DE102018214912A1 - Radiator for a vehicle - Google Patents

Abstract

The invention relates to a cooler of a vehicle air conditioning system or a vehicle cooling system with a plurality of tubes between two tube sheets, a reinforcement acting in the axial direction of the tubes being provided between at least two adjacent tubes.

Description

Technical field

The invention relates to a cooler of a vehicle air conditioning system or a vehicle cooling system. Such an air conditioning system or cooling system is used, for example, in a car. Furthermore, such a vehicle air conditioning system or such a cooling system can also be used in buses or trucks.

State of the art

A cooler for a vehicle air conditioning system usually comprises a plurality of pipes which extend between two pipe plates. In this context, coolers are known in which the coolant is introduced into one of the tube sheets, whereas the liquid is discharged through the other tube sheet. The heat exchange takes place during the passage of the coolant through the pipes.

Furthermore, coolers are known in which one of the tube sheets is divided into two sections by a separation, so that the coolant is supplied in one of the sections of this tube sheet, whereas the coolant is discharged in the further section of the corresponding tube sheet. The further tube sheet of such an embodiment serves to deflect the coolant.

With such coolers, it can occur in certain driving conditions, weather conditions or in the event of a defect that a supply valve retains a heated coolant so that it does not reach the cooler. The tubes of the cooler cool down when the ambient temperature is low.

If the valve then opens quickly, the heated coolant flows into a cooler that may have cooled down considerably due to the ambient conditions. Here, some of the pipes are filled with the heated coolant, causing these pipes to expand thermally. Due to the increased temperature gradients, this leads to increased thermal stresses, in particular in the area of connection points between the tubes and the tube sheets, as a result of which material fatigue and thus material failure can occur. This ultimately leads to leakage in the area of the connection point of a pipe and a pipe base.

Subject of the invention

The invention relates to a cooler for a vehicle air conditioning system or a vehicle cooling system, which has an increased service life.

The subject matter of claim 1 provides a corresponding cooler. Further preferred embodiments are listed in the dependent claims and / or explained in the description below.

In particular, a cooler of a vehicle air conditioning system or a vehicle cooling system with a plurality of pipes is provided between two pipe plates. The cooler is characterized in that a reinforcement acting in the axial direction of the tubes is provided between at least two adjacent tubes. This has the advantage that the reinforcement provided in this way counteracts thermal expansion. This can counteract material fatigue, particularly in the area of the connection points between tubes and a tube sheet, and consequently extend the service life of the cooler.

In this context, it is preferred that at least one reinforcement viewed in a direction in which the tubes are arranged next to or above one another is arranged outside the tubes. This procedure enables a comparatively inexpensive manufacture of the cooler.

Furthermore, it can be provided that the reinforcement is formed by a reinforcement grid, which is punched in particular. A useful and inexpensive solution can thus be provided.

At least one reinforcement, viewed in a direction in which the tubes are arranged next to or above one another, can be provided within the projection of the tubes. This arrangement reduces the depth of such a cooler and provides a particularly durable construction.

It can be provided in the context of one embodiment that the reinforcement is formed at least in sections by an open-pore metal foam. Such a metal foam can be applied after the installation of the tubes on the tube sheets between the tubes of the cooler, it being preferred that the metal foam is injected into the areas between the tubes after the tubes and tube sheets are installed. It has been shown that increased stiffness can be introduced with a metal foam.

According to a further embodiment it is provided that at least one reinforcement is formed by fins or fins which have a higher strength than other fins or fins provided between adjacent tubes. This measure can be integrated particularly advantageously into the assembly process for manufacturing the cooler.

According to a further embodiment, the reinforcement can be provided exclusively at the inlet of the tubes from a tube sheet and, if appropriate, preferably at a delimitation from an outlet of the tubes to the same tube sheet. Thus, a resource-saving and targeted construction is implemented.

In one embodiment, it is provided that adjacent reinforcements differ with regard to the axial extent. For example, one of the reinforcements in the axial direction of the adjacent tubes of the cooler can be made longer than the other reinforcement. In the case of three or more reinforcements, one or more reinforcements of the same or essentially the same length can be provided in the axial extent, or all the reinforcements differ in their length.

The reinforcement can be soldered on, so that it is correspondingly attached to one or more tubes of the cooler.

In a further embodiment, it is provided that at least one reinforcement is made of aluminum, which enables a weight-optimized solution.

Furthermore, the invention can be directed to the use of a cooler according to one of the above-mentioned embodiments in a vehicle, in particular a car.

