EP3472528A1

EP3472528A1 - Cooling device for installing under a ceiling of a room

Info

Publication number: EP3472528A1
Application number: EP17725194.9A
Authority: EP
Inventors: Michael Freiherr; Alexander SALM
Original assignee: Guentner GmbH and Co KG
Current assignee: Guentner GmbH and Co KG
Priority date: 2016-06-17
Filing date: 2017-05-09
Publication date: 2019-04-24
Anticipated expiration: 2037-05-09
Also published as: WO2017215847A1; PL3472528T3; EP3472528B1; JP2019522165A; RU2731072C2; RU2018146516A; RU2018146516A3; CN109416194B; HUE049185T2; DE102016111136A1; CN109416194A; US20190178506A1

Abstract

The invention relates to an air cooler for cooling the air in rooms, in particular in storage rooms or cooling rooms in which persons can walk, which air cooler comprises: a housing (1), which has a bottom (1a), a cover (1b), which can be fastened directly and without spacing to a ceiling of the room to be cooled, and at least one side wall (1c), in which at least one air outlet (2) is arranged; at least one planar heat exchanger (3), which is arranged in the housing (1) and which lies at least substantially horizontal; and at least one fan (4) arranged in the housing (1) for sucking in air from the room to be cooled, wherein the air sucked in by the fan (4) flows through the planar heat exchanger (3) at least substantially in the vertical direction and is deflected by the fan (4) in the horizontal direction to the air outlet (2). In order to provide a highly efficient air cooler for cooling the air in large-volume storage rooms or cooling rooms, in particular storage rooms or cooling rooms in which persons can walk, which is arranged directly on a ceiling such that said air cooler can be installed in space-saving manner and which avoids the dripping of condensed water and the accumulation of dust and dirt, the fan (4) and the air outlet (2) are arranged above the heat exchanger (3) in the air cooler according to the invention.

Description

COOLING DEVICE FOR MOUNTING UNDER A ROOM CEILING

The invention relates to an air cooler according to the preamble of claim 1 and a method for cooling the air in rooms, especially in walk-in storage or cold rooms.

Generic air coolers are, for example. For cooling the air in large-volume rooms, such. B. walk-in storage or cold rooms used. The air coolers used for this purpose are part of the equipment of the storage or cooling room and installed in stationary. The air cooler contains a heat exchanger, for example in the form of a heat exchanger, on or through which the air to be cooled is passed or passed through, wherein the heat exchanger extracts heat from the air and cools it. The heat exchanger can be a heat exchanger which has a pipe or channel system through which a coolant or refrigerant flows. The heat exchanger can also be an evaporator which has a pipe or channel system through which a two-phase refrigerant flows. The pipe or channel system of the evaporator is coupled to a condenser or a recooler, which is regularly outside the space to be cooled, for example. On the roof of the building in which the storage or cooling room is located. The refrigerant is filled only after the installation of the cooling system, consisting of the arranged in the storage or cooling chamber air cooler and the external condenser or recooler in the condenser or recooler. The condenser or recooler is connected via pipelines to the evaporator of the air cooler to direct the refrigerant in the liquid state and at low pressure through the evaporator. As it flows through the air to be cooled of the storage or cooling space through the evaporator evaporates the first liquid refrigerant and removes the air flowing through heat. The vaporized refrigerant is returned via the pipe into the condenser or recooler to be liquefied there by compression or cooled.

From JP 2009 024 936 A, an air conditioner is known, which has a housing which can be installed on a ceiling, in which a radial fan is arranged. The centrifugal fan sucks ambient air through one at the bottom of the housing arranged air inlet and blows the sucked air in the radial direction through laterally arranged in the housing air outlets. In each case a heat exchanger is arranged in the air outlets through which the air blown out by the centrifugal fan is passed and thereby cooled. The radial fan and the heat exchanger are in each case at the same height with the air outlets arranged laterally in the housing.

