DE29722841U1 - Cooler for diesel oil flowing back from the injection pump or injector - Google Patents

Description

Cooler for diesel oil flowing back from the injection pump or injector

The invention relates to a cooler for the excess diesel oil flowing back to the tank from the injection pump and/or injection nozzle of a diesel engine, which cooler is designed as an air-cooled heat exchanger and is composed and connected from two deep-drawn sheet metal parts, in particular from an aluminum alloy, wherein a cooling coil is formed by a deep-drawn impression in at least one of the sheet metal parts, which is tightly connected to the other sheet metal part, so that the cross section of the cooling coil is closed.

Such a cooler is already known from DE-297 15 878 Ul and has proven itself. In modern diesel engines, the fuel is injected into the combustion chamber(s) at the highest possible pressure, for which it is supplied in excess. This excess, which is then not injected, must flow back into the diesel oil tank. Due to the high pressure load and also the generally high ambient temperature, this returning diesel oil is heated up very strongly and must therefore be fed back through a cooler, which is usually an air-cooled heat exchanger.

In addition to the cooler mentioned at the beginning, it is also already known to manufacture such coolers from an extruded profile part with attached or soldered end pieces, whereby these parts consist of an aluminum alloy. When they are machined to the required length, chips are produced, which is why these coolers have to be thoroughly cleaned so that no chips remain in them. This makes the manufacture of such extruded coolers complex, without the risk of contamination being completely eliminated.

With the coolers mentioned above, this danger is eliminated.

The task now is to improve the cooling performance of the cooler mentioned at the beginning, so that either the entire unit can be kept smaller with the same cooling performance or more heat can be dissipated with it while remaining the same size. Nevertheless, the advantage should be retained that no chips are produced during production that could get into the cooler.

0 The solution to this problem in a cooler of the type mentioned at the beginning consists in that cooling fins engage at least one surface of the cooler in the direction of extension of the cooling coils,

) which are covered by a cover at their edge regions or edges facing away from the cooler, and that open channels are formed between the cooling fins and the cooler and/or the cover in the longitudinal direction or extension direction of the respective cooling coil regions.

Surprisingly, cooling fins are attached to the sheet metal cooler 0, and these are also provided with a cover so that channels are created between the cooler, the cooling fins and the cover through which the air can flow. This achieves particularly effective cooling and, with the same dimensions of the cooler, a greater cooling capacity is achieved, or the cooler can be used for a

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certain cooling performance can be kept lower than without the cooling fins.

With extruded coolers, the installation of cooling fins is obvious, but with coolers made of sheet metal, this represents a surprising design, whereby the invention makes use of the idea that these cooling fins can be arranged between the cooler and the cover and thus easily held in between, i.e. they are not manufactured in one piece with the cooler, as is the case with the extrusion process. 10

fc In a practical and advantageous manner, at least a part of the cooling fins can be placed between two parallel cooling coil areas on the surface of the cooler with an edge facing the cooler and pressed onto it by means of the cover. This makes use of the fact that the cooler has a recess between each cooling coil area, on both sides of which the parallel cooling coil areas run. This recess is then used to insert and attach cooling fins, which can thus be held positively 0 on the surface of the cooler across their cross section. If they are pressed and fixed in this position by the cover, good heat transfer is achieved at the same time.

A further advantageous embodiment can consist in that several cooling fins are connected by touching each other at their edge areas or are connected in one piece at the edge areas, so that the cross section of these connected cooling fins has a back and forth, zigzag, Z-shaped and/or S-shaped course, whereby the cover in each case covers the contact area of two connected cooling fins at their

This design allows two connected, i.e. touching or even integrally connected cooling fins to be inserted together into the recess between two cooling coil areas. 35

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This results in cooling fins that are slightly angled to one another in cross-section, which support one another when they are pressed together onto the cooler by the cover or cover plate, and are held with their cooler-side edges in the recesses between the cooling coil areas. This angled position simultaneously increases the cross-sectional length and thus the effective width of the cooling fins.

The cover can form-fit over the edge areas of the cooling fins facing away from the cooler by means of a bead or similar deformation fc. This means that the fins can also be held in a form-fit manner at their edges that are farther away from the cooler, so that if they become trapped between the cover and the cooler, they are enclosed at both edges and thus held in a form-fit manner. This is particularly effective when the cooling fins are manufactured as a continuous zigzag part, in which all the cooling fins, which are slightly inclined to one another, are connected in one piece.

It is particularly advantageous if the additional cooling fins and/or the cover are made of sheet metal, metal, in particular an aluminum alloy or aluminum. This allows for very simple production, which also contributes to the production of the cooler itself.

) fits.

It has already been mentioned that all cooling fins can be made from a single, roughly zigzag-shaped sheet metal. They can have roughly the same height or cross-sectional length and the cover that covers them can be attached to the edge of the cooler, particularly outside the cooling coils, for example by means of a pressure-jointed connection, a screw connection, a weld, a soldered connection or the like. Thus, the cover and the actual cooler form a housing in which the cooling fins are located and in which they are fixed, so that there is good heat transfer from the cooler to the cooling fins 5 and to the cover, so that very effective cooling can be achieved in a small space.

