DE102021112521A1 - Heating, ventilation and/or air conditioning - Google Patents

Abstract

A heating, ventilation and/or air conditioning system (10) is specified, having a housing (12) which has a floor pan (18) in which a condensation water drain (32) is formed, an evaporator (20) and a fresh air inlet (22), wherein an air duct for air sucked in through the fresh air inlet (22) proceeds from the fresh air inlet (22) through the housing (12) to the evaporator (20) and proceeds from the evaporator (20) to an air outlet (28) extends, and wherein a bypass channel (34) to the evaporator (20) is provided, which branches off after the fresh air inlet (22) from the air duct and further downstream of the fresh air inlet (22) and downstream of the evaporator (20) directly into the floor pan (18) flows.

Description

The invention relates to a heating, ventilation and/or air conditioning system for a motor vehicle.

Heating, ventilation and/or air conditioning systems are designed to generate one or more temperature-controlled air flows. Such systems are used in motor vehicles for ventilation and air conditioning of a vehicle interior.

For this purpose, an air flow is first sucked in by means of a fan via a fresh air inlet, which can then be tempered by means of an evaporator and a heating device.

When sucking in the fresh air, it can happen that not only air but also water is sucked in, for example when it rains or when water runs into the fresh air inlet during a washing process.

When stationary, when the fan is not working or when the fan is only running at low speed, the water can drain downwards. At a higher fan speed, especially from a speed of 4000 rpm, the suction power of the fan is so high that the water can no longer drain off easily. In addition, due to the flow conditions in a housing of the heating, ventilation and/or air conditioning system at high fan speed, a relatively high air pressure occurs in a lower area of the housing, which can even push penetrating water upwards.

As a result, there is a risk that water will get into the fan or into a filter arranged upstream of the evaporator, which can impair the function of the heating, ventilation and/or air conditioning system.

It is therefore an object of the invention to provide a heating, ventilation and/or air conditioning system in which water drawn in is reliably discharged even if the fan has a high suction power.

This object is achieved according to the invention by a heating, ventilation and/or air conditioning system with a housing that has a floor pan in which a condensation water drain is formed, an evaporator and a fresh air inlet, with an air duct for air sucked in through the fresh air inlet starting from the fresh air inlet through the housing to the evaporator and starting from the evaporator to an air outlet, and wherein a bypass duct is provided to the evaporator, which branches off from the air duct after the fresh air inlet and further downstream of the air inlet and downstream of the evaporator opens directly into the floor pan.

The bypass duct represents a water drainage duct through which water that may have been sucked in through the fresh air inlet can be reliably discharged downwards and discharged from the heating, ventilation and/or air conditioning system through the condensate drainage.

Since the bypass duct opens directly into the base pan, water that penetrates from the bypass duct can run directly into the base pan and can thus be discharged particularly quickly from the heating, ventilation and/or air conditioning system. In particular, a backwater of water is avoided.

For example, the bypass channel runs directly along a side wall of the evaporator. This contributes to a particularly compact design of the heating, ventilation and/or air conditioning system.

In particular, the bypass channel extends continuously and in a straight line along the evaporator.

According to one embodiment, the heating, ventilation and/or air conditioning system includes a fan and an inlet of the bypass channel is below the level of the fan when the heating, ventilation and/or air conditioning system is installed. This ensures that penetrating water can flow into the bypass duct before it flows to the fan.

The inlet of the bypass duct is preferably arranged upstream of the fan. This also contributes to the fact that penetrating water is reliably drained away before it can get into the fan.

The bypass passage may be formed by a bulge in the housing that is directly adjacent to the evaporator and/or a gasket placed on the evaporator. By virtue of the bypass channel being formed by a bulge in the housing, the bypass channel can be implemented without an additional component being necessary. In addition, the bypass channel can be formed particularly easily in the housing in the form of a bulge.

According to one embodiment, the heating, ventilation and/or air conditioning system includes a filter that is arranged upstream of the evaporator, and the opening of the bypass channel into the floor pan is downstream of the filter. In this way it is avoided that water, which is discharged through the bypass channel, can come into contact with the filter after the water has run out leaked out of the bypass channel. In particular, when the fan is active, the water exiting the bypass channel can be deflected in a direction away from the filter by the air flow flowing through the heating, ventilation and/or air conditioning system.

The vertical height of the bypass duct and the maximum fan output are preferably matched to one another in such a way that, at maximum fan speed, standing water in the bypass duct remains below the inlet of the bypass duct due to the hydrostatic pressure. This ensures that in any operating state of the heating, ventilation and/or air conditioning system, the hydrostatic pressure building up in the bypass channel is high enough to prevent water that has penetrated from getting into the fan or the filter.