Another air conditioner of this type is known from JP 06 137 558 A. Also, this air conditioner comprises a housing which can be installed on a ceiling, in which a diagonal fan and a heat exchanger are arranged. The diagonal fan sucks in ambient air through a suction opening arranged on the underside of the housing, in which the heat exchanger is arranged. The sucked air flows through the areally formed and substantially horizontally lying heat exchanger and is thereby cooled. The sucked and cooled air is guided by the diagonal fan obliquely upwards and deflected by means of guide elements obliquely downwards in the direction of laterally arranged in the housing air outlets. The cooled air flows through the air outlets back into the room.

These known air conditioners are typically used for the air conditioning of smaller spaces, such as e.g. Residential and office space used to produce a comfortable room temperature in the range of 20 ° C to 25 ° C. When using such air conditioners in large-scale storage or cooling rooms in which much lower cooling temperatures in the range of below 16 ° C to be generated, there is a risk that forms condensate in the air conditioner, especially on the pipes and fins that from the air conditioner can drip. In an arrangement of the fan below the heat exchanger, the water droplets of condensed water can be sprayed in the fan and blown with the cooled air from the air outlets, thereby creating an unwanted droplet throw in the room. The same can happen even if the fan is located above the heat exchanger when the fan is operated at high power (high speed).

From US 2006/0130 517 AI a cooling system for large-volume rooms, eg. For walk-in cooling and storage rooms is known, which comprises a arranged in the space to be cooled evaporation device and thus connected via piping external compressor and a downstream condenser, the outside to Cooling space are arranged. In the external compressor, a refrigerant carried in a piping system is compressed and liquefied in the downstream condenser and then passed in the liquid state through the piping into the evaporator. Before the refrigerant enters the evaporator, the liquid refrigerant flows through an expansion valve to drain the refrigerant. The cooling system can be operated either with a single-phase or a two-phase refrigerant, wherein the evaporator arrangement during operation of the system with a single-phase refrigerant acts as a simple heat exchanger and when operating with a two-phase refrigerant as an evaporator in which evaporates the expanded refrigerant through the expansion valve and - After it has been heated by the passing ambient air - passed in gaseous state through the pipes back to the compressor and liquefied there again.

The evaporator device comprises a housing in which two microchannel evaporators are arranged. In the housing further comprises a planar and covered by a grille air inlet and a likewise flat trained and covered by a grille air outlet, wherein the air inlet and the air outlet are arranged in opposite walls of the housing and the microchannel evaporator therebetween. In the housing, a plurality of fans are further arranged, which are coupled to the microchannel evaporators to direct air through the evaporator means. For this purpose, ambient air is sucked through the air inlet and blown out of the housing through the air outlet. The ambient air drawn in by the fans is passed or passed through the microchannel evaporators, which cools the air. The housing of the evaporator device can be placed in the walk-in storage or cooling room or suspended from the ceiling, so that between the ceiling and the top of the housing remains a free space that allows the inflow or outflow of air. The installation of the housing on the bottom of the Lagerbzw to be cooled. However, the refrigerator requires a lot of space, which is no longer available as a storage room. A suspended arrangement of the evaporator device on the ceiling of the accessible storage or cooling space has the disadvantage that dust and dirt can be deposited on the horizontal upper side of the housing on which the air inlet or the air outlet is arranged. This is particularly problematic in storage and cold storage for food, as the stored material can be contaminated, resulting in hygiene problems. Furthermore, in this evaporator device, the condensation that adheres to precipitates the piping and fins of the microchannel evaporator, dripping out through the air outlet (or air inlet).

On this basis, the invention is based on the object to provide a highly efficient air cooler for cooling the air in large-volume and especially walk-storage or cold rooms, which has a housing which is arranged on a ceiling of the space to be cooled and which the disadvantages of Known in the prior art cooling equipment and in particular the dripping of condensation and the accumulation of dust and dirt on the top of the suspended from the ceiling cooling equipment avoids. The air cooler should be space-saving installable in the room to be cooled and in particular be as low as possible to allow installation on the ceiling, without significantly reducing the room height.

