阅读说明：本技术 热交换器 (Heat exchanger ) 是由 G·J·克莱尔 J·拉普西克 J·马蒂尼 于 2018-06-07 设计创作，主要内容包括：本发明涉及热交换器,上述热交换器包括：多个流体引导金属管(2),具有以隔开间隔的方式相互并排的管端部(3)；至少一个管底部(4),由塑料形成,具有能够在内部收容上述管端部(3)的收容贯通口(5)；以及收集箱(6),由塑料形成,能够通过形成于管底部与收集箱之间的锁定装置来与管底部(4)相连接,可向管底部(4)与收集箱(6)之间插入密封部(9),上述密封部确保管端部(3)上的管底部(4)的压入配合,并使收集箱(6)对管底部(4)进行密封且使管底部(4)对管端部(3)进行密封。(The present invention relates to a heat exchanger, comprising: a plurality of fluid-conducting metal tubes (2) having tube ends (3) which are arranged next to one another at spaced intervals; at least one tube bottom (4) formed of plastic and having a receiving through-hole (5) capable of receiving the tube end (3) therein; and a collection box (6) which is made of plastic and can be connected to the tube bottom (4) by a locking device formed between the tube bottom and the collection box, and between the tube bottom (4) and the collection box (6) a seal (9) can be inserted which ensures press-fitting of the tube bottom (4) on the tube end (3), seals the collection box (6) against the tube bottom (4) and seals the tube bottom (4) against the tube end (3).)

1. A heat exchanger, comprising: a plurality of fluid-conducting metal tubes (2) having tube ends (3) which are arranged next to one another at spaced intervals; at least one tube bottom (4) formed of plastic and having a receiving through-hole (5) capable of receiving the tube end (3) therein; and a collecting box (6) formed of plastic, connectable with the tube bottom (4) by means of a locking device formed between the tube bottom and the collecting box, characterized in that,

A sealing part (9) is inserted between the tube bottom part (4) and the collecting box (6), the sealing part ensures the press fit of the tube bottom part (4) on the tube end part (3), and the collecting box (6) seals the tube bottom part (4) and the tube bottom part (4) seals the tube end part (3).

2. The heat exchanger according to claim 1, wherein the sealing portion (9) is formed by a compressible elastomer sealing portion having a through insertion opening (10), the through insertion opening (10) having a through insertion extension (10.1) for the tube end (3), the elastomer sealing portion (9) being inserted between an inner surface of the receiving through opening (5) and an outer periphery of the tube end (3).

3. Heat exchanger according to claim 1, characterized in that the above-mentioned seal (9) is integrated in the tube bottom (4) or in the collecting tank (6) by means of an injection moulding method.

4. Heat exchanger according to claim 1, characterized in that the seal is inserted between the tube bottom (4) and the collecting tank (6) by welding of the material bond of the tube bottom (4) and the collecting tank (6).

5. Heat exchanger according to claim 4, characterized in that welding points are arranged at a mutual distance in mutually facing inner faces of the collecting tank (6) and the tube bottom (4), at which welding points the collecting tank (6) and the tube bottom (4) are welded to each other.

6. A heat exchanger according to claim 1 wherein said locking means comprises: clips arranged on the tube bottom (4) or the collection box (6); and a locking opening (8) arranged in the tube bottom (4) or the collection box (6) in a manner facing the clip (7).

Technical Field

The present invention relates to a heat exchanger characterized by improved durability against temperature changes and weight reduction. Such a heat exchanger is particularly suitable for use in a motor vehicle.

Background

Disclosure of Invention

Technical problem

The object of the invention is to provide a heat exchanger with improved installation space utilization and a relatively low weight.

Means for solving the problems

The above technical problem is solved by a heat exchanger having the features according to claim 1 of the present invention. Various modifications and variations are shown in the dependent claims.

