EP4109004A2 - Air conditioning device - Google Patents

Abstract

The invention relates to an air conditioning device with an air duct housing (20) which has at least one air inlet (31.1) and at least one air outlet (31.2), a heat exchanger (24) and an air conveying device (31) being arranged in the air duct housing (20), wherein the heat exchanger (24) is arranged in the flow path between the air inlet (31.1) and the air outlet (31.2), and wherein in the area of the air inlet (31.1) and/or the air outlet (31.2) and/or in the flow path between the air inlet (31.1) and the air outlet (31 2) a filter arrangement (70) is arranged, wherein the filter arrangement (70) has a filter element (71) which has copper. For an effective reduction of the viral load in the conditioned air, the invention provides that the filter element (71) has a flat textile element, which in particular forms a fiber material, preferably a mesh, a knitted fabric or a tangle, and that a moistening device (74) is provided, which is connected to a water reservoir (27) via a delivery line (28.1), and that the moistening device (74) has at least one water outlet opening (73) which is assigned to the filter element (71) in such a way that water can flow out of the Water reservoir (27) on the filter element (71) can be conveyed.

Description

The invention relates to an air conditioning device with an air duct housing that has at least one air inlet and at least one air outlet, with a heat exchanger and an air conveying device being arranged in the air duct housing, with the heat exchanger being arranged in the flow path between the air inlet and the air outlet, and with in the region of the A filter arrangement is arranged in the air inlet and/or the air exclusion and/or in the flow path between the air inlet and the air outlet, the filter arrangement having a filter element which has copper in the region of its effective filter surface.

Such an air conditioning device is off WO 2006/019208 famous. In this air conditioning device, a fan and a heat exchanger are arranged in an air duct housing. The air duct housing has several air inlets, some of which can be optionally closed. An additional housing can be placed on the air duct housing in the area of an air inlet. This additional housing has its own fan and is equipped with a filter element. Ambient air can be sucked into the additional housing by means of the fan via a supply opening and guided through the filter element. In the direction of flow after the fan, the additional housing has an outlet opening that opens back into the environment. This outlet opening can optionally be opened or closed with a flap. In the closed state of the flap, a flow path is released, which opens into the air duct housing. Accordingly, the filtered air can be fed into the Air duct housing are promoted and air-conditioned there. When the flap is open, the ambient air is filtered and immediately discharged back into the environment through the outlet opening.

The filter element has a multi-layer structure. It has a first particulate filter backed by a copper filter. A silver filter is placed behind the copper filter. A dust separator is arranged downstream of the silver filter in the direction of flow. Ambient air can be cleaned and sterilized with this filter arrangement.

The object of the invention is to provide an air conditioning device of the type mentioned at the outset, with which viruses in the air guided through the air duct housing can be effectively killed in a simple manner.

This object is achieved in that the filter element has a flat textile element, the textile element forming in particular a fiber material, preferably a braid, a knitted fabric or a tangle, which has the copper that a moistening device is provided, which is connected via a conveyor line to a Water reservoir is connected, and that the moistening device has at least one water outlet opening, which is associated with the filter element such that water from the water reservoir can be conveyed to the filter element in order to moisten at least part of the copper material.

The inventors have recognized that copper has a suitable virucidal effect to kill viruses in the ducted air in the significant range. According to the invention, this effect is further improved if this is moistened. Accordingly, according to the invention, the flat textile element is moistened during the operational use of the air conditioning device via the moistening device with the water supplied from the water reservoir. In this case, the humidification can be carried out either permanently or at intervals, for example at constant intervals. It is also conceivable that a humidity sensor is used, with which the degree of humidity, for example of the filter element or in the vicinity of the filter element, in particular in the air flow after the filter element. In the event that the humidity falls below a predetermined threshold value, the humidification device can be activated and water can be refilled, for example.

According to a preferred variant of the invention, provision can be made for copper fibers to be inserted and/or applied into the fiber material of the filter element and/or directly onto the fiber material of the filter element. For example, the filter element may be such that it is formed from a braid or tangle into which copper fibers are woven. For example, a synthetic fiber knitted fabric, for example a polyester knitted fabric, can be used, into which the copper fibers are woven.

