The present application claims the benefit of and priority from German Application No. DE 102007049932.0, filed Oct. 18, 2007, the entire disclosure of which is hereby incorporated by reference herein.
1. Field of the Invention
The invention relates to a connecting element for a fluid containing pivotal component, in particular a heat exchanger.
Cooling of utility vehicles, in particular of farm machinery and construction machinery, takes place by means of a plurality of cooling circuits integrated into the utility vehicles, inside which circuits a heat exchanger may be fitted in each case. The heat exchangers ensure that a coolant cannot exceed a specific temperature. Owing to the limited space available inside the utility vehicles the heat exchangers are fitted so as to be optimally compact, the heat exchangers conventionally being arranged in succession in the direction of travel of the utility vehicle. The individual heat exchangers are fitted in the utility vehicles so as to be non-rotatable. The heat exchangers also each comprise an inlet line and an outlet line for supplying and removing the coolant into the heat exchangers.
The compact and non-rotatable arrangement of the heat exchangers inside the utility vehicles makes access to a particular heat exchanger difficult during repair, cleaning and maintenance tasks. It is precisely when utility vehicles are used in a dusty environment, such as use of farm tractors on dry soils, that particles of dirt and dust cannot be prevented from accumulating in the cooling meshes of the heat exchangers. These particles of dirt and dust therefore have to be removed several times a day using brooms, compressed air or high pressure cleaners in order to prevent a reduction in the effectiveness of cooling of the utility vehicle. The heat exchangers are not accessible due to the successive and non-rotatable arrangement thereof. Individual heat exchangers of the cooling system are accordingly arranged to move, so they can be pivoted about an axis of rotation and/or linearly displaced for cleaning and are therefore freely accessible.
2. Description of Related Art
EP 0 952 024 discloses a radiator arrangement of a motor vehicle in which the heat exchangers are not arranged in succession but are spatially arranged around a chamber. Providing that at least one heat exchanger is arranged so as to move, accessibility in order to remove dirt is much improved.
A requirement of all the movably arranged heat exchangers known from the prior art however is that the inlet and outlet lines for supplying and removing the coolant are flexible rather than rigid. In practice hose lines are used for this purpose which, owing to the flexibility of the hose, allow movement of the heat exchanger.
Use of hose lines has the drawback however that production costs are much higher compared with inflexible pipe lines. The screw joints used for connecting the inlet and outlet lines may also become loose due to the movement of the hose line and can therefore lead to leaks. The movement of the heat exchangers also means that the hose lines have to have an excess length. This additional installation space reduces the overall installation space in the region of the cooling system. Sharp edges also have to be avoided in the region of movable hose lines in order to prevent damage to the surface of the hoses during movement. It is precisely in utility vehicles with fewer units that predominantly sharp-edged but inexpensive sheet metal parts are used, these edges thus require edge protection elements.
The object underlying the present invention accordingly lies in constructing the heat exchangers inside the utility vehicle in such a way that they can move and the supply and removal of the coolant is implemented compactly and inexpensively.
This object is achieved according to the invention by a connecting element for a fluid containing pivotable component, comprising an inlet element and an outlet element, wherein the connecting element surrounds the inlet element and is arranged so as to pivot about the inlet element, the connecting element comprises an inlet line and an outlet line, wherein the inlet line can be fluidically connected or is connected to a container or a continuative line via the inlet element, the outlet line is connected to a first cavity provided between a circumferential surface of the external diameter of the inlet element and a circumferential surface of the internal diameter of the connecting element, wherein the first cavity can be fluidically connected to the outlet element.
Advantageous embodiments of the invention are also identified in the sub-claims.
The advantages achieved with the invention lie in particular in the fact that the connecting element, which comprises an inlet line and an outlet line, is rotatable about an inlet element of the heat exchanger thus allowing rotation of the heat exchanger without an additional adjustment of the inlet line and outlet line. The heat exchanger can thereby be simply rotated during cleaning, repair and/or maintenance without the described drawbacks of flexible hose lines having to be accepted and having to keep installation space for excess lengths available. Consequently cleaning, repair and/or maintenance of the heat exchangers are possible under operationally reliable and cost-optimized circumstances.
A further advantage lies in the fact that the connecting element is coupled to both the inlet line and the outlet line, via which the fluid can flow into and out of the heat exchangers. This arrangement of the inlet line and outlet line in one component makes it possible to quickly and easily fit or disassemble the heat exchanger.
Details of the invention will be described in more detail with reference to the drawings, in which:
The support 2 is rotatably coupled at one its ends to the connecting element 1 by at least one coupling element 51, 51′. At its end remote from the connecting element 1 the support 2 is also rotatably arranged in a bearing 21 that adjoins the heat exchanger 3. One side of the heat exchanger 3 also comprises an outlet element 31 which is connected to the connecting element 1 by a line 32.