The heat exchanger according to the invention has a plurality of fluid-conducting metal tubes which can be arranged longitudinally alongside one another from within one block. In this case, the pipe ends of the metal pipe as the pipe protrusion are arranged at intervals from each other. Further, the heat exchanger according to the present invention has at least one tube bottom portion formed of plastic, in which a plurality of receiving through-holes are formed. The arrangement of the receiving through-openings of the tube bottom corresponds to the arrangement of the tube ends so that finally the tube bottom can be mounted on the tube ends, in which case the tube ends can be received in the receiving through-openings. Also, a collecting box formed of plastic is provided, which is connected to the pipe bottom by a locking means formed between the pipe bottom and the collecting box, in which case a sealing part may be inserted between the pipe bottom and the collecting box, which sealing part ensures a press fit (press fit) of the pipe bottom on the pipe end, and which seals the collecting box against the pipe bottom and the pipe bottom against the pipe end.

The tube bottom and the collecting box are formed of plastic, so that a weight reduction of approximately 50% is possible in relation to the aluminum parts. The advantage of the heat exchanger according to the invention is therefore essentially a weight reduction. Furthermore, material costs can be saved by the use of more advantageous plastics than aluminum.

According to an embodiment of the heat exchanger of the present invention, it is proposed that the sealing portion is a compressible elastomer sealing portion having a through insertion opening with a through insertion extension for the pipe end, so that the sealing portion can finally be inserted between an inner surface accommodating the through opening and an outer periphery of the pipe end. Preferably, the shape of the cross section of the through insertion opening and the shape of the cross section of the through insertion extension conform to the outer peripheral side shape of the pipe end. Preferably, the inner circumference of the through-insertion opening and the inner circumference of the through-insertion extension are smaller than the outer circumference of the pipe end, so that finally a press-fit can be ensured.

The elastomer seal can be realized as a separate structural part, which can additionally be inserted between the pipe end and the pipe bottom and the collecting tank when the pipe bottom is mounted on the pipe end. However, it is also possible to provide that the seal is integrated or inserted into the tube bottom or the collection tank by means of an injection molding method, in particular by means of a combination of injection molding methods. The sealing portion is injected into the tube bottom or the collection tank by a combination of injection molding methods, so that the sealing portion becomes a constituent part of each relevant component. Such a case can reduce the complexity of the arrangement and the cost by the ease of assembly of the components, because the sealing portion does not need to be separately inserted.

According to another variant embodiment of the heat exchanger according to the invention, it can be provided that the seal is inserted between the tube bottom and the collection tank by welding of the tube bottom in material combination with the collection tank. In this case, the seal is formed by melting of plastic, which is the material of the collecting tank and the bottom of the tube. The plastic of the bottom of the tube is also deformable by the welding process to ensure a press fit of the bottom of the tube over the end of the tube. The welding of the plastic of the tube bottom and the collecting container can thus be effected by material-bonding of the components, such as the tube bottom and the collecting container, and sealing of the tube ends. Preferably, the tube bottom and the collecting tank are welded to each other when mounted on the tube end.

In the facing inner faces of the collecting tank and the tube bottom, there can be provided joints or welds arranged in a spaced-apart manner, in which joints or welds the collecting tank and the tube bottom can be welded to one another. Preferably, a plurality of welding points are distributed over the entire circumference of the arrangement formed by the collecting box and the tube bottom, so that finally a uniform connection can be achieved. Mechanical additional interconnection of the components, such as the collecting tank and the pipe bottom, protruding above the locking connection of the locking device is achieved by spot welding at the welding points.

the locking means may comprise a plurality of clips arranged at the bottom of the tube or in the collection box and locking openings arranged in the bottom of the tube or in the collection box in an opposing manner to the clips. It is therefore possible to propose a variant embodiment in which the clips are formed on the collecting chamber, in which case the locking openings are formed in an opposing manner on the bottom of the tube. At this time, it is preferable that the clips and the locking openings which are placed opposite each other and the clips cooperate with the insides thereof to form a locking connection are distributed uniformly over the entire length of the array formed by the tube bottom and the collecting box. A lower insertion depth of the tube bottom is required due to the locking connection, as this advantageously contributes to an efficient utilization of the available heat transfer area.