In other words, within the scope of the invention, a mesh or tangle of plastic fibers can form a support structure into which the copper threads are woven or onto which the copper threads are applied. It is preferably the case that the meshwork or tangle of plastic fibers is designed in such a way that it allows dust to be filtered.

A conceivable configuration of the invention can be such that the heat exchanger is designed as an evaporator which is connected to a refrigeration circuit via a refrigerant inlet and a refrigerant outlet, and that during operation of the air conditioning device the condensate occurring on the evaporator is fed to the water reservoir. In this way, the moisture separated from the conditioned air at the evaporator is used to allow the copper on the filter element to be humidified. This has the advantage that no external water supply or only a small amount of water has to be supplied externally in order to implement the function according to the invention. Of course, it can also be provided within the scope of the invention that an external water supply is provided additionally or alternatively.

In order to achieve safe and reliable moistening of the filter element in a simple manner, provision can be made for water to be conveyed from the water reservoir through the delivery line to the water outlet opening(s) by means of a pump. It is conceivable that the pump is connected to a control device which receives and processes the signal from a moisture sensor which is assigned to the filter element. If the moisture value falls below a threshold value, the control device activates the pump. The control device then switches the pump off again above a threshold value. If the air conditioner is not in operation, the pump is also deactivated with the control device.

According to a preferred variant of the invention, it can be provided that the moistening device has a large number of water outlet openings which are arranged, preferably equidistantly, from one another. In this way, the entire filter element or at least a large area of the filter surface can be moistened effectively, preferably evenly.

A good moistening effect can be achieved in particular if it is provided that the water outlet openings are arranged along an edge area of the flat textile element. Then the line routing for the water supply can also be selected in particular in such a way that the free air passage area of the filter element is not or only slightly influenced.

A simple design can be realized for the filter arrangement if it is provided that it has a carrier which has a support structure for the filter element or to which such a support structure is assigned, the support structure forming in particular a support grid that supports the filter element on the support structure rests, and that the carrier carries a line segment of the humidifier, the line segment having at least one water outlet opening.

If it is provided that the carrier is designed as a removable frame that can be exchanged with the air duct housing by means of quick-change fasteners connected, then a simple replacement or cleaning of the filter element can be carried out.

The object of the invention is also achieved with a filter element in the form of a flat textile element, which in particular forms a fiber material, preferably a braid, a knitted fabric or a tangle, copper fibers being used in the fiber material of the filter element and/or directly on the fiber material of the filter element and /or are applied, and wherein a moistening device is provided, which can be connected to a water reservoir via a delivery line, and that the moistening device has at least one water outlet opening, which is assigned to the filter element in such a way that water can be delivered from the water reservoir to the filter element .

• Fig. 1: eine Klimatisierungseinrichtung in perspektivischer Explosionsdarstellung,
• Fig. 2: eine Abdeckung für die Klimatisierungseinrichtung gemäß Fig. 1 in perspektivischer Darstellung,
• Fig. 3: eine Filteranordnung in perspektivischer Darstellung,
• Fig. 4 und Fig. 5 eine weitere erfindungsgemäße Filteranordnung in schematischer Darstellung und in verschiedenen Ansichten.

The invention is explained in more detail below with reference to an exemplary embodiment illustrated in the drawings. Show it:

• 1 : an air conditioning device in a perspective exploded view,
• 2 : according to a cover for the air conditioning device 1 in perspective view,
• 3 : a filter arrangement in a perspective view,
• 4 and 5 another filter arrangement according to the invention in a schematic representation and in different views.

figure 1 shows an air conditioning device that is designed in the form of a split device. This air conditioning device can be mounted inside a room. The air conditioning device forms a heat sink, for example by means of a heat exchanger 24, preferably an evaporator, and accordingly serves to absorb heat from the room. The air conditioning device can be connected to a condenser via refrigerant lines of a refrigeration cycle. The condenser is mounted outside the room.

