DE102009020711A1 - Radiator for a motor vehicle with an internal combustion engine - Google Patents

Abstract

The invention relates to a radiator for motor vehicles with an internal combustion engine, comprising a radiator block with at least four rows of flow channels (2a, 2b, 3a, 3b) for a cooling circuit of the internal combustion engine removable coolant, at least one coolant box (4, 5) for the and / or outlet, the distribution, collection and / or deflection of the coolant, wherein in the at least one coolant box (4, 5) longitudinal and / or transverse partitions (4a, 4b, 4c, 5a) for deflecting the coolant in the depth and / or the width are arranged and wherein the radiator block of air in the flow direction (L) flows through and the coolant through the flow channels (2 a, 2 b, 3 a, 3 b) is guided in countercurrent. It is proposed that the coolant on the inlet side is distributed over a number of flow channels (2a, 2b) which corresponds at most to the number of flow channels in a row.

Description

The The invention relates to a radiator for a motor vehicle according to the preamble of claim 1.

Radiators that are operated in countercurrent to increase performance, ie in which the air to be heated is conducted in countercurrent to the coolant, are known. Such a radiator was through the DE 44 31 107 C2 known. In the known countercurrent radiator, the coolant is deflected in one or more stages of the air outlet side in the direction of the air inlet side. This can be a higher heat transfer performance can be achieved. The disadvantage here is that the coolant must be distributed on the inlet side over the entire row of tubes, not all tubes are supplied evenly with coolant. As a result, a Temperatursträhnigkeit, ie occur over the width inhomogeneous temperature distribution.

By the DE 102 47 609 A1 has known a radiator in which the coolant is deflected exclusively in width, in several stages, with several coolant flows are connected in parallel. The aim of this arrangement is to achieve relatively large pressure losses by turbulence of the coolant at the deflection of the coolant boxes.

By the DE 10 2005 048 227 A1 the applicant has been known a radiator with flat tubes, in which the coolant is guided in cross-counterflow to the air flow, ie there is a deflection in the depth in the direction of the air inlet side.

By the applicant's earlier application with the official file number 10 2008 017 485.8 (Applicant's internal reference: 07-B-142-A) a radiator for motor vehicles with diversion of the coolant both in width and in depth known.

It Object of the present invention, a radiator improve the performance of the type mentioned in the beginning, at the same time as compact as possible construction and a uniform temperature distribution on the Air outlet side (leeward) should be achieved.

The The object of the invention is characterized by the features of claim 1 solved. Advantageous embodiments emerge the dependent claims.

According to the invention provided that the coolant on the inlet side to a number of flow channels (hereinafter short channels called) is distributed, which maximally the Number of channels in a row. The inlet cross section of the coolant in the radiator block (with four Channel rows) thus amounts to a maximum of 25% of the cross section all flow channels of the radiator block. Preferably, the channels can through pipes, in particular Flat tubes are formed, wherein a flat tube as a two-chamber tube, d. H. be formed with two discrete flow channels can. The radiator then has two rows of flat tubes.

Prefers is the coolant on the inlet side either to a single, d. H. distributed the leeward arranged channel row and then deflected in the depth. Alternatively, the coolant distributed on two channel rows on the entrance side and then at least once deflected in width. In both cases result on the inlet side, a more uniform admission the channels and an increase in performance. After another preferred embodiments, the coolant then deflected for the first or second time in depth to one then be redirected again in width. With the distribution and deflection according to the invention the coolant becomes the advantage of a high power density and achieved a high efficiency. This will continue the advantage that an electric booster heater, a so-called Heater, leeward with conventional radiators is arranged, can be omitted. That by the known Zuheizer additionally claimed construction volume is due to the radiator according to the invention ingested. The latter thus does not take up more space than known radiator with electric heater. This will be the electrical system of the motor vehicle of an additional Consumers released. The heat contained in the coolant can thus to a greater extent for the Heating the passenger compartment of the motor vehicle are used. Another advantage is a high power density at low volume flows of the coolant. By the smaller volume flows can be hose diameter and thus the amount of coolant can be reduced, resulting in a faster heating of the coolant leads. The individual embodiments according to the invention each have a specific temperature profile at a very high heating power and thus offer the opportunity a special use in the air conditioning of the motor vehicle. This can be different versions of the air conditioning on a suitable radiator with adapted temperature profile be resorted to.