Figure list

• 1 shows a schematic representation of a first embodiment according to the invention.
• 2 shows a schematic representation of a second embodiment of the invention.
• 3a shows a schematic view of a cooler with several reinforcements according to a first variant of the invention, and a detailed view of one of the reinforcements provided between tubes.
• 3b shows a detailed view of a reinforcement between adjacent tubes according to a second variant of the invention.
• 4 shows a detailed view of a cooler with a reinforcement according to a third embodiment of the invention.

Detailed description of the preferred embodiments

Preferred embodiments and variants of the invention are described below with the aid of the attached figures in order to explain the invention clearly. The described embodiments and variants can each be combined with one another. Furthermore, further modifications can be used with each of the described embodiments and variants to form further embodiments of the invention. Although the embodiments described below are to be understood purely by way of example, individual features of the embodiments or variants can be used to identify the invention.

1 shows a cooler 10 that a first tube sheet 14 and a second tube sheet 16 includes. On the first tube sheet 14 is an inlet 14a through which a coolant enters the radiator 10 reached. The second tube sheet 16 includes an outlet 16a through which the coolant from the radiator 10 is derived. Between the first tube sheet 14 and the second tube sheet 16 extend several pipes 12 through which the coolant from the first tube sheet 14 to the second tube sheet 16 can flow. The pipes 12 are spaced from each other. Between the pipes 12 are cooling fins 13 arranged to improve heat exchange with the environment.

At the in 1 illustrated embodiment of the cooler 10 it is a so-called I-cooler, in which the inlet 14a at an end portion of the first tube sheet 14 whereas the outlet 16a at an end section of the second tube sheet provided in the opposite direction 16 is arranged. In such an I-cooler, the coolant thus flows through one of the tubes and through a further section of one of the tube sheets before the coolant reaches the outlet 16a reached.

Between the pipes 12 that are close to the inlet 14a is adjacent to the first tube sheet 14 a first reinforcement 18a and a second reinforcement 18b provided instead of cooling fins. Alternatively, the reinforcements can also be used in addition to the cooling fins 13 on the respective pipes 12 to be appropriate. The reinforcements 18a . 18b viewed in one direction, are in which the tubes are arranged side by side or one above the other, within the projection of the tubes 12 ,

According to the in 1 illustrated embodiment extends the second reinforcement 18b in the axial direction of the neighboring pipes 12 further towards the second tube sheet 16 as the first reinforcement 18a , In other words, the second reinforcement 18b trained longer than the first reinforcement 18a ,

According to a first modification of the first embodiment, it can also be provided that only the first reinforcement 18a between two pipes 12 is arranged.

According to a second modification of the first embodiment, the first gain 18a the same or substantially the same length as the second reinforcement 18b exhibit.

According to a third modification of the in 1 illustrated cooler 10 can the inlet 14a , in the axial direction of the first tube sheet 14 considered, be arranged in the middle. The outlet can also be used 16a , in the axial direction of the second tube sheet 16 considered, be arranged in the middle.

The first embodiment and the modifications of the first embodiment described above are distinguished by the fact that between at least two adjacent tubes one in the axial direction of the tubes 12 acting reinforcement 18a . 18b is provided. In this way, a thermal expansion of the respective pipe end sections caused by a high temperature gradient can be reduced, so that also in the transition region between the pipes 12 and the first tube sheet 14 acting mechanical stresses can be reduced. Such a phenomenon can occur in particular in an area adjacent to the inlet.

2 shows a schematic representation of a second embodiment of a cooler 10 ' , The cooler 10 ' includes several pipes 12 ' that are between a first tube sheet 14 ' and a second tube sheet 16 ' extend.

In contrast to the cooler 10 the first embodiment is in the area of the first tube sheet 14 ' not just an inlet 14a ' , but also an outlet 14b ' , The outlet 14b ' is at the opposite end to the entrance 14a ' on the first tube sheet 14 ' intended. Furthermore, the first tube sheet 14 ' by delimitation 20th into an inlet side section 21 and an outlet-side section 22 divided. So flows through the inlet 14a ' introduced coolant through the pipes 12 ' , is in the area of the second tube sheet 16 ' deflected and reaches the outlet-side section 22 of the first tube sheet 14 ' , in the area of which the outlet 14b ' located.

Similar to the first embodiment are between the tubes 12 ' Cooling fins 13 ' intended.

In the field of pipes 12 ' which, viewed in side view, is adjacent to the boundary 20th of the first tube sheet 14 ' several reinforcements are provided 18c . 18d . 18e arranged in the axial direction of the tubes 12 extend. The reinforcements 18c . 18d . 18e are instead of the cooling fins 13 ' between the pipes mentioned 12 ' arranged. Alternatively, the reinforcements 18c . 18d . 18e also in addition to the cooling fins 13 ' on the pipes 12 ' to be appropriate.