ADVANTAGEOUS EFFECTS OF INVENTION

The concept according to the invention of the heat exchanger is that the tube bottom and the collecting tank use plastic to achieve a weight reduction and a cost reduction. The heat exchanger according to the invention is particularly suitable for use in automobiles.

Drawings

Additional details, features and advantages of the invention are apparent from the following detailed description of various embodiments, which proceeds with reference to the accompanying figures. Wherein the drawings are as follows.

Fig. 1 is a schematic exploded view showing a first embodiment of a heat exchanger according to the present invention.

Fig. 2 is a diagram showing the collection tank with the seal and the bottom of the tube as viewed from the side.

Fig. 3 is a schematic sectional view showing the first embodiment, in which case the collection container having the sealing portion and the bottom of the tube is engaged.

Fig. 4 is a schematic detail sectional view showing the first embodiment without the seal portion.

Fig. 5 is a schematic detail sectional view showing the first embodiment having the sealing portion.

Fig. 6 is a diagram showing a second embodiment of a heat exchanger according to the present invention.

Detailed Description

A plurality of features repeated in each drawing are denoted by the same reference numerals.

Fig. 1 shows a first embodiment of a heat exchanger according to the invention in an exploded view. A block formed by a plurality of fluid-conducting metal tubes 2 arranged side by side in the longitudinal direction is shown by reference numeral 1. A plurality of disks formed of metal may be formed between the plurality of metal pipes. The pipe ends 3 of the metal pipe 2 have a narrow open cross section and are spaced apart side by side. A tube bottom formed of plastic and having a receiving through opening 5 is shown by reference numeral 4. The arrangement of the through-openings 5 in the bottom part 4 corresponds to the arrangement of the pipe ends 3 in the block 1, and the bottom part 4 can be finally attached to the pipe ends 3, in which case the pipe ends 3 can be inserted into the through-openings 5 in the bottom part 4. The collecting container 6, which is formed from plastic, can be connected to the tube bottom 4 by means of a clip 7 arranged on the collecting container 6 and a locking device formed by a locking opening 8 arranged opposite the clip 7 on the tube bottom 4. A seal 9 can be inserted between the tube bottom 4 and the collecting box 6, which seal ensures a press-fit of the tube bottom 4 on the tube end 3, and seals the collecting box 6 against the tube bottom 4 and the tube bottom 4 against the tube end 3. In the illustrated embodiment, an elastomer sealing part which has a through-insertion opening 10 for the pipe end 3 and is compressible serves as the sealing part 9, which can finally be inserted between the inner face which accommodates the through-opening 5 and the outer circumference of the pipe end 3. In order to ensure a press-fit of the tube bottom 4 at the tube end 3, the cross-section of the through-insertion opening 10 is smaller than the cross-section of the tube end 3. Also, the seal portion 9 has an annular projection 11 which is formed in a lip shape at an outer peripheral edge of the seal portion 9 and seals the catch tank to the tube bottom 4 as surrounding the inside of the catch tank 6.

Fig. 2 is a diagram showing the collecting tank 6 with the sealing 9 and the tube bottom 4 of the first embodiment of the heat exchanger according to the invention seen from the side. The sealing part 9, which is a compressible elastomer sealing part, has through-insertion openings 10, the through-insertion openings 10 having through-insertion extensions 10.1, the arrangement of these through-insertion openings corresponding to the arrangement of the receiving through-openings 5 of the tube bottom 4. The shape and outer periphery of the insertion through extension 10.1 correspond to the shape and inner periphery of the receiving through opening 5. The cross-section of the through-insertion opening 10 and the through-insertion extension 10.1 is smaller than the cross-section of the pipe end 3, so that when the pipe end 3 (not shown) is inserted into the through-insertion opening 10 or the through-insertion extension 10.1, the sealing part 9 is pushed and elastically presses the pipe bottom part 4, whereby a press-fit in the form of a positive-engagement coupling is formed between the pipe bottom part 4 and the pipe end 3.