Embodiments of the invention are illustrated in the drawings and will be described in more detail below, with further features and / or advantages of the description and / or Drawing can result. Show it

1 a double-row flat-tube radiator with four flow channels,

2 . 2a A first embodiment of the invention for a lying horizontally arranged radiator (flat tubes),

3 . 3a . 3b A second embodiment of the invention for a vertically arranged radiator (pipes vertical), with flow of the coolant,

4 . 4a . 4b A third embodiment of the invention,

5 . 5a . 5b A fourth embodiment of the invention,

6 . 6a . 6b A fifth embodiment of the invention,

7 . 7a . 7b a sixth embodiment of the invention,

8th . 8a . 8b A seventh embodiment of the invention,

9 . 9a . 9b an eighth embodiment of the invention,

10 . 10a . 10b A ninth embodiment of the invention,

11 . 11a . 11b a tenth embodiment of the invention,

12 . 12a . 12b an eleventh embodiment of the invention,

13 . 13a . 13b a twelfth embodiment of the invention,

14 . 14a . 14b A thirteenth embodiment of the invention,

15 . 15a . 15b a fourteenth embodiment of the invention.

1 shows one as a radiator 1 trained for motor vehicles heat exchanger, which two rows of flat tubes 2 . 3 which are each designed as a two-chamber tubes and two discrete flow channels 2a . 2 B . 3a . 3b exhibit. Between the flat tubes 2 . 3 (Seen perpendicular to the plane) are not shown, designed as corrugated secondary surfaces arranged, which are overflowed by air, represented by an arrow L. Flat tubes and corrugated ribs form a radiator block. The flat tubes 2 . 3 are end in an upper coolant box 4 and a lower coolant box 5 added. The radiator 1 is preferably made entirely of aluminum materials, and all the items are soldered together. The flat tubes 2 . 3 or their flow channels 2a . 2 B . 3a . 3b are flowed through by a heating medium, for which the coolant of the cooling circuit of the internal combustion engine of the motor vehicle is used. The radiator is arranged on the water side in a secondary circuit (heating circuit) of the cooling circuit. The heat contained in the coolant is thus used for the heating of the air, which is supplied to a vehicle interior of the motor vehicle, not shown. The invention thus relates to a so-called engine-dependent heating. The direction of flow L of the air is also referred to as the depth direction, ie a deflection of the coolant in or against the direction of the arrow L is referred to below as a deflection in the depth. A deflection of the coolant - in one or both of the coolant boxes 4 . 5 - perpendicular to the plane is referred to as a deflection in the width. In the upper coolant box 4 are longitudinal partitions 4a . 4b . 4c provided, which allow a deflection of the coolant in the depth direction. In the lower coolant box 5 is a middle longitudinal partition 5a arranged. The arrangement of the partitions shown here 4a . 4b . 4c . 5a is only an example, it basically does not apply to the embodiments of the invention described below.

2 . 2a show as a first embodiment of the invention, a horizontally arranged radiator 10 ie its flat tubes 12 . 13 , according to the in 1 illustrated flat tubes 2 . 3 , are arranged horizontally. The inlet side coolant box 14 as well as the deflection box 15 are arranged vertically. The coolant box 14 is additionally in a plan view in 2a shown and has a longitudinal partition wall 14a as well as a cross partition 14d on which the longitudinal dividing wall 14a limited. In the deflection box 15 is a continuous longitudinal partition 15a arranged, which is partially shown by dashed lines. The flow direction of the air, which is the radiator 10 flows through, is shown by arrows L. Inlet and outlet of the coolant are represented by arrows E, A. It can be seen that the coolant and the air are guided in countercurrent or countercurrent: the coolant, represented by the arrow E, occurs on the leeward side of the radiator 10 ie in the flat tubes 12 one. The flow direction of the coolant is in 2a represented by cross and point symbols, wherein the cross symbol in the circle a flow direction perpendicular to the plane and the point symbol in the circle indicate a flow direction perpendicular to the plane out. In addition, the flow of the coolant is in 2 denoted by seven each perpendicular to each other arrows S1 to S7. The coolant flows through the radiator 10 after entry so first according to the arrow S1, ie in the entire width, but only in the upper half (as shown in FIG 2 ). Subsequently, the coolant in the deflection box 5 deflected over the entire width according to the arrow S2 and then flows through the radiator 10 across the full width in the opposite direction, ie according to the arrow S3. Thereafter, according to arrow S4 in the coolant tank 14 a deflection in the depth, ie against the air flow direction L. The following arrows S5, S6, S7 correspond to the flow arrows S1, S2, S3 in the reverse direction. Thus, the coolant once in the row of flat tubes 12 in width, once in depth, and a second time in the row of flat tubes 13 deflected in width.