This object is achieved with an air cooler with the features of claim 1 and with the method for cooling the air in rooms with the features of claim 14. Preferred embodiments of the air cooler according to the invention will become apparent from the dependent claims.

The air cooler according to the invention comprises a housing with a bottom, a lid which can be fastened directly and without clearance to a ceiling of the space to be cooled and at least one side wall, in which at least one air outlet is arranged, and at least one planar and substantially configured one in the housing horizontally lying heat exchanger and at least one arranged in the housing above the heat exchanger fan. The fan sucks ambient air from the space to be cooled through an air inlet and the sucked air flows at least substantially in the vertical direction through the planar heat exchanger and is deflected by the fan in the horizontal direction to the arranged in the side wall of the housing air outlet. According to the invention, the fan and the air outlet are above the heat exchanger.

By this arrangement it is possible that the sucked air flows through the flat heat exchanger at least substantially perpendicular to its plane and leave the housing through the at least one laterally disposed air outlet and can flow back into the room. This will create a large effective heat transfer area and thus ensuring a good heat transfer efficiency. Furthermore, a vertical air flow of the cooled air from the housing into the space to be cooled is prevented because the cooled air leaves the housing through the at least one lateral air outlet in a substantially horizontal flow direction. This prevents unpleasant vertical air currents in the room to be cooled and allows a uniform distribution of the cooled air in the room.

The immediate arrangement of the cover of the housing on the ceiling of the room to be cooled, without space between the ceiling and the cover of the housing, prevents dust and dirt from depositing on the top of the lid.

The inventive arrangement of the fan, the at least one air outlet and the heat exchanger in the housing of the air cooler also allows the arrangement of a pan for collecting condensation, located on the outer surface of the heat exchanger, in particular on the fins and the pipes of a finned heat exchanger or a Mikrokanalverdampers, can form. For this purpose, a recess is expediently formed in the bottom of the housing, or it is arranged in the interior of the housing a collecting trough on the floor. The condensation, which forms on the outer surface of the heat exchanger and drips from there due to gravity, can collect in the depression of the soil or in the arranged on the bottom drip tray and be discharged via a at the lowest point of the depression or the drip tray opening drain line.

The air inlet, through which the ambient air is sucked by the fan into the interior of the housing, is expediently arranged below the heat exchanger and - as the at least one air outlet - in a side wall of the housing. This ensures, on the one hand, that the entire ambient air flowing into the housing is conducted through the heat exchanger, whereby a very efficient heat transfer can be produced. On the other hand, the arrangement of the at least one air inlet in a side wall of the housing prevents unpleasant air flows in the space to be cooled in the vertical direction. Suitably, several air inlets and several air outlets are provided in the housing. The housing may be cylindrical and have a cylinder jacket-shaped side wall. In this embodiment of the air cooler according to the invention, it is expedient to provide the air inlet and the air outlet at diametrically opposite points of the cylinder jacket-shaped side wall. With several air inlets and outlets these are expediently arranged alternately and uniformly around the circumference of the side wall of the cylindrical housing.

The housing may also be formed cuboid with four mutually perpendicular side walls, expediently in the or each side wall, in which an air outlet is provided, no air inlet is arranged, and vice versa. This prevents that already cooled air leaving the housing through an air outlet can be sucked back into the housing directly through an air inlet arranged adjacent to the air outlet.