Fig. 3 is a sectional view showing the first embodiment in the mounted state, in which case the collecting chamber 6, the sealing part 9, the tube bottom 4 and the tube end 3 are inserted inside each other, in which case the press-fit on the tube end 3 and the sealing of the tube end 3 to the tube bottom 4 of the tube bottom 4 and the sealing of the tube bottom 4 of the collecting chamber 6 are ensured by the compressible sealing part 9.

Fig. 4 is a detailed cross-sectional view of the first embodiment without a seal between the tube bottom 4 and the collection tank 6. In the illustrated example, the tube bottom 4 and the collection chamber 6 are arranged in a state of being inserted together, in which case the clip 7 of the collection chamber 6 fits into the locking opening 8 of the tube bottom 4. If there is no seal between the tube bottom 4 and the collecting container 6, a fixed mounting on the tube end 3 and the seal is not ensured.

Fig. 5 is a detail section showing the first embodiment, in which case the elastomer seal 9 is inserted between the tube bottom 4 and the collecting tank 6 and between the tube bottom 4 and the tube end 3. Since the inner cross section of the through-insertion opening 10 with the through-insertion extension 10.1 of the compressible elastomer sealing 9 is smaller than the outer cross section of the tube end 3, the elastomer sealing 9 is pressed into the receiving through-opening 5, finally ensuring a press-fit of the tube bottom 4. In this case, an annular projection 11 in the form of a lip formed on the outer peripheral edge of the elastomer seal 9 is arranged between the tube bottom 4 and the collection tank 6. By the locking connection between the collecting chamber 6 and the tube bottom 4, the annular projection 11 of the elastomer seal 9 is compressed, whereby the collecting chamber 6 seals the tube bottom 4. Reference numeral 10.2 denotes an annular projection of the through-insertion extension 10.1 of the through-insertion opening 10. The annular projection 10.2 ensures a secure mounting of the sealing 9 in the receiving through-opening 5 of the bottom 4, and finally the sealing is not pushed outward when a tensile or shear load is applied in the longitudinal direction of the metal tube 2, which may be caused, for example, by thermal expansion of the metal tube 2. The arrangement described above thus makes it possible to achieve a fixed mounting and sealing of the same pipe ends 3 as inside the collecting chamber 6.

Fig. 6 is a diagram showing a second embodiment of a heat exchanger according to the invention with a tube bottom 4 formed of plastic and having a receiving through-opening 5 in order to be able to receive a tube end 3 (not shown) in its interior and a collecting tank 6 formed of plastic and connectable with the tube bottom 4 by means of a locking device formed between the tube bottom and the collecting tank. In this case, a seal can be introduced between the tube bottom 4 and the collecting box 6, which seal ensures a press-fit of the tube bottom 4 on the tube end 3, and seals the collecting box 6 against the tube bottom 4 and the tube bottom 4 against the tube end 3. In this variant, the seal can be inserted between the tube bottom 4 and the collection tank 6 by welding of the tube bottom 4 and the collection tank 6 by material bonding. The seal is formed by melting plastic, which is the material of the collection tank 6 and the pipe bottom 4. The plastic of the tube bottom 4 is also deformable by the welding process to ensure a press-fit of the tube bottom 4 on the tube end 3. The welding of the plastic of the tube bottom 4 and the collecting container 6 thus enables a material-bonding connection of the components, such as the tube bottom 4 and the collecting container 6, and a sealing of the tube end 3. Preferably, the tube bottom 4 and the collecting chamber 6 are welded to each other when mounted on the tube end 3.

In the interior side of the collecting box 6 facing the tube bottom 4, joints or welding points 12 are shown, which are arranged at a distance from one another and in which the collecting box 6 and the tube bottom 4 can be welded to one another. Preferably, the welding points 12 are distributed over the entire circumference of the arrangement formed by the collecting box 6 and the tube bottom 4, so that a uniform connection is finally achieved. Mechanical additional interconnection of the components, such as the collecting tank 6 and the tube bottom 4, projecting above the locking connection of the locking device is achieved by means of a circular or spot-shaped weld formed at the welding point.

Industrial applicability

The present invention relates to a heat exchanger characterized by improved durability against temperature changes and weight reduction. Such a heat exchanger is particularly suitable for use in a motor vehicle.