All subsequent embodiments also work after the countercurrent principle, where the terms luv- and leeward designate the air inlet and outlet side. The coolant So it always occurs leeward and windward.

3 . 3a . 3b show a second embodiment of the invention for a standing radiator 20 ie the flat tubes 22 . 23 are arranged vertically. The radiator 20 has an upper coolant box 24 for the lateral inlet and outlet of the coolant as well as a lower coolant box 25 on, which in each case in 3a and 3b are shown in a plan view with partitions and flow direction symbols. The upper coolant box 24 in 3a has a continuous longitudinal partition 24a on, as well as an eccentrically arranged transverse partition 24d , The lower coolant box 25 has a continuous longitudinal partition 25a and an off-center transverse partition 25b on. The partitions 24d . 25b are, as far as concealed, also shown in dashed lines. The flow path of the coolant is in 3 represented by thirteen flow arrows S1 to S13. Thereafter, the coolant is deflected twice in the width in the inlet and leeward tube row, after which takes place according to arrow S7, a deflection in the depth in the windward outlet row. There, the coolant is also deflected twice in width according to the arrows S9 to S13. In this exemplary embodiment, the coolant, due to the total of fivefold deflection, travels a relatively long distance, which is advantageous in particular in the case of small volume flows and low inlet temperatures.

4 . 4a . 4b show a third embodiment of the invention for a flow pattern 30 , The associated radiator is omitted here and in the following embodiments, it corresponds to the basic structure of the radiator 20 according to 3 , The only difference is the arrangement of the longitudinal and transverse partitions and partly the inlet and outlet of the coolant. The flow pattern 30 is characterized by eleven adjoining flow arrows S1 to S11, ie by a simple deflection in the width in the first row of tubes, a subsequent deflection in the depth (arrow S5) and then a double deflection in the width in the second row of tubes. The upper coolant box 34 the radiator, not shown, is in 4a , the bottom coolant box 35 in 4b shown. One recognizes here - as well as with the flow model 30 in that the inlet E of the coolant into the lower coolant box 35 and the outlet A from the upper coolant box 34 he follows. The for the flow pattern 30 required longitudinal and transverse partitions are in 4a and 4b clearly drawn in the same way as in the previous illustrations, so that in this case - as in the following exemplary embodiments - partial additional labeling with reference numbers can be dispensed with. It is merely noted here that the longitudinal partition wall 35a in 4b not over the entire width of the radiator is continuous, so that a deflection of the coolant in the depth - according to the arrow S5 in 4 - is possible.

5 . 5a . 5b show a fourth embodiment of the invention with a flow model 40 for the coolant, represented by arrows S1 to S12, ie from the inlet E to the outlet A of the coolant. The upper coolant box 44 represented in 5a , has a non-continuous longitudinal partition wall 44a on, in their non-continuous area a dot symbol 7b , corresponding to the flow arrow S7b in 5 , is located. The lower coolant box 45 represented in 5b , also has a non-continuous longitudinal partition wall 45a on, in the non-continuous region, a cross symbol S6a is located, which the flow arrow S6a in 5 equivalent. As from the flow model 40 can be seen after the deflection in the width, according to the flow arrow S5 a branching of the coolant in a deflection in the width (arrow S6a) and a deflection in the depth (arrow S6b). The combination of the coolant sub-streams is carried out by meeting the flow arrows S7a and S7b. To further clarify the names of the vertical flow arrows are off 5 the dot or cross symbols in the 5a . 5b assigned.

In the embodiments of the 2 to 5 the longitudinal partitions are always centered, ie arranged between the two rows of flat tubes. The deflection of the coolant in the width is thus always within the flat tube row, ie parallel in two rows of channels. In the following Ausfüh The longitudinal partitions are also off-center, ie arranged between two rows of ducts - as a result of which the coolant can be better distributed over the entire width of the radiator.