The invention is not limited to split devices, rather it is also conceivable to use the arrangement according to the invention in combined devices in which the evaporator and the condenser are combined in one device, for example a device housing.

how figure 1 illustrated, the air conditioning device has an air duct housing 20 which has a mounting section 21 . The mounting section 21 is designed as a base from which the side walls 22 rise all the way around. With the assembly section 21 and the side walls 22, a receiving space 23 can be formed, within which air to be air-conditioned can be moved. In the receiving space 23, a heat exchanger 24 is mounted, which is presently designed as an evaporator of the refrigeration cycle.

The heat exchanger 24 can be connected to a refrigeration cycle via a refrigerant inlet 25 and a refrigerant outlet 26 so that the refrigerant carried in the refrigeration cycle can flow through the heat exchanger 24 . In the present embodiment, the heat exchanger 24 is ring-shaped. However, it can also have any other shape.

An air conveying device 31 is assigned to the heat exchanger 24 in the air duct housing 20 . The air conveying device 31 can be designed in the form of a fan. Preferably, the air conveyor 31, such as figure 1 shows designed as a radial fan to generate a high pressure difference can. However, it is also conceivable for the air conveying device 31 to be in the form of an axial fan.

The air conveying device 31 has an air inlet 31.1 and an air outlet 31.2. The heat exchanger 24 is arranged downstream of the air outlet 31.2 in the direction of flow.

The air conveying device 31 can be driven by a fan motor 30 . The fan motor 30 is connected to a voltage supply and can preferably also be connected to a control device 15 via a signal line in order to be able to change the operating state of the fan motor 30 depending on the operating states of the air conditioning device.

figure 1 also shows that the air duct housing 20 can be closed by means of a cover 40 . For this purpose, the cover 40 is placed on the ends of the side walls 22 facing away from the mounting section 21 and sealed here.

The cover 40 has a frame 41 which has a central receptacle 43 . An air guide element 42 with an air supply opening can be inserted into this receptacle 43 . The air guiding element 42 is designed and arranged in such a way that it is connected to the air inlet 31.1 of the air conveying device 31. In other words, ambient air can be guided via the air guiding element 42 to the air inlet 31.1 of the air conveying device 30.

The cover 40 also has at least one air outlet opening 45. In the present exemplary embodiment, several (four in the present example) air outlet openings 45 are distributed around the air supply opening 44 for the purpose of effective air discharge from the air duct housing 20.

The air outlet openings 45 are designed and arranged in such a way that they are spatially connected to the air outlet 31.2 of the air conveying device 31 in an air-conducting manner.

In other words, the air conveyed by the air conveying device 31 can be conveyed from the air outlet 31.2 through the air outlet openings 45 of the cover 40

how figure 2 shows, a screen 50 can be used, which can be placed on the cover 40 in order to optically close the air-conditioning device make possible. The panel 50 has a cover frame 51 with openings 52 and a filter holder 53 . The openings 52 communicate with the air outlet openings 45 of the cover 40. The filter holder 53 is arranged so that it communicates with the air supply opening 44 of the cover 40. FIG.

figure 1 FIG. 1 further shows that the air conditioning device can have a water reservoir 27. FIG. This water reservoir 27 can be designed as a container which is preferably arranged in the air duct housing 20 . Provision can particularly preferably be made for the water reservoir 27 to be arranged below at least part of the heat exchanger 24 in the direction of gravity. In this case, the assignment can be such that during the operational use of the air conditioning device, condensate which is precipitated from the air to be air-conditioned at the evaporator is routed directly or indirectly into the water reservoir 27 . Accordingly, the condensate is collected in the water reservoir 27 .

It is also conceivable within the scope of the invention for any other water reservoir 27 to be used. For example, the water reservoir 27 can also be a container which can be filled with water by a user. It is also conceivable that the water reservoir 27 is formed by an external water supply, for example by a fresh water supply line.

A delivery line 28.1 is connected to the water reservoir 27. A pump 28.2 is integrated into this delivery line 28.1. After the pump 28.2, the delivery line 28.1 forms a connection 28.3. The delivery line 28.1 can be routed to a filter arrangement 70, as will be explained in more detail later.