The bypass channel preferably extends over more than half the vertical height of the evaporator. In particular, the bypass channel extends over more than 3/4 of the vertical height of the evaporator. As a result, when the bypass duct is completely filled with water, the hydrostatic pressure is high enough to overcome an air pressure at the outlet of the bypass duct in any operating state of the heating, ventilation and/or air conditioning system. The vertical height of the bypass channel is preferably at least 10 cm, in particular up to 20 cm.

According to one embodiment, the bypass channel runs along one side of the evaporator and at least one wall of the bypass channel is formed by the evaporator and/or a seal arranged on the evaporator. As a result, the bypass channel can be implemented particularly easily. In particular, it is not necessary to create a circumferentially closed channel in the housing, but rather the wall of the evaporator and the seal are used to close the bypass channel circumferentially. This contributes to a compact construction of the heating, ventilation and/or air conditioning system.

A seal arranged on the evaporator can be divided in the area of the bypass channel in such a way that a part of the bypass channel runs in the seal. In this way, a cross section of the bypass duct can be increased without affecting the external dimensions of the heating, ventilation and/or air conditioning system. The function of the seal is also not affected by the division. A larger cross-section of the bypass duct is advantageous in that the bypass duct has a larger volume with the same vertical height and thus penetrating water can also be discharged quickly in larger quantities.

For example, the bypass channel tapers at least in sections in the direction of its outlet. To put it more precisely, the bulge that forms the bypass channel flattens out towards the outlet and merges into a housing wall. As a result, there is no need to seal the bypass channel to the outside in the area of the outlet.

A housing wall of the housing can drop downstream of the fresh air inlet towards the inlet of the bypass duct. This contributes to water entering through the fresh air inlet running in a targeted manner in the direction of and into the bypass duct.

The housing is preferably in several parts. In particular, the housing comprises two housing shells in addition to the floor pan, with the bypass channel being formed in one of the two housing shells.

• - 1 eine erfindungsgemäße Heizungs-, Lüftungs- und/oder Klimaanlage,
• - 2 einen Querschnitt durch die Heizungs-, Lüftungs- und/oder Klimaanlage aus 1,
• - 3 eine Bodenwanne der Heizungs-, Lüftungs- und/oder Klimaanlage aus 1,
• - 4 eine weitere Schnittdarstellung der Heizungs-, Lüftungs- und/oder Klimaanlage aus 1,
• - 5 eine perspektivische Darstellung der Heizungs-, Lüftungs- und/oder Klimaanlage aus 1,
• - 6 eine Detailansicht im Bereich eines Einlasses eines Bypasskanals, und
• - 7 eine weitere Ansicht der Heizungs-, Lüftungs- und/oder Klimaanlage aus 1.

Further advantages and features of the invention result from the following description and from the accompanying drawings, to which reference is made. In the drawings show:

• - 1 a heating, ventilation and/or air conditioning system according to the invention,
• - 2 a cross section through the heating, ventilation and/or air conditioning system 1 ,
• - 3 a floor pan of the heating, ventilation and/or air conditioning system 1 ,
• - 4 another sectional view of the heating, ventilation and/or air conditioning system 1 ,
• - 5 a perspective view of the heating, ventilation and / or air conditioning 1 ,
• - 6 a detailed view in the area of an inlet of a bypass channel, and
• - 7 another view of the heating, ventilation and/or air conditioning system 1 .

1 shows a heating, ventilation and/or air conditioning system 10 in a side view. 2 shows a cross section through the heating, ventilation and/or air conditioning system 10.

Such heating, ventilation and/or air-conditioning systems 10 are usually used in motor vehicles in order to ventilate and air-condition a vehicle interior.

The heating, ventilation and/or air conditioning system 10 comprises a housing 12 which has two housing shells 14, 16 fastened to one another (see FIG 2 ).

In addition, the housing 12 includes a base pan 18 which is connected to the two housing shells 14, 16 in a fluid-tight manner and forms a base of the housing 12. The floor pan 18 is in 3 shown separately.

The housing 12 is in particular a fan housing for accommodating an evaporator 20 (see FIG 2 ) and for accommodating fan flaps. The fan flaps are not shown in the figures for the sake of simplicity.

The heating, ventilation and/or air conditioning system 10 has a fresh air inlet 22 through which fresh air is drawn in, in particular by means of a fan 24 which is accommodated in the housing 12 .

The fresh air inlet 22 is formed in an inlet port 26 which also forms part of the housing 12 .

Starting from the fresh air inlet 22, an air duct for air drawn in through the fresh air inlet 22 extends through the housing 12 to the evaporator 20 and, starting from the evaporator 20, to an air outlet 28.

A filter 30 is arranged upstream of the evaporator 20, through which the intake air also flows.

The air duct is formed in particular by housing walls and fan flaps, which influence the course of the flow of the intake air. In 1 a course of the air flow is shown schematically by way of example using a dashed line, with the exact course being able to vary depending on the position of the fan flaps.