6 . 6a . 6b show a fifth embodiment of the invention, shown as a flow model 50 , The 6a . 6b show the upper coolant box 54 and the lower coolant box 55 the radiator, not shown. The coolant box 54 has a central, non-continuous longitudinal partition wall 54a as well as an off-center, continuous longitudinal partition wall 54b between the channels 52a . 52b the flat tubes 52 on. The lower coolant box 55 has a centrally arranged, continuous longitudinal partition wall 55a on. How out 6a can be seen, the coolant after the entry according to arrow E across the entire width of the coolant box 54 distributed, but only in the series of channels 52a , In the lower coolant box 55 Then there is a deflection in depth, represented by two arrows T1 in 6 , As a result of non-continuous, central partition 54a Then there is a second deflection in depth, represented by an arrow T2 in 6 , Subsequently, in the exit-side row of the flat tubes 53 a double deflection in the width.

7 . 7a . 7b show a sixth embodiment of the invention, shown as a flow model 60 , This embodiment substantially corresponds to the embodiment according to 6 with the differences that the inlet and outlet of the coolant to a coolant box, namely the upper coolant box 64 are arranged and that takes place in the exit-side row of tubes only a simple deflection in width. Coincidentally, therefore, are the twofold deflections T1, T2 in the depth.

8th . 8a . 8b show a seventh embodiment of the invention in the form of a flow model 70 , wherein the inlet E and the outlet A of the coolant on opposite sides (narrow sides) of the upper coolant box 74 he follows. Due to an off-center, continuous longitudinal partition wall 74b There is a first deflection in depth in the lower coolant box 75 due to the non-continuous partition 75b , In 8th this deflection is shown as arrow T1. A second deflection in depth takes place in the upper coolant box 74 due to the non-continuous longitudinal partition wall 74a , what in 8th is shown by the arrow T2. The deflections in the depth T1, T2 thus take place - as can be seen on the flow model 70 can recognize - in itself diagonally opposite areas of the radiator.

9 . 9a . 9b show an eighth embodiment of the invention in the form of a flow model 80 , wherein the coolant inlet E and the coolant outlet A respectively frontally, ie on the leeward and windward side of the upper coolant tank 84 represented in 9a , he follows. Notwithstanding the previous embodiments, here is a non-continuous, centrally arranged longitudinal partition wall 84a is provided, which has on both sides for a deflection in depth - this is indicated by the arrows T2 in 9 shown. The first deflection in the depth takes place in the lower coolant box 85 - in 9 represented by the arrows T1. The coolant flow is thus due to the non-continuous partition 84a divided, ie, in equal part streams, which are easily deflected in each case on the exit-side row of tubes and merged again in the central region of the outlet A. This flow model 80 is characterized by a particularly homogeneous temperature distribution across the width due to the symmetrical flow guidance.

10 . 10a . 10b show a ninth embodiment of the invention in the form of a flow model 90 , wherein the coolant inlet E and the coolant outlet A are respectively centered on the longitudinal sides of the upper coolant box 94 respectively. As 10a shows, the upper coolant box points 94 two off-center arranged continuous longitudinal partitions 94b . 94c on.

The lower coolant box 95 represented in 10b , Has a twice interrupted, eccentrically arranged longitudinal partition wall 95c as well as also eccentrically arranged, end non-continuous longitudinal partition 95b on. So it comes in the lower coolant box 95 to a first two-sided deflection in the depth, in 10 represented by the two arrows T1. The incoming coolant flow is thus divided by the outer deflections in depth, then each simply deflected in width, reunited in the middle and then divided again and deflected in depth - this is in 10 represented schematically by the two arrows T2. The coolant sub-streams are in the last, luvseitig located channel row in the upper coolant box 95 merged again in the area of exit A. Here, too, there is the advantage of a homogeneous temperature distribution in the width and long flow paths, which allow a high heat transfer of the coolant to the air.

11 . 11a . 11b show a tenth embodiment of the invention, shown as a flow model 100 , 11a shows the upper coolant box 104 , which two eccentrically arranged through partitions 104b . 104c having. 11b shows the lower coolant box 105 , the two eccentrically arranged, non-continuous partitions 105b . 105c having. The Coolant is distributed after the entry first over the entire width of a channel row and then in depth - represents by the arrow T1 in 11 - redirected. In the central region of the radiator, a simple deflection in the width and then a further deflection in depth, represented by the arrow T2 in 11 , The exit of the coolant occurs - analogous to the entry - over the entire width of a channel row.

12 . 12a . 12b show an eleventh embodiment of the invention, shown as a flow model 110 , 12a shows the upper coolant box 114 with coolant inlet according to arrow E. 12b shows the lower coolant box 115 with coolant outlet according to arrow A. In the inlet-side flat tube row is a double deflection in width, then a deflection in depth, represented by the arrow T1 in 12 , then a further deflection in depth according to arrow T2 in 12 , The exit of the coolant takes place via the windward channel row.