Cooling can be achieved.

The distance of the cover and thus the effective cross-sectional length of the cooling fins can be greater than the thickness of the cooling coils. Nevertheless, the entire cooler with cooling fins has a compact design.

In order to achieve a flat design, the cooling fins protruding from one side of the radiator and their cover can, in the position of use, face the roadway of a motor vehicle with a diesel engine.

fc Although cooling fins could protrude from both sides of the radiator and be held by a cover, it is sufficient in the arrangement according to the invention if this only happens on one side, which gives the cover an additional function, namely that of protection against particles thrown up. The entire radiator can then also be accommodated within the engine compartment in places that may be exposed to parts thrown up from the road, without there being any risk of damage to the radiator. In comparison to a radiator with cooling fins on both sides, 0 there is also considerably less effort if cooling fins and a cover are only arranged on one side, tests having shown that this makes it possible to achieve the same result overall as the

) sheet metal cooler provides an effective and sufficiently large

Cooling performance can be achieved in a small space.
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An embodiment of the invention is described in more detail below with reference to the drawing. It shows, in a partially schematic representation:

Fig.l is a view of a cooler according to the invention from the side of its cover, so that the cooling coils molded or embossed on the cooler itself are not visible,

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Fig.2 is a longitudinal section along line BB in Fig.l,

Fig.3 a front view and

Fig.4 shows a cross section along the section line A-A in Fig.1 of the cooler for diesel oil according to the invention, designed as an air-cooled heat exchanger with cooling fins projecting to one side, wherein the cooling fins are held between the cooler itself and a cover connected to it.

A cooler, designated as a whole with 1, serves to cool the excess diesel oil flowing back to the tank from an injection pump and/or injection nozzles of a diesel engine, whereby the cooler 1 is designed as an air-cooled heat exchanger.

Above all, when looking at Fig. 2 and 4 at the same time, it becomes clear that this cooler 1 is composed and connected from two deep-drawn sheet metal parts 2, which are expediently made of an aluminum alloy that conducts heat well, which at the same time allows the already mentioned deep-drawing or embossing of a

f cooling coil 3. The cooling coil 3, which can be seen above all in Fig. 1, is thus formed by deep-drawn impressions in the 5 sheet metal parts 2, after which the sheet metal parts 2 are tightly connected to one another, so that the cross-section of the cooling coil 3, which can be seen on the one hand in Fig. 2 and on the other hand above all several times in Fig. 4, is closed.

0 Two deep-drawn sheet metal parts 2 are provided which are essentially symmetrical to a longitudinal center plane 4, each of which contains one half of the cross section of the cooling coil 3 and are connected to one another in such a way that the parts of the embossed cooling coil 3 complement one another to form the cooling coil 3 which protrudes on both sides relative to the longitudinal center plane 4.

The cross-section of the cooling coil 3 is approximately round in the exemplary embodiment, i.e. a cooling coil part with a circular arc in cross-section is embossed into each of the sheet metal parts 2, whereby this circular arc is slightly smaller than a semicircle in the exemplary embodiment, which makes it easier to remove a corresponding embossing tool.

The two sheets or sheet metal parts 2 forming the cooler 1 are welded together to form a tight connection, namely by laser beam welding. This creates a tight

A strong connection and welding is achieved with a relatively low heat input.

In Fig.l, the weld seams 5 used to connect the two sheet metal parts 2 are indicated by dot-dash lines and it can be seen that they are arranged on the outside of the cooling coil 3 and between the respective turns 3a of the cooling coil 3, so that the entire course of the cooling coil 3 takes place between weld seams 5 and thus the best possible tightness is achieved. 20

Outside the cooling coil 3, the sheet metal parts 2 forming the cooler 1 in the embodiment have protruding edges or flanges 6 with fastening points designed as holes 7, which facilitate assembly. Corresponding connections 8 can be seen at the inlet and outlet of the cooling coil 3. It should also be mentioned that the number of turns and also the side where the connections 8 are provided could be different from the embodiment.

Above all, when looking at Figures 2 to 4 at the same time, it becomes clear that cooling fins 9 engage on a surface of the cooler 1 in the direction of extension of the respective parallel sections of the cooling coil 3, which are overlapped and held by a cover 10 at their edge regions or edges 9a facing away from the cooler 1. Between the cooling fins 9 and the cooler 1 and

In the cover 10, open channels 11 are formed in the longitudinal direction or extension direction of the respective cooling coil areas and the cooling fins 9, through which the cooling air can flow, especially the air flow generated by the airstream when the cooler 1 is used on a motor vehicle.

It can be seen, particularly in Figures 3 and 4, that the cooling fins 9 with their edge 9b facing the cooler 1 are each placed on the surface between two parallel cooling coil regions 3a, in which these cooling coil regions run parallel to one another.

fe of the cooler 9 and are fixed or pressed into this position by means of the cover 10.

