DE202011104885U1 - Air conditioner with condensate drain - Google Patents

Abstract

Air conditioning unit, with - a heat exchanger (4) through which a refrigerant can flow; and with - a collecting device (7) for condensate dripping from the heat exchanger (4) during operation; wherein - in the collecting device (7) there is an outlet opening (9) to an outlet channel (8) for removing the condensate from the collecting device (7); and wherein - in the drain channel (8) at least one reducing point (11), as seen in the flow direction of the condensate, a reduction in the cross section of the drain channel (8) is provided.

Description

The invention relates to an air conditioner, in particular an air conditioner for air conditioning of interior spaces in motorhomes, caravans, cabs or boats.

Air conditioning units generally have a refrigeration cycle in which a refrigerant is first compressed and then passed through a serving as a condenser heat exchanger in which the heat stored in the refrigerant is dissipated to the environment. The compressed refrigerant is subsequently expanded, causing it to cool down considerably and in turn to be able to absorb heat from the environment. In this cold state, the refrigerant is passed through a serving as an evaporator heat exchanger in which it can cool the air flowing through the heat exchanger. This thus cooled air passes - usually by support with a blower device - in the room to be cooled. The heated by the air and now gaseous refrigerant is compressed again by the compressor and returned to the condenser.

Such air conditioners for the recreational vehicle area are often designed as roof air conditioners. However, they can also be arranged on the floor of a recreational vehicle, for example in a base cabinet.

As already explained, the air to be cooled is removed from the space to be cooled and passed over the serving as an evaporator heat exchanger, so that the refrigerant flowing through the heat exchanger evaporates. If the evaporation temperature of the refrigerant is below the dew point temperature of the air in the current state of temperature and relative humidity, the humidity in the form of condensation water is eliminated. At the fins of the heat exchanger, small droplets form, which eventually drip down and collected by a collecting device, usually in a kind of tub, and discharged to the outside via a condensate drain neck of gravity following. The condensate thus flows automatically out of the sump due to the effect of gravity and can thus enter the environment and drip, for example, on the street.

Rooftop air conditioners are often integrated in a compact housing in which old components of the air conditioner, in particular the components of the refrigerant circuit, are arranged inside the housing. In addition to the heat exchangers for the evaporator and condenser, this also applies to the blower devices which are each intended to generate an air flow through the heat exchangers.

In the case of the heat exchanger serving as an evaporator, an air flow is thus produced by means of a suitable blower ("indoor blower") through the fins of the heat exchanger, which is cooled in the heat exchanger and subsequently guided into the interior to be cooled.

The blower device inevitably generates a negative pressure in the region of the heat exchanger in order to bring about the desired air flow. The flow resistances in the intake area upstream of the blower device are also increased, inter alia, by filter installations or long air paths with a narrow cross-section, which leads to an increase in the pressure loss. In the case of a high pressure loss in the air intake area, the air to be sucked in is sucked in not only via the intake openings provided in the housing, but also through further openings which are located in the intake area. These openings also include the drain opening already described above in the drip pan, via the condensate to drain to the outside (condensate drain or drain channel). Thus, an air flow is generated in the drain opening, which is directed opposite to the flow direction of the condensate. While the condensate from the area of the heat exchanger to the outside (especially down) to flow, the air is promoted by the suction effect of the blower device from the environment via the drain passage into the interior.

In practice, the air flow - especially at a high pressure drop in the intake - be so strong that the condensate located in the drain channel is torn back into the drip pan or from the sump not even flow through the drain opening in the drain channel. Consequently, the condensate drain is not ensured, so that the condensate is distributed uncontrollably in the interior of the housing of the air conditioner and finally exits or flows away at undesirable points.

The invention has for its object to provide an air conditioner, in which the removal of the condensate is ensured from the air conditioner in the environment.

The invention is achieved by an air conditioner with the features of claim 1. Advantageous embodiments are specified in the dependent claims.

An air conditioner has a heat exchanger through which a refrigerant can flow and a collecting device for condensate dripping from the heat exchanger during operation. In the catcher is a drain opening to a drain passage for discharging the condensate from the Receiving device provided. In the drainage channel, a reduction of the cross-section of the drainage channel is provided at at least one reducing point, as seen in the flow direction of the condensate.