Since the support 2 is permanently fitted in the utility vehicle and the heat exchanger 3 is rotatably mounted on the connecting element 1 and the bearing 21, the heat exchanger 3 can be rotated about the support 2 with the outlet element 31 and the line 32.
The heat exchanger 3 comprises a housing 34 on which the outlet element 31 and an inlet element 35 are arranged. The inlet element 35 can be formed in this case for example by a connecting branch that projects from the housing 34. Arranged inside the housing 34 is a first reservoir 33 which is in fluid communication with the inlet element 35. A cooling mesh 37 is also arranged in the housing 34. Heat exchange of a fluid with air or a different fluid takes place across the cooling mesh 37. An additional second reservoir 36 arranged in the housing 34 is connected to the outlet element 31 and the cooling mesh 37.
The fluid can thus flow via the inlet element 35 into the first reservoir 33. Heat exchange of the fluid with air or a different fluid takes place across the cooling mesh 37 that is connected downstream of the first reservoir 33 before the fluid collects in the second reservoir 36. The fluid can leave the second reservoir 36 via the outlet element 31 and a line 32 connected downstream of the outlet element 31.
The inlet element 35 is surrounded by a connecting member 4 and the connecting element 1. The connecting element 1 is rotatably arranged on the inlet element 35 and the connecting member 4 is non-rotatably arranged on the inlet element 35. The connecting member 4 is also connected to the line 32. When the heat exchanger 3 is rotated about the support 2 the connecting member 4 co-rotates with the heat exchanger 3, while the connecting element 1, owing to its coupling to the support 2, remains in the original position.
In the present embodiment the connecting element 1 comprises two annular pieces 11, 12 which are rotatably arranged on the inlet element 35. The first annular piece 11 is securely connected to the second annular piece 12 at one end respectively. For example the two annular pieces can be welded to each other. It is also possible for the connecting element 1 to be constructed in one piece or to comprise more than two annular pieces. At its end remote from the first annular piece 11 the second annular piece 12 is connected to the connecting member 4. The banjo bolt 18, which is connected to the first annular piece 11 and the inlet element 35, prevents axial movement of the first annular piece 11 and second annular piece 12. The end of the first annular piece 11 that is remote from the banjo bolt 18 is closed for example by a screw plug 180.
An inlet line 13 is also arranged on the first annular piece 11 and ends into a recess 17 located inside the first annular piece 11. A fluid is supplied via this inlet line 13 to the connecting element 1. This recess 17 is connected to the reservoir 33 via a passage 38 located in the inlet element 35. An outlet line 14, via which the fluid can flow out of the connecting element 1, is also arranged on the second annular piece 12.
In the present embodiment the first annular piece 11 is formed in one piece with the inlet line 13 and the second annular piece 12 is formed in one piece with the outlet line 14 respectively. However there is also the possibility for example that the connecting element 1 includes a respective threaded connection for an appropriately formed inlet line and outlet line.
The outlet line 14 is connected to a first cavity 19. The cavity 19 is formed between a circumferential surface of the external diameter of the inlet element 35 and a circumferential surface of the internal diameter of the second annular piece 12. The internal diameter of the second annular piece 12 can be variably configured by an appropriately shaped recess in the second annular piece 12 and an associated reduction in the material of the second annular piece 12, and the volume of the cavity 19 may thus be changed. The first cavity 19 is in fluid communication to a second cavity 19′, arranged inside the connecting member 4, by a connecting passage 15.
The second cavity 19′ is formed between the circumferential surface of the external diameter of the inlet element 35 and a circumferential surface of the internal diameter of the connecting element 4. The internal diameter, and therewith the volume of the cavity 19′, can be influenced by an appropriately shaped recess in the connecting member 4 or by an associated reduction in the material of the connecting member 4. The cavity 19′ is also in fluid communication with the line 32.
The fluid issuing from the outlet element (not visible in
To prevent escape of fluid from the respective cavities inside the connecting element 1 and inside the connecting member 4, sealing rings 16 are arranged in the transition region between the two annular pieces 11, 12 and in the transition region between the second annular piece 12 and the connecting member 4 for respective sealing of the transition region.
At least one coupling element 51, 51′ is also arranged on one face of the connecting element 1. In this embodiment a first coupling element 51′ is associated with the first annular piece 11 and a second coupling element 51 with the second annular piece 12. At the end that opposes the connecting element 1 the respective coupling element 51, 51′ is coupled to a fastening element 5. The fastening element 5 can be constructed as a screw-on metal sheet for example and is connected to the support 2.
The first and second annular pieces 11, 12