The cooling fins 9 are connected in their edge areas in that they touch each other both at their edges 9b facing the cooler 1 and at their edges 9a facing away from the cooler 1 and in the exemplary embodiment are even connected in one piece. The cooling fins 9 thus form a connected cross-section that has a back and forth, zigzag-shaped course, with the cover 10 overlapping the contact area of two touching or connected cooling fins 9 at their edge 9a facing away from the cooler 1.

The cover 10 overlaps the edges 9a of the cooling fins 9 facing away from the cooler 1 in the exemplary embodiment by means of a bead 10a which runs in the direction of extension of the cooling fins 9 and thus forms a positive connection that is effective transversely to this course, as is achieved at the opposite edges 9b by the cooling coils 3. Although the cooling fins 9 are at an angle to one another with their cross sections, they are held firmly and immovably and clamped in a positive fit between the cooler 1 and the cover 10 so that they do not require any further fastening. They are all made of a zigzag-shaped bent sheet and each have approximately the same width or cross-sectional length so that the cover 10 is essentially parallel to the longitudinal center of the cooler.

1. The cover 10, which like the cooling fins 9 is made of sheet metal, in particular of an aluminum alloy or aluminum, is fastened in the edge area of the cooler 1 outside the cooling coils 3 according to Fig. 1, 3 and 4, thus has a corresponding bend that reaches up to the cooler 1 and can have a pressure-jointed connection, a screw connection, a weld, a soldered connection or the like with the cooler 1.

In Figures 3 and 4 it can also be seen that the distance of the cover 10 and thus the effective cross-sectional length of the

Jk cooling fins 9 is larger than the thickness and cross-sectional dimensions of the cooling coils 3 or the entire cooler 1. This results in a very good cooling effect solely due to air cooling.

The cooling fins 9 protruding from one side of the radiator 1 and their cover 10 can face the road in the position of use for a motor vehicle with a diesel engine in this vehicle, so that the cover 10 simultaneously protects the radiator 1 and its cooling fins 9 against stone chips or the like. The radiator can be mounted in a suitable manner using special retaining tabs 12.

) It should also be mentioned that the channels 11 also allow liquid or water cooling under certain circumstances, if they are provided with corresponding connections on the front side.

Expectations

Claims (7)

&iacgr;&ogr; Claims 1. Cooler for the excess diesel oil flowing back to the tank from the injection pump and/or injection nozzle of a diesel engine, which cooler is designed as an air-cooled heat exchanger and is composed and connected from two deep-drawn sheet metal parts, in particular from an aluminum alloy, wherein a cooling coil is formed by a deep-drawn impression in at least one of the sheet metal parts, which is tightly connected to the other sheet metal part, so that the cross section of the cooling coil is closed, characterized in that on at least one surface of the cooler (1) in the direction of extension of the cooling coils (3) cooling fins (9) which are covered by a cover (10) at their edge regions or edges (9a) facing away from the cooler (1), and that open channels (11) are formed between the cooling fins (9) and the cooler (1) and/or the cover (10) in the longitudinal direction or direction of extension of the respective cooling coil regions. 2. Cooler according to claim 1, characterized in that at least a part of the cooling fins (9) with an edge (9b) facing the cooler (1) is placed between two parallel cooling coil regions (3a) on the surface of the cooler (9) and is pressed on by means of the cover (10). 3. Cooler according to claim 1 or 2, characterized in that several cooling fins are connected by touching each other at their edge areas or are connected in one piece at the edge areas, so that the cross section of these connected cooling fins has a back and forth, zigzag, Z-shaped and/or S-shaped course, whereby the cover (10) in each case covers the contact area of two connected cooling fins (9) at their edge away from the cooler (1). *■ • i ·* • 1 * t •t The * • a* *·» • *
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opposite edge (9a). 4. Cooler according to one of claims 1 to 3, characterized in that the cover (10) engages in a form-fitting manner over the edge regions (9a) of the cooling fins (9) facing away from the cooler (1) by means of a bead (10a) or similar deformation. 5. Cooler according to one of claims 1 to 4, characterized in that the additional cooling fins (9) and/or the cover (10) consist of sheet metal, metal, in particular of an aluminum alloy or aluminum. 6. Cooler according to one of claims 1 to 5, characterized in that all cooling fins are formed from a single, approximately zigzag-shaped bent sheet metal and have approximately the same height or cross-sectional length and that the cover (10) overlapping them is fastened in the edge region of the cooler (1), in particular outside the cooling coils (3), for example by means of a pressure-jointed connection, a screw connection, a weld, a soldered connection or the like. ) 7. Cooler according to one of claims 1 to 6, characterized in that the distance of the cover (10) and thus the effective cross-sectional length of the cooling fins (9) is greater than the thickness of the cooling coils (3). 8. Radiator according to one of claims 1 to 7, characterized in that the cooling fins (9) projecting from one side of the radiator (1) and their cover (10) face the roadway of a motor vehicle with a diesel engine in the position of use. 5 Patent Attorney