Thus, in the air conditioner condensate first - as in the prior art - collected and collected by a catcher. About the drain device, the condensate can flow out of the catcher due to the force of gravity and flow through the adjoining the drain opening drainage channel. However, the drainage channel does not have a constant cross section over its length, but its cross section is markedly reduced at least at one point, namely at the reduction point.

While it could be assumed that an enlargement of the cross section of the drainage channel helps to ensure the outflow of condensate even with an oppositely acting air flow, it has surprisingly been found that just the opposite, namely the narrowing of the drainage channel by reducing its cross-section to the desired effect leads.

One reason may be that a laminar flow of air in the exhaust duct due to the suction effect of the blower device is formed at the heat exchanger at a usually cylindrical and unchanging over the length of the cross section of the flow channel. The laminar flow of air prevents the condensate (condensed water) from draining.

By the reduction in cross section, for example by a diameter jump, in the flow channel, a turbulent flow is generated, which is no longer able to retain the accumulated condensate or to prevent it from flowing. Accordingly, the condensate can reach the environment via the drainage channel.

Furthermore, the air flow or its velocity is reduced by the cross-sectional reduction - which represents a cross-sectional widening from the point of view of the oppositely flowing air flow. The reduction of the flow velocity by expansion (cross-sectional expansion) also seems to be a reason that the air flow can no longer hinder the drainage of the condensate.

Furthermore, the amount of sucked, warm ambient air (incorrect air) is reduced. This allows the room air to be cooled faster in a closed indoor circle.

The reduction of the cross section in the discharge channel can be erratic. But it can also be done over a certain distance in the drainage channel, so for example by a over a certain distance uniformly or non-uniformly reducing cross-section. It is also possible to round the transitions inside the drainage channel. An essential aspect is that a "noticeable" reduction of the cross section takes place. Thus it can be assumed that a gradual reduction of the cross section over a too long distance should not bring the desired result.

In the drainage channel, an extension of the cross-section of the drainage channel, seen in the flow direction of the condensate, can be provided at at least one extension point. The extension of the cross section can thus be done in addition to the reduction of the cross section. This makes it possible to additionally enhance the turbulence of the air flow in the drainage channel. Likewise, after the extension of the cross section, a renewed, additional reduction of the cross section can be provided.

Thus, it is possible to provide in the flow channel several successive Reduzierstellen and extension points.

The air conditioner may comprise a housing device made of a plastic material, in which the essential components, in particular the components of the refrigerant circuit are housed. The plastic material may be a foamed material. For example, EPP (expanded polypropylene) has proven itself.

The housing means may consist of, for example, two shells, an upper and a lower shell, which hold the components of the air conditioner. Thus, in particular, the heat exchangers are inserted into the housing device. In addition, the corresponding air ducts and inlet and outlet openings for the air can be formed in the housing device. Finally, the collecting device and / or the drainage channel or at least a part of the drainage channel can also be provided in the housing device.

The collecting device can be arranged below the heat exchanger, so that the condensate dripping from the heat exchanger is collected directly.

For this purpose, it may be expedient if the collecting device is trough-shaped in order to ensure a secure collection of the condensate.

The Reduzierstelle and / or the extension point may be formed by an insertion. The insert is to be inserted into the drainage channel or into the housing device. In order to achieve the desired reduction in cross-sectional area precisely, it may already be useful for manufacturing reasons to make the insert piece separately from the rest of the housing device and the drainage channel and then insert it into the housing device. In this case, the insertion piece can form the drainage channel completely or only partially.

The collecting device can thus be formed in the housing device, wherein the insertion piece is inserted in the direction away from the collecting device drainage channel. The drainage channel in turn is also formed in the housing device. Even if the housing device is realized by a foamed plastic material, the dimensions of the housing device have certain tolerances, which may not reach the accuracy and sharpness required for the design of the drainage channel or the execution of the cross-sectional reduction. The ability to fabricate the insert separately and from a suitable plastic or metal material, the cross-sectional reduction can be made precisely in the insert. Subsequently, the insert is inserted into the housing device.

In a variant, a blower device is provided for generating an air flow to be cooled by the refrigerant through the heat exchanger. Furthermore, a control device may be provided for changing the rotational speed of the fan device. The control device may be designed such that it reduces the speed of the fan device at regular or irregular time intervals for a certain period of time relative to a normal speed.