Between the two-dimensional and at least substantially lying in a horizontal plane heat exchanger and the fan, a partition plate is preferably arranged, in which an air passage opening is formed. The air passage opening in the partition plate is aligned with the fan, ie the air passage opening is coaxial with the axis of rotation of the fan and the diameter of the air passage opening corresponds at least substantially to the diameter of the fan, which is typically in the range of 200 to 400 mm, but also up to 1200 mm can be large. The ambient air sucked in laterally from the fan through the air inlet flows into the housing at least substantially in the horizontal direction and is deflected there by the negative pressure generated by the fan in the area above the partition plate in the vertical direction and flows first through the flat heat exchanger and then through the air passage opening in the partition plate in the fan. The partition plate divides the interior of the housing in a horizontal plane and ensures that the ambient air sucked in by the fan can flow at least substantially completely in the vertical direction through the heat transfer in a planar manner. By dividing the interior of the housing by means of the partition plate, a decoupling of the flow of the sucked ambient air in the vertical direction by the heat exchanger and the outflow of the cooled air in an at least substantially horizontal flow direction is ensured by the at least one air outlet. This can cause air turbulence inside the Housing and consequently a reduction in heat transfer efficiency can be avoided.

As in US 2006/0130517 A1, the heat exchanger can be designed as a microchannel evaporator or, alternatively, as a lamellar heat exchanger, in both cases the air drawn in flows parallel to the lamellae of the heat exchanger or the evaporator, namely in the case of a Lammellen heat exchanger parallel to the fins of the heat exchanger and in the case of a microchannel evaporator parallel to the zig-zag between the parallel microchannels of the microchannel evaporator arranged lamellae. In both cases, the sucked air flows perpendicular to the flow direction of the flowing through the tubes or channels of the heat exchanger refrigerant. This also ensures a large heat transfer surface and thus efficient heat transfer. These and other features and advantages of the invention will become apparent from the embodiments described in more detail below with reference to the accompanying drawings. The drawings show:

Figure 1: Perspective view of a first embodiment of an air cooler according to the invention with a housing and arranged therein

Fan and a heat exchanger designed as a heat exchanger, wherein the front side wall of the housing is removed for the representation of the housing interior; Figure 2: elevation of the embodiment of an air cooler according to the invention of Figure i;

Figure 3 is a perspective detail view of the heat exchanger and the fan of the embodiment of the air cooler of Figure 1, wherein for better illustration, the front and the rear side wall and the lid of the housing and a partition plate are not shown;

Figure 4: detailed perspective view of the lid and the upper portion of the lateral side walls of the housing with a horizontal partition plate of Embodiment of the air cooler of Figure 1, wherein for better illustration of the heat exchanger is not shown; detailed perspective view of the heat exchanger of the embodiment of the air cooler of Figure 1 (Figure 5 a) and a schematic representation of the air flow through the heat exchanger (Figure 5b).

6 shows a perspective view of a second embodiment of an air cooler according to the invention with a heat exchanger designed as an evaporator, with the front side wall of the housing being removed for the purpose of depicting the interior of the housing;

Elevation of an embodiment of an air cooler according to the invention compared to the embodiment of Figure 6 with a pan for collecting condensation water;

FIG. 8 shows a perspective detailed representation of the evaporator

Heat exchanger of the embodiment of the air cooler of Figures 6 and 7.

The exemplary embodiment of an air cooler shown in FIGS. 1 to 5 for cooling the air in large-volume rooms, in particular in walk-in storage or cooling rooms or cooled working spaces (in particular in the food industry, eg in slaughterhouses), comprises a cuboidal housing 1 with a horizontal lying floor la, a parallel and spaced apart lid lb and four perpendicular to each other and to the bottom or lid standing side walls lc. In the housing 1, a fan 4 and a heat exchanger 3 is arranged, wherein the heat exchanger 3 is formed in the embodiment of Figures 1 to 5 as a heat exchanger. The flat-shaped heat exchanger, which is shown in Figures 3 and 5 respectively in a perspective view in detail, is arranged in the interior of the housing in a horizontal position. The fan 4 may be a radial or a diagonal fan. The lid lb can be attached directly and without clearance to a ceiling of the room to be cooled, so that the air cooler can be arranged without gaps on the ceiling. This can be done, for example, by attaching the lid lb via fastening means or a frame on the underside of the ceiling.

