured to adjust the speed of the fan based on the detected first pressure and the detected second pressure to generate an air flow through the air treatment device corresponding to the air flow from the ventilation air inlet to the room or compartment or the air flow into or out of the air conditioning device, and

wherein the housing comprises a protrusion (140; 320) extending from the air inlet side around an air inlet in the housing, the protrusion being adapted to surround a ventilation air inlet (160) of the room or cabin or an air outlet of the air conditioning device to form an at least partially enclosed space (180) such that air from the ventilation air inlet (160) of the room or air from the air outlet of the air conditioning device enters the enclosed space before it continues into the air treatment device, the first pressure sensor (200) being arranged to measure the pressure within the at least partially enclosed space; or

Wherein the housing comprises a protrusion extending from an outlet side of the housing to direct the air flow from the air handling device towards an air inlet of the air conditioning device, wherein the protrusion is arranged to form an at least partially enclosed space with an inlet housing wall of the air conditioning device.

2. The air treatment device of claim 1, wherein the control unit is configured to control the speed of the fan and the air flow such that the first and second pressures are approximately equal.

3. The air treatment device of any one of the preceding claims, wherein the air treatment portion further comprises an ionization unit (155) arranged at the air inlet to ionize particles in air flowing into the housing.

4. The air treatment device of claim 3, wherein the ionization unit comprises:

a collector electrode (156) disposed about the air inlet; and

an emitter (157) disposed at a center of the inlet.

5. An air treatment device as claimed in claim 3, wherein the ionising unit is arranged upstream of the filtering means.

6. The air treatment device of claim 1 or 2, wherein the filtration means comprises a particulate filter media, a molecular filter media, or a combination thereof.

7. An air treatment device according to claim 1 or 2, wherein the protrusion has at least one opening (141; 322) for allowing air to flow into and out of the enclosed space.

8. The air treatment device of claim 7, wherein the control unit is configured to adjust the speed of the air flow such that the first pressure is lower than the second pressure, thereby causing air to be drawn from the room through the at least one opening in the protrusion.

9. The air treatment device of claim 6, wherein the housing further comprises at least one housing sidewall (130) disposed between the front side and the inlet side, and wherein the air outlet is disposed in the housing sidewall.

10. The air treatment device of claim 9, wherein the filter means is arranged in the at least one side wall of the housing and/or in the front side (110) of the housing.

11. An air treatment device as claimed in claim 1 or 2, wherein the housing is box-shaped with six side walls and the air inlet and air outlet are arranged in opposite side walls of the housing.

12. An air treatment device as claimed in claim 11, wherein one side wall of the housing is intended to face a wall of the room or compartment, and the air flow through the air treatment device is substantially parallel to the wall of the room.

13. The air treatment device of claim 11, wherein the first pressure sensor is arranged at the air outlet side, which is intended to face an air inlet of the air conditioning device to measure the air pressure in a space between the air outlet side and the air inlet of the air conditioning device.

14. The air treatment device of claim 11, wherein the housing comprises a protrusion (420) extending from the air outlet side around the air outlet in the housing, the protrusion being intended to surround the air outlet of the air treatment device to form an at least partially enclosed space such that air from the air treatment device enters the at least partially enclosed space before it continues into the air conditioning device, the first pressure sensor (200) being arranged to measure the pressure within the at least partially enclosed space between the air treatment device and the air conditioning device.