In this variant, the fan speed is thus reduced regularly or irregularly and set, for example, from normal operation to "low" or "medium". As a result, the air flow through the air conditioner and thus also through the drainage channel weakens for this time, so that the condensate can flow away in this period.

The Reduzierstelle in the flow channel can be designed in many ways. It is an essential feature that the cross-section available for the air flow-seen in the direction of flow of the condensate-is reduced or, viewed in the direction of air flow, increased.

Incidentally, the flow connection to the environment formed by the drainage channel or the condensate drainage can be part of forced ventilation, which as a rule must be provided in an interior in a caravan.

These and further features of the invention are explained in more detail below by means of examples with the aid of the accompanying figures. Show it

1 a sectional perspective view of an air conditioner according to the invention;

2 an excerpt from 1 with an insert; and

3 the insert of 2 in an enlarged view.

An example of an inventive air conditioner is fragmentary in 1 and - in further enlargement - in 2 shown.

The air conditioner has a housing device 1 on, which can be designed in many ways. In principle, it has been proven that the housing device 1 an upper shell 2 and a lower shell 3 having. The upper shell 2 and the lower shell 3 can consist of a foamed plastic material, for example EPP, and be joined together so that they the essential components of the refrigerant circuit, ie in particular the heat exchanger (evaporator and condenser), the fan means (for the air to be cooled for the interior and for heat dissipation to the Environment) and the compressor, to keep between them. By holding a certain clamping effect can be achieved, which holds the components reliably in position.

In addition, the housing device ensures 1 in that a so-called indoor air circuit can be realized, which is closed to the environment, so that the suction of warm false air from the environment is effectively prevented.

In 1 is a serving as an evaporator heat exchanger 4 shown schematically. Also the heat exchanger 4 is between the upper shell 2 and the lower shell 3 held or clamped.

The heat exchanger 4 can be flowed through during operation of air, which has an air inlet opening 5 from the environment or - in circulating mode - out of the room to be cooled. The air flow at the inlet is indicated by an arrow A.

The air flow is effected by a blower device, not shown, behind an air intake 6 is arranged. In the area of the air intake opening 6 the flow of air is indicated by an arrow B.

During operation of the air conditioner, moisture is applied to the fins of the heat exchanger, which are not shown in detail 4 down when the air between the air inlet opening 5 and the air intake opening 6 is cooled. The moisture in the form of condensation (condensate) drips on the heat exchanger 4 From or is derived by appropriate water supply down and can eventually be used in a catcher serving as a catcher 7 collect.

To the drip tray 7 subsequently or at the level of the lowest point of the collecting trough 7 is a drainage channel 8th provided, which serves in the drip pan 7 remove collected condensate to the outside. About the drainage channel 8th For example, in the case of a roof air conditioner, the condensate may be discharged to the top of the vehicle carrying the roof air conditioning unit, from where the condensate is discharged by the gravitational action via the usually provided gutter construction.

The drainage channel 8th is in 2 shown enlarged. He has one in the drip tray 7 trained drain opening 9 on, over which the condensate in the drainage channel 8th enters and in the direction of arrow C flows.

In the example shown, the drainage channel is 8th completely through an insert 10 educated. The insert piece 10 is made of a harder plastic material or metal and in the relatively soft foam material of the lower shell 3 pressed in, like 2 shows.

As already explained above in connection with the prior art, the condensate drain is above the drainage channel 8th the problem that the blower device, the air over the air inlet 5 sucks, a negative pressure in the area of the heat exchanger 4 generated. Depending on the flow conditions and flow resistance, the negative pressure can be so strong that over the drainage channel 8th Air is sucked in. The air flow for this case is indicated by arrow D ( 2 ). This air thus flows opposite to the direction of flow C of the condensate and may in the worst case lead to the condensate not via the drainage channel 8th can drain down.

To prevent such a negative effect, the drain channel 8th or the insertion piece 10 a reducer 11 on, at the cross section of the drainage channel 8th or the insert 10 - Seen in the flow direction C of the condensate - is suddenly reduced.

This means that in the direction of arrow D in the flow channel 8th inflowing air undergoes a cross-sectional widening, whereby the flow velocity decreases abruptly. It has been found that this and due to the probably turbulent air flow, the obstruction of the condensate drainage is significantly reduced, so that the condensate now almost unhindered over the drainage channel 8th can flow down (arrow C).