The air duct housing 20 can be inserted into an assembly housing 10 . This assembly housing 10 has a bottom 11 and side walls 12,13. The walls 12, 13 can be connected to each other with a corner piece 14. The control device 15 of the air conditioning device can be attached to the side of the mounting housing 10 . The controller 15 can also be positioned anywhere else. The control device 15 is used to control functions of the air conditioning device.

figure 3 shows a filter arrangement 70, which can be designed, for example, so that it can be installed in an exchangeable manner in the filter holder 53 of the air-conditioning device.

The filter arrangement 70 has a filter element 71 which is placed on a carrier 72 or inserted into a carrier 72 . In this case, the carrier 72 is designed in such a way that air can flow from an inflow side, which is assigned to the environment, through the filter element 71 and into the air-conditioning device.

The filter element 71 can be designed as a flat textile element, which in particular forms a fiber material, preferably a mesh, a knitted fabric or a tangle. Copper fibers are inserted or applied into the fiber material of the filter element 71 and/or onto the fiber material of the filter element 71 . The fiber material is preferably made of plastic fibers.

Provision can furthermore be made for the filter arrangement 70 to have a support grid 60 which supports the filter element 71 on the back, preferably on the side facing away from the surroundings.

how figure 3 can be seen, the filter assembly 70 can be designed so that it can be exchangeably connected to the filter holder 53, preferably by means of quick-change fasteners.

figure 5 illustrates that the filter arrangement 70 can have a moistening device 74 in the area of its carrier 72 . For example, the moistening device 74 can be formed by the carrier 72 or can be connected to the carrier 72 . The moistening device 74 has at least one, preferably a large number of, water outlet openings 73 .

how figure 4 shows, the moistening device 74 can comprise a line section over the length of which the water outlet openings 73 are distributed. The water outlet openings 73 are arranged in such a way that water which is supplied to the humidifying device 74 reaches or enters the filter element 71 via the water outlet openings 73 . In other words, the filter element 71 can be moistened by means of the moistening device 74 . It is preferably provided that the porosity of the filter element 71 is selected such that the supplied water is distributed at least in regions in the filter element 71 via the capillary effect of the filter element 71 . The water comes into contact with the copper threads or the copper elements which are integrated into the filter element 71 and/or placed on the filter element 71 . Accordingly, these copper components are then also wetted with water on their surface.

The wetting of the copper components of the filter element 71 with water according to the invention improves the virucidal effect of these components.

figure 4 shows that the moistening device 74 can have a connection 75 to which the delivery line 28.1 can be connected with its connection 28.3.

During operation of the air conditioning system, ambient air (see figure 3 : at point I) sucked in by means of the air conveying device 31 and guided through the filter element 71 . This air reaches the air inlet 31.1 of the air conveying device 30 (see figure 1 : at II). The air is accelerated by the air conveying device 31 and is preferably brought to a higher pressure level. The air then leaves the air conveying device 31 in the area of the air outlet 31.2 (see figure 1 at III). The air then enters the area of the heat exchanger 24, where its temperature level is reduced. As a result of this drop in temperature, moisture entrained in the air falls off the heat exchanger and deposits on the surface of the heat exchanger. This water gets at least partially into the water reservoir 27. After the air has been air-conditioned by the heat exchanger 24, it leaves the air-conditioning device through the air outlet openings 45 (see figure 1 at IV).

During operation, water is supplied to the humidifying device 74 permanently, at intervals or under the control of the control device 15 . In the present exemplary embodiment, it can be the case that the pump 28.2 is activated and transports water from the water reservoir 27 to the water outlet openings 73. As explained above, the copper components in or on the filter element 71 are thereby moistened. The ambient air guided through the filter element 71 is then guided past the copper components. Any viruses that may be carried along with the ambient air are effectively killed on the moistened copper components.

Within the scope of the invention, it can also be provided that a moisture sensor is used. This humidity sensor can, for example, directly determine the humidity of the filter element 71 or the humidity of the air downstream of the filter element 71 in the direction of flow. It is also conceivable that a differential measurement is carried out, with the humidity of the ambient air being measured in the direction of flow upstream of the filter element 71 using a 1st humidity sensor and the humidity of the air downstream of the filter element 71 being measured using a 2nd humidity sensor. The moisture sensor or sensors can be connected to the control device 15 by means of signal lines.