The interior of the housing 1 is divided by a horizontal partition plate 6 in a lower space and an upper space, wherein the fan 4 are arranged in the upper space above the partition plate 6 and the heat exchanger 3 in the lower space below the partition plate 6. In the center of the partition plate 6, a circular air passage opening 6a is provided, which is aligned with the fan 4 arranged above in such a way that the air passage opening 6a is arranged coaxially to the axis of rotation of the fan 4 and has a diameter which is at least substantially the diameter of the fan 4th equivalent. In the lower space of the housing 1 air inlets 5 are provided on opposite side walls lc. The air inlets 5 are formed by openings in the side walls lc. Suitably, an air filter 9 is arranged in each of these openings.

In the upper space of the housing 1 lc air outlets 2 in the form of openings in the side walls lc are also provided in opposite side walls. Outside the housing are in the area of the air outlets 2 more baffles 10 or blind slats parallel to each other and spaced from each other and have obliquely downwards. The baffles or the Venetian blinds are preferably movable and expedient motorized, so they can be closed, for example, in a defrost.

The bottom la contains a sloping towards the center, in particular spherical depression whose lowest point opens into a drain line, not shown here.

The heat exchanger 3 embodied as a heat exchanger in this exemplary embodiment is shown in detail in FIGS. 3 and 5 and comprises distributor lines 3c which run parallel to a side wall 1c of the housing 1 along an x-direction and are connected to transverse lines 3b arranged perpendicular thereto (FIG. as shown in Fig. 5a). The transverse lines 3b extend along a z-direction. Slats 3a are arranged transversely to the transverse lines 3b, which extend in an xy plane and in the z direction at a distance are arranged to each other. Through the distribution lines 3 c and the transverse lines 3b, a coolant, for example. A glycol-containing coolant, passed. For this purpose, the distribution lines 3c are coupled to a coolant circuit, is passed through the cooled coolant in the transverse lines 3b and is returned from there to re-cooling again. To cool the coolant, the coolant circuit contains a recooler, which is expediently arranged outside the space to be cooled, for example, on a building roof.

For cooling the air in the storage or cooling space in which the air cooler is arranged, ambient air is sucked in by means of the rotating fan 4 through the air inlets 5. The sucked air flows in a substantially horizontally extending inlet flow through the air inlets 5 in the lower chamber of the housing 1 and due to the negative pressure generated by the fan 4 in the upper space in at least substantially vertical direction through the heat exchanger 3. While flowing through the sucked air through the heat exchanger 3, the air is deprived of heat, whereby the air is cooled. The heat extracted from the air is taken up by the coolant circulating in the heat exchanger and removed to the recooler in order to cool the coolant coming from the heat exchanger 3 and heated again. In Figure 5b, the air flow through the formed as a plate heat exchanger heat exchanger 3 is shown schematically. The sucked into the interior of the housing 1 air flows in the vertical direction (y-direction) through the flat heat exchanger 3 and flows in particular past the transverse lines 3b, through which flows the (cold) coolant. The transverse to the transverse lines 3b arranged fins 3a, which like the pipes of the distribution and the transverse lines, of a thermally conductive material, for example. From a metal, preferably aluminum, formed thereby increase the effective heat exchange surface between the air flow to be cooled and the Pipes of the heat exchanger 3. The air flows perpendicular to the flow direction of the flowing through the transverse lines 3b coolant.

After flowing through the heat exchanger 3, the cooled air flows through the air passage opening 6a in the partition plate 6 in the upper space of the housing 1 and is deflected there by the fan 4 in a horizontal direction. The horizontally deflected and cooled air eventually flows in a substantially horizontal outlet flow through the air outlets 2 out of the housing 1 and is thereby unglenkt by the baffles 10 obliquely downwards.

Condensation, which can form on the pipes and the fins of the heat exchanger 3, drips from there due to gravity and can be collected in the recess of the bottom la and discharged through the drain line.