The housing 12 usually has a plurality of air outlets 28, with an air flow being directed to specific air outlets 28 depending on the position of the fan flaps.

A seal 31 is arranged on the evaporator 20 . The seal 31 preferably extends at least along the side walls of the evaporator 20 and over the entire vertical height of the evaporator 20. This prevents air from flowing laterally past the evaporator 20 and thus not being cooled.

If the air flowing through the evaporator 20 has a relatively high humidity, water usually condenses on the evaporator 20.

The water drips from the evaporator 20 into the base pan 18 and runs to a condensate drain 32 (see Fig 3 ).

The condensate drain 32 is formed at the lowest point in the floor pan 18 in the installed position. In particular, the condensation drain 32 is an opening in the floor pan 18.

Apart from the condensation that can form on the evaporator 20 , water can also get into the heating, ventilation and/or air conditioning system 10 via the fresh air inlet 22 . This can happen, for example, during a washing process or when it rains, in particular if the fan 24 is operated at a high speed and the suction capacity of the fan 24 is therefore particularly high.

In order to prevent the sucked-in water from getting into the fan 24 or into the filter 30, a bypass duct 34 is provided to the evaporator, which branches off the air duct after the fresh air inlet 22 and further downstream of the fresh air inlet 22 and downstream of the evaporator 20 directly into the Floor pan 18 opens out as 2 and the inside 4 shown sectional view can be seen.

Since the filter 30 is arranged upstream of the evaporator 20, the opening of the bypass channel 34 into the floor pan 18 is also downstream of the filter 30.

The opening of the bypass channel 34 into the floor pan 18 represents an outlet 36 of the bypass channel 34.

Water drawn in can flow past the evaporator 20 directly into the floor pan 18 through the bypass channel 34 and be discharged from the heating, ventilation and/or air conditioning system 10 via the condensate drain 32 without it flowing through the fan 24 or the filter 30.

As in 2 can be seen, the bypass channel 34 extends directly along a side wall of the evaporator 20.

More precisely, a wall of the bypass channel 34 is formed at least partially by the seal 31 arranged on the evaporator 20 .

An inlet 38 of the bypass duct 34 is arranged upstream of the fan 24 . this is in 5 12 is a perspective view of the heating, ventilating, and/or air conditioning system 10 with an upper portion of the inlet stub 26 hidden to allow a view of the inlet 38 of the bypass duct 34 .

Also shown for illustration is a flow path from intake air to fan 24 drawn in dashed. In particular, the air flow from the fresh air inlet 22 to the fan 24 makes a curve.

Thus, penetrating water first flows to the bypass channel 34 before it can reach the fan 24.

Rapid draining off of the water is also promoted by the fact that a housing wall of the housing 12 falls downstream of the fresh air inlet 22 toward the inlet 38 of the bypass duct 34 .

This is particularly clear 6 can be seen, which shows a detailed view in the area of the inlet 38 of the bypass channel 34 .

The inlet 38 of the bypass channel 34 is below the level of the fan 24.

From the 1 and 2 shows that the bypass channel 34 is formed by a bulge 40 in the housing 12, in particular in one of the housing shells 14, 16.

The bypass channel 34 tapers towards its outlet.

7 shows another view of the heating, ventilation and/or air conditioning system 10, in which 7 the housing shells 14, 16 are hidden. A particularly good view of the seal 31 is thus possible.

The seal 31 is divided in the area of the bypass channel 34 in such a way that a part of the bypass channel 34 runs in the seal 31 .

The seal 31 is in particular divided in such a way that two sealing strips 42, 44 of the seal 31 run parallel to one another on a side wall of the evaporator 20.

One of the two sealing strips 42 ends on the side wall of the evaporator 20, while the other sealing strip 44 continues to an underside of the evaporator 20 and runs further along it.

As in 7 As can be seen, this offset results in an opening between the sealing strips 42, 44, which forms the outlet 36 of the bypass channel 34.

The sealing strip 42 arranged further downstream in the direction of flow of the two sealing strips 42, 44 is preferably shortened. As a result, the water emerging from the bypass channel 34 can flow in the direction away from the filter 30 .

Due to the division of the seal 31 , one side of the evaporator 20 is partially exposed in an area in which the bypass duct 34 runs, so that the evaporator 20 also forms part of a wall of the bypass duct 34 .

The bypass channel 34 is thus formed as soon as the evaporator 20 is assembled with the gasket 31 in the housing 12 .

In an alternative embodiment, the seal 31 may not be split. In this case, only the seal 31 and not the evaporator 20 forms a wall of the bypass channel 34.

If there is no seal on the evaporator 20 in the area of the bypass duct 34 , the bulge 40 can be directly adjacent to the evaporator 20 so that the evaporator 20 forms a wall of the bypass duct 34 .