In the example shown, the reduction in cross-section (seen in the direction of flow of the condensate) takes place over a certain distance in the discharge channel 8th , The reduction in cross section takes place relatively quickly, as reflected by the strong inclination of one at the Reduzierstelle 11 provided stage 12 relative to the otherwise cylindrical wall of the drainage channel 8th shows ( 3 ).

Of course it would also be possible to change the level 12 perpendicular to the cylindrical duct wall to achieve a true diameter jump.

By reducing the cross-section, moreover, a capillary effect appears to be achieved, which also promotes the outflow of the condensate.

The drainage channel 8th is abstract and concerns the area in which the condensate after passing through the drain opening 9 continues to flow. Thus, the drainage channel can be completely formed by an insertion piece as in FIGS 1 to 3 shown. However, it is also possible that the insertion piece is arranged only in a part of the drainage channel and there causes the desired reduction in cross-section, while another part of the drainage channel is not affected.

In variants also insert pieces can be used as a drain channel 8th or only as part of the drainage channel 8th serve or in the drainage channel 8th be used.

So it has turned out that parts of an air filter or a grid construction - rolled up - in the drain opening 9 or the drainage channel 8th can be inserted. The insert piece 10 can be made of plastic or metal (eg copper). It is also possible to insert the insert 10 z. B. by a plurality of individual tubes (eg., Made of copper), which are arranged side by side to form a unit.

The insert piece 10 can also be plugged as a pure reducer, for example as a plug into the drainage channel to effect the desired reduction of the cross-section. The Reduzierstelle with the reduction of the cross section is then at the top of the insert.

In practice, a further variant has proven useful in which a cord is glued into the drainage channel and thereby causes the required reduction in cross-section. In addition, the string may, for example, be led to a gutter so that the dripping condensate is directed along the string to the gutter.

Claims (12)

Air conditioner, with - a heat exchanger through which a refrigerant can flow ( 4 ); and with - a collecting device ( 7 ) for the heat exchanger ( 4 ) dripping during operation condensate; in which - in the collecting device ( 7 ) a drain opening ( 9 ) to a drain channel ( 8th ) for removing the condensate from the collecting device ( 7 ) is provided; and wherein - in the drainage channel ( 8th ) at least one reducing point ( 11 ), seen in the flow direction of the condensate, reduction of the cross section of the flow channel ( 8th ) is provided. Air conditioner according to claim 1, characterized in that the reduction of the cross-section is erratic. Air conditioner according to claim 1 or 2, characterized in that the reduction of the cross-section over a certain distance in the flow channel ( 8th ) he follows. Air conditioner according to one of the preceding claims, characterized in that in the flow channel ( 8th ) at at least one extension point, seen in the flow direction of the condensate, expansion of the cross section of the flow channel ( 8th ) is provided. Air conditioner according to one of the preceding claims, characterized in that in the flow channel ( 8th ) several successive reduction points ( 11 ) and extension points are provided. Air conditioner according to one of the preceding claims, characterized in that - a housing device ( 1 ) is provided of a (foamed) plastic material; and that - the heat exchanger in the housing device ( 1 ) is used. Air conditioner according to one of the preceding claims, characterized in that the collecting device ( 7 ) below the heat exchanger ( 4 ) is arranged. Air conditioner according to one of the preceding claims, characterized in that the collecting device ( 7 ) is trough-shaped. Air conditioner according to one of the preceding claims, characterized in that the reduction point ( 11 ) and / or the extension point by an insert ( 10 ) is formed. Air conditioner according to one of the preceding claims, characterized in that the insert ( 10 ) the drainage channel ( 8th ) forms completely or partially. Air conditioner according to one of the preceding claims, characterized in that - the collecting device ( 7 ) in the housing device ( 1 ) is trained; and that - the insert ( 10 ) in which the catcher ( 7 ) leading drain channel ( 8th ) is used. Air conditioner according to one of the preceding claims, characterized in that - a blower device is provided for generating a to be cooled by the refrigerant air flow through the heat exchanger ( 4 ); - That a control device is provided for changing the rotational speed of the blower device; - That the control device is designed such that it reduces the speed of the fan device at regular or irregular intervals for a certain period of time relative to a normal speed.

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