In Figure 4, the upper part of the housing 1 is shown in a perspective view, wherein the front side wall is removed for clarity. From Figure 4, in particular, the horizontal partition plate 6 with the central air passage opening 6a and the fan 4 arranged above can be seen. The arranged below the partition plate 6 heat exchanger is not shown in the illustration of Figure 4 for reasons of clarity. For mounting the heat exchanger 3 on the housing 1 on the side walls lc inwardly projecting support plates 11 are formed. On these support plates 11, the lateral edge regions of the heat exchanger 3 and in particular its distribution lines 3 c can be placed and secured to hold the heat exchanger 3 in an at least substantially horizontal position.

In Fig. 6, another embodiment of an air cooler according to the invention is shown, this embodiment corresponds to the heat exchanger 3, the embodiment of Figures 1 to 5. In the embodiment of Figure 6, the heat exchanger 3 is designed as an evaporator and in particular as a micro-channel evaporator. The designed as a microchannel evaporator heat exchanger 3 of the embodiment of Figure 6 is shown in Figure 8 in detail. It comprises lateral, parallel and along the x-direction spaced apart extending manifolds 3 c, which are connected to a plurality of perpendicular thereto (in the z-direction) extending, flat transverse channels 3d. The transverse channels 3d are internally subdivided into several (eg 10 to 15) microchannels which have a diameter or a width / height of 1 to 2 mm, respectively. Via the distributor pipes 3 c, a two-phase refrigerant is passed into the microchannels of the transverse channels 3d. Between the x-direction in the spaced-apart transverse channels 3d zigzag-shaped extending lamellae 3e are arranged. The distribution pipes 3 c are coupled via a piping system to an external compressor and a subsequent condenser, both of which are arranged outside the space to be cooled, for example. On a building roof. In the compressor, the refrigerant is compressed and liquefied in the subsequent condenser and passed through the piping to the heat exchanger 3. Upstream of the heat exchanger 3, an expansion valve is arranged so that the passed and initially liquid refrigerant can expand and evaporate. When passing the expanded refrigerant through the microchannels of the microchannel evaporator, the refrigerant vaporizes and absorbs heat from the air flowing through the heat exchanger 3. The air flows in the vertical direction (y-direction) parallel to the slats 3e through the microchannel evaporator and is cooled by discharging the heat to the heat exchanger 3. The vaporized refrigerant of the microchannel evaporator flows from the transverse channels 3d back into a distribution line 3 c and is returned from there via the piping system in the compressor and the subsequent condenser, where it is again compressed and liquefied.

In order for an oil contained in the refrigerant used (which is required for the lubrication of the compressor) to be discharged from the pipelines of the microchannel evaporator and, in particular, from the microchannels of the transverse lines 3b when the refrigerant is exchanged, it is expedient in this embodiment to use the flat heat exchanger 3 not exactly in a horizontal position to position, but to maintain a low inclination to the horizontal of about 1 ° to 3 °. A slight inclination of the heat exchanger 3 relative to the horizontal is also recommended when using a heat exchanger as a heat exchanger when it is operated with a two-phase and an oil-containing refrigerant, which is compressed in a downstream arranged external compressor. FIG. 7 shows a modified variant of the embodiment of FIG. Like the air cooler of FIG. 6, the air cooler of the exemplary embodiment of FIG. 7 also has a heat exchanger 3 embodied as a microchannel evaporator. Unlike the embodiment of Figure 6, in which a recess for collecting condensed water is formed in the bottom 1a (as in the embodiment of Figure 1), the embodiment of Figure 7 includes a sump 8 in which condensate can be collected , Suitably, the drip tray 8 is slightly inclined relative to the horizontal, for example. In an angular range of l ° -5 °. On an inclined side, the drip pan 8 contains a drain line 12, via which the collected condensation water can be removed and, in particular, sucked off. The drip tray is appropriately dimensioned that it covers or covers the floor plan of the overlying heat exchanger, so that any condensation that drips on the pipes and fins of the heat exchanger can be completely collected. The invention is not limited to the exemplary embodiments illustrated in the drawings. Thus, for example, instead of a microchannel evaporator, a finned tube heat exchanger or evaporator (fm-and-tube heat exchanger) can be used as a heat exchanger. The heat exchanger can, in accordance with the above embodiments, flat or curved, in particular concave, be. Further, a plurality of fans and heat exchangers may be arranged in the housing 1, wherein suitably alternately (from bottom to top) depending on a heat exchanger and a fan can be arranged in blocks one above the other.