If the fan 24 is operated at a high fan speed, due to the flow conditions prevailing in the housing 12, there may be a higher air pressure in the area of the floor pan 18 and in particular in the area of the outlet 36 of the bypass channel 34 than in the area of the inlet 38 of the bypass channel 34.

In order to avoid the water present in the bypass channel 34 being pushed upwards by the high air pressure in the area of the floor pan 18, the bypass channel 34 is dimensioned in such a way that a hydrostatic pressure in the bypass channel 34 is large enough to ensure that the heating, Ventilation and / or air conditioning 10 to keep the air pressure prevailing at the outlet 36 stand. In particular, it should be avoided that water is pressed upwards through the inlet 38 .

This is accomplished by a vertical height of the bypass duct 34 and a maximum fan output being matched to one another such that standing water in the bypass duct 34 remains below the inlet 38 of the bypass duct 34 due to the hydrostatic pressure at maximum fan speed.

The bypass channel 34 is particularly preferably designed in such a way that the hydrostatic pressure at the outlet 36 of the bypass channel 34 is large enough to overcome the air pressure prevailing at the outlet, so that the water can flow out of the bypass channel 34 to the condensate drain 32 .

In order to achieve the greatest possible hydrostatic pressure, the bypass channel 34 must come be completely filled with water. But even if the bypass channel 34 is only partially filled with water, it is reliably ensured that the water in the bypass channel 34 remains below the inlet 38 since the air pressure in the bypass channel 34 decreases towards the top.

In the exemplary embodiment, the bypass channel 34 extends over more than half the vertical height of the evaporator 20, in particular over more than 3/4 of the vertical height of the evaporator 20.

For example, a height of the bypass channel 34 is at least 10 cm.

A cross section of the bypass channel 34 is between 1 cm ² and 3 cm ² , for example.

Claims (11)

Heating, ventilation and/or air conditioning system (10) with a housing (12) which has a floor pan (18) in which a condensation water drain (32) is formed, an evaporator (20) and a fresh air inlet (22), wherein an air duct for air drawn in through the fresh air inlet (22) extends from the fresh air inlet (22) through the housing (12) to the evaporator (20) and from the evaporator (20) to an air outlet (28), and wherein a Bypass channel (34) to the evaporator (20) is provided, which branches off from the air duct after the fresh air inlet (22) and further downstream of the fresh air inlet (22) and downstream of the evaporator (20) opens directly into the floor pan (18). Heating, ventilation and / or air conditioning (10) after claim 1 , characterized in that the heating, ventilation and / or air conditioning (10) comprises a fan (24) and an inlet (38) of the bypass channel (34) is below the level of the fan (24). Heating, ventilation and / or air conditioning (10) after claim 2 , characterized in that the inlet (38) of the bypass channel (34) is arranged upstream of the fan (24). Heating, ventilation and/or air conditioning system (10) according to one of the preceding claims, characterized in that the bypass channel (34) is formed by a bulge (40) in the housing (12) which is directly attached to the evaporator (20) and /or a seal (31) arranged on the evaporator (20). Heating, ventilation and/or air conditioning system (10) according to one of the preceding claims, characterized in that the heating, ventilation and/or air conditioning system (10) comprises a filter (30) which is arranged upstream of the evaporator (20). is, and the mouth of the bypass channel (34) is in the floor pan (18) downstream of the filter (30). Heating, ventilation and/or air conditioning system (10) according to one of the preceding claims, characterized in that the bypass duct (34) extends over more than half the vertical height of the evaporator (20). Heating, ventilation and/or air conditioning system (10) according to one of the preceding claims, characterized in that the vertical height of the bypass duct (34) and the maximum fan output are matched to one another in such a way that standing water in the bypass duct (34) can escape at maximum fan speed remains below the inlet (38) of the bypass channel (34) due to the hydrostatic pressure. Heating, ventilation and/or air conditioning system (10) according to one of the preceding claims, characterized in that the bypass duct (34) runs along one side of the evaporator (20) and at least one wall of the bypass duct (34) passes through the evaporator (20 ) and/or a seal (31) arranged on the evaporator (20). Heating, ventilation and / or air conditioning (10) after claim 8 , characterized in that a seal (31) arranged on the evaporator (20) is divided in the region of the bypass channel (34) in such a way that part of the bypass channel (34) runs in the seal (31). Heating, ventilation and/or air conditioning system (10) according to one of the preceding claims, characterized in that the bypass channel (34) tapers at least in sections in the direction of its outlet (36). Heating, ventilation and/or air conditioning system (10) according to any one of the preceding claims, characterized in that a housing wall of the housing (12) slopes down downstream of the fresh air inlet (22) towards the inlet (38) of the bypass duct (34).

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