A first reinforcement 18c has substantially the same length as a third reinforcement 18e , One between the first reinforcement 18c and the third reinforcement 18e arranged second reinforcement 18d has according to the second embodiment in the axial direction of the adjacent tubes 12 ' a greater length than the first reinforcement 18c and the third reinforcement 18e ,

According to a first modification of the second embodiment, the first gain 18c and the third reinforcement 18e be left out so the cooler 10 ' according to this modification only a reinforcement 18d having.

According to a second modification of the second embodiment, the reinforcements 18c - 18e in the axial direction of the neighboring pipes 12 ' essentially the same length.

According to a third modification of the second embodiment, are in an area adjacent to the inlet-side section 21 of the first tube sheet in which the inlet 14a ' for the coolant, between all pipes 12 Reinforcements provided.

In the 3a and 3b Variants of the reinforcements are shown as they can be used in the previously described embodiments as well as the further modifications of the respective embodiments.

The reinforcements in the 3a . 3b are viewed in a direction in which the tubes are arranged side by side or one above the other and within the projection of the tubes 12 " are provided. In particular, it is in 3a reinforcement shown 18 " around fins, which are staggered when viewed in plan view, so that the rigidity between the tubes 12 " is increased in this area. The reinforcement 18 " is here instead of between the tubes 12 " arranged cooling fins 13 " intended.

The staggered arrangement of reinforcement 18 ' is in the perspective detail view of 3a to recognize. The ribs of the reinforcement each form a plane, the rib of a plane being bent approximately at right angles in order to alternately be in contact with one of the adjacent pipes. The contact sections to an adjacent tube of an adjacent plane of the fins are similar, but staggered.

At the in 3b The variant shown is a metal foam between pipes 12 ''' introduced, which increases the rigidity in this area due to its open-pore structure. The metal foam can, for example, between adjacent pipes 12 ''' are injected, an open-pore structure forming during application or after application of the material, which then hardens. The reinforcement 18 '" is here instead of between the tubes 12 '" arranged cooling fins 13 '" intended.

4 shows a third embodiment of a cooler 10 "" having a gain 18f has, which is formed as a punched sheet and with several tubes 12 "" of the cooler 10 "" communicates. The reinforcement 18f according to the third embodiment, has diamond-shaped webs, the webs of the reinforcement 18f viewed in a side view inclined to the direction of extension of the tubes 12 "" are aligned. Between the pipes 12 "" extend cooling fins 13 "" which, according to the third embodiment, are also provided in the areas in which the reinforcement 18f on the pipes 12 "" is appropriate.

According to a first modification of the third embodiment, the webs of reinforcement 18f at least partially perpendicular or substantially perpendicular to the direction of extension of the tubes 12 "" of the cooler 10 "" be aligned.

In a second modification of the third embodiment, the gain 18f be designed as an aluminum grille, which is attached to several tubes of the cooler by means of a soldered connection.

According to a third modification of the third embodiment, the gain 18f also be designed as a sheet, which is in contrast to the in 4 illustrated embodiment is present without recesses.

Claims (10)

Cooler (10) of a vehicle air conditioning system or a vehicle cooling system with a plurality of tubes (12) between two tube sheets (14, 16), characterized in that a reinforcement acting in the axial direction of the tubes (12) is provided between at least two adjacent tubes (12). Radiator (10) after Claim 1 , characterized in that at least one reinforcement (18) is viewed in a direction in which the tubes (12) are arranged side by side or one above the other is arranged outside the tubes. Radiator (10) after Claim 1 or 2 , characterized in that the reinforcement is formed by a reinforcing grid (18) which is in particular stamped. Cooler (10) according to one of the preceding claims, characterized in that at least one reinforcement viewed in a direction in which the tubes (12) are arranged side by side or one above the other is provided within the projection of the tubes (12). Cooler (10) according to one of the preceding claims, characterized in that the reinforcement is formed at least in sections by an open-pore metal foam. Cooler (10) according to one of the preceding claims, characterized in that at least one reinforcement is formed by fins or fins which have a higher strength than other fins or fins provided between adjacent tubes. Cooler (10) according to one of the preceding claims, characterized in that the reinforcement only at the inlet of the tubes (12) from a tube sheet (14), and optionally preferably at a boundary (20) to an outlet of the tubes (12) to the same Tube plate (14) is provided. Cooler (10) according to any one of the preceding claims, characterized in that adjacent reinforcements differ in terms of an axial extension. Cooler (10) according to one of the preceding claims, characterized in that at least one reinforcement is soldered. Cooler (10) according to one of the preceding claims, characterized in that at least one reinforcement is made of aluminum.

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