The air coolers according to the invention are expediently dimensioned such that they produce a heat output in the range of> 1 kW. This allows room temperatures in the range of 4 to 16 ° C to be achieved.

Claims

Expectations

1. Air cooler for cooling the air in rooms, in particular in walk-in storage or cold rooms, comprising a housing (1) with a base (la), a cover (lb) which can be attached directly and without a distance to a ceiling of the room to be cooled, and at least one side wall (lc), in which at least one air outlet (2) is arranged, at least one flat heat exchanger (3) arranged in the housing (1) and lying at least essentially horizontally, and at least one fan (4) arranged in the housing (1). ) for sucking in air from the room to be cooled, with the air sucked in by the fan (4) at least in

Flows essentially in the vertical direction through the flat heat exchanger (3) and is deflected by the fan (4) in the horizontal direction to the air outlet (2), characterized in that the fan (4) and the air outlet (2) above the heat exchanger (3 ) are arranged.

2. Air cooler according to claim 1, characterized in that at least one air inlet (5) is arranged in the housing (1) below the heat exchanger (3).

3. Air cooler according to claim 1 or 2, characterized in that an air inlet (5) is arranged in at least one side wall (lc).

4. Air cooler according to claim 2 or 3, characterized in that the housing has four side walls (la, lb, lc, ld) and that in the or each side wall (la, lb) in which an air outlet (2) is provided , no

Air inlet (5) is arranged, and vice versa.

5. Air cooler according to one of the preceding claims, characterized in that a separating plate (6) with an air passage opening (6a) is arranged between the heat exchanger (3) and the fan (4).

6. Air cooler according to claim 5, characterized in that the

Air passage opening (6a) is aligned with the fan (4) arranged above the separating plate (6).

7. Air cooler according to claim 5 or 6, characterized in that the air sucked in laterally through the air inlet (5) flows into the housing at least essentially in a horizontal direction and is deflected there in a vertical direction, flows vertically through the heat exchanger (3) and into vertical direction flows into the fan (4) through the air passage opening (6a).

8. Air cooler according to one of the preceding claims, characterized in that the heat exchanger (3) is designed as a microchannel or as a finned heat exchanger.

9. Air cooler according to claim 8, characterized in that the sucked in air flows through the heat exchanger (3) parallel to the fins of the finned heat exchanger or parallel to the zigzag-shaped fins of the microchannel heat exchanger.

10. Air cooler according to one of the preceding claims, characterized in that the heat exchanger (3) contains pipes (3a) or channels (3b) through which a refrigerant flows.

11. Air cooler according to claim 10, characterized in that the sucked in air flows through the heat exchanger (3) perpendicular to the flow direction of the refrigerant flowing through the tubes (3a) or channels (3b) of the heat exchanger (3).

12. Air cooler according to one of the preceding claims, characterized in that the base (la) has a depression or a trough (8) for collecting condensation.

13. Air cooler according to one of the preceding claims, characterized in that the fan (4) is designed as a radial or diagonal fan.

14. Method for cooling the air in rooms, in particular in walk-in storage or cold rooms, the air to be cooled being sucked into a housing (1) of an air cooler with a fan (4), there through a flat and at least essentially horizontal heat exchanger (3 ) and is blown out of the housing (1) by the fan (4) via at least one side air outlet (2), the fan (4) and the air outlet (2) being arranged above the heat exchanger (3) and which are blown out by the fan ( 4) sucked in air flows at least substantially in the vertical direction through the flat heat exchanger (3) and is deflected by the fan in the horizontal direction to the side air outlet (2).