13 . 13a . 13b show a twelfth embodiment of the invention, shown as a flow model 120 , The 13a . 13b show the upper coolant box 124 with coolant inlet E and coolant outlet A and the lower coolant box 125 , After the coolant inlet E takes place first in the leeward flat-tube row a simple deflection in width, then a deflection in depth - as indicated by arrow T1 in 13 - Then a distribution of the coolant to a channel row and a second deflection in depth, according to arrow T2 in 13 , The outlet A of the coolant takes place from the windward channel row.

14 . 14a . 14b show a thirteenth embodiment of the invention, shown as a flow model 130 , The 14a . 14b show the upper coolant box 134 with coolant inlet E and coolant outlet A and the lower coolant box 135 , The coolant is simply deflected in width after entering the leeward flat tube row, then in depth, according to arrow T1 in 14 , deflected and distributed on a channel row in full width. Subsequently, a second deflection in depth corresponding to the two arrows T2 in 14 and the exit of the coolant from the windward channel row.

15 . 15a . 15b show a fourteenth embodiment of the invention, shown as a flow model 140 , 15a shows the upper coolant box 144 with coolant inlet E and coolant outlet A while 15b the lower coolant box 145 shows. The coolant is distributed after entry over the entire width of the leeward channel row, then outside in the lower header 145 deflected in the depth, according to the arrow T1 in 15 , and distributed over the remaining three rows of channels. Then there is a double deflection in width over three rows of channels, which are flowed through parallel to each other.

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• - DE 4431107 C2 [0002]
• - DE 10247609 A1 [0003]
• - DE 102005048227 A1 [0004]

Claims (15)

Radiator for motor vehicles with an internal combustion engine, comprising a radiator block with at least four rows of flow channels ( 2a . 2 B . 3a . 3b ) for a cooling circuit of the internal combustion engine removable coolant, at least one coolant box ( 4 . 5 ) for the inlet and / or outlet, the distribution, collection and / or deflection of the coolant, wherein in the at least one coolant box ( 4 . 5 ) Longitudinal and / or transverse partitions ( 4a . 4b . 4c . 5a ) are arranged for deflecting the coolant in the depth and / or the width and wherein the radiator block of air in the flow direction (L) flows through and the coolant through the flow channels ( 2a . 2 B . 3a . 3b ) is guided in countercurrent, characterized in that the coolant on the inlet side to a number of flow channels ( 2a . 2 B ), which corresponds at most to the number of flow channels of a row. Radiator according to claim 1, characterized in that the coolant on two channel rows ( 2a . 2 B ) is distributed. Radiator according to claim 2, characterized that the inlet side coolant at least once is deflected in width. Radiator according to claim 3, characterized in that in the inlet-side coolant box ( 24 ) at least one transverse partition ( 24d ) is arranged. Radiator according to claim 3 or 4, characterized in that the coolant is then deflected in the depth and on at least one row of flow channels ( 3a . 3b ) is distributed. Radiator according to claim 5, characterized that the coolant then at least once is deflected in width. Radiator according to claim 6, characterized in that in the outlet-side coolant box ( 24 . 34 . 44 ) at least one transverse partition ( 24d ) is arranged. Radiator according to one of claims 2 to 7, characterized in that in the inlet and outlet coolant box ( 24 . 25 ; 34 . 35 ; 44 . 45 ) each have a longitudinal partition wall ( 24a . 25a ; 34a . 35a ; 44a . 45a ) is arranged. Radiator according to claim 1, characterized in that the coolant is applied to a series of flow channels ( 2a ; 52a ) is distributed. Radiator according to claim 9, characterized that the coolant then at least once in the depth (T1, T2) is deflected. Radiator according to claim 10, characterized in that in the inlet-side coolant box ( 54 ) at least one longitudinal dividing wall ( 54b ) is arranged. Radiator according to claim 11, characterized in that that the coolant before leaving it at least once is deflected in width. Radiator according to one of the preceding claims, characterized in that the inlet and outlet of the coolant from a narrow side or from a longitudinal side of a coolant box. Radiator according to one of the preceding claims, characterized in that in each case two adjacent flow channels ( 2a . 2 B ; 3a . 3b ) as Zweikammerflachrohre ( 2 . 3 ) are formed. Radiator according to claim 14, characterized in that between the flat tubes ( 2 . 3 ) Corrugated ribs are arranged.