If the measured humidity falls below a threshold value, for example the control device 15 can activate the operation of the pump 28.2. If the humidity measured falls below a preset value, the control device 15 can deactivate the pump 28.2.

As explained above, the invention relates to an air conditioning device with an air duct housing 20 which has at least one air inlet 31.1 and at least one air outlet 31.2, with a heat exchanger (24) and an air conveying device 31 being arranged in the air duct housing 20. The heat exchanger 24 is in the flow path between the Air inlet 31.1 and the air outlet is arranged 31.2. In the area of the air inlet 31.1 and/or the air outlet 31.2 and/or in the flow path between the air inlet 31.1 and the air outlet 31.2 there is a filter arrangement 70 with a filter element 71 which has copper. The filter element 71 can preferably be designed as a flat textile element, to which a moistening device 74 is assigned. Water can be conveyed from a water reservoir to the filter element via a conveying line 28.1 in order to at least partially moisten the copper components of the filter element 71. This effectively reduces the virus load in the air-conditioned air.

Claims (10)

Air conditioning device with an air duct housing (20) which has at least one air inlet (31.1) and at least one air outlet (31.2), with a heat exchanger (24) and an air conveying device (31) being arranged in the air duct housing (20), with the heat exchanger (24 ) is arranged in the flow path between the air inlet (31.1) and the air outlet (31.2), and wherein in the area of the air inlet (31.1) and/or the air outlet (31.2) and/or in the flow path between the air inlet (31.1) and the air outlet ( 31 2) a filter arrangement (70) is arranged, the filter arrangement (70) having a filter element (71) which has copper,
characterized,
that the filter element (71) has a flat textile element, which in particular forms a fiber material, preferably a mesh, a knitted fabric or a tangle, and that a moistening device (74) is provided, which is connected to a water reservoir (27 ) is connected, and that the moistening device (74) has at least one water outlet opening (73) which is assigned to the filter element (71) in such a way that water can be conveyed from the water reservoir (27) to the filter element (71). Air conditioning device according to Claim 1, characterized in that copper fibers are inserted and/or applied into the fiber material of the filter element (71) and/or directly onto the fiber material of the filter element (71). Air conditioning device according to Claim 1 or 2, characterized in that the heat exchanger (27) is designed as an evaporator which is connected to a refrigeration circuit via a refrigerant inlet (25) and a refrigerant outlet (26), and that during operation of the air conditioning device at least a part of the condensate that has precipitated out of the air to be air-conditioned at the evaporator is fed to the water reservoir. Air conditioning device according to one of Claims 1 to 3, characterized in that water is conveyed from the water reservoir (27) through the conveying line (28.1) to the water outlet opening(s) (73) by means of a pump (28.2). Air conditioning device according to one of Claims 1 to 4, characterized in that the humidifying device (74) has a large number of water outlet openings (73) which are arranged, preferably equidistantly, from one another. Air conditioning device according to Claim 5, characterized in that the water outlet openings (73) are arranged along an edge region of the flat textile element. Air conditioning device according to one of Claims 1 to 6, characterized in that the filter arrangement (70) has a carrier (72) which has a support structure for the filter element (71) or to which such a support structure is assigned, the support structure being in particular a support grid ( 60) forms that the filter element (71) rests on the support structure and that the carrier (72) carries a line segment of the humidifying device, the line segment having the at least one water outlet opening (73). Air-conditioning device according to Claim 7, characterized in that the support (72) is designed as a removable frame which is connected to the air duct housing (20) in an interchangeable manner by means of quick-change fasteners. Filter element (71) in the form of a flat textile element, which in particular forms a fiber material, preferably a mesh, a knitted fabric or a tangle, with copper fibers being used in the fiber material of the filter element (71) and/or directly on the fiber material of the filter element (71). and / or are applied, and wherein a moistening device (74) is provided, which is connected via a conveyor line (28.1) to a water reservoir (27), and that the Humidifying device (74) has at least one water outlet opening (73) which is assigned to the filter element (71) in such a way that water from the water reservoir (27) can be conveyed to the filter element (71). Filter element according to claim 9, for use in an air conditioning device according to any one of claims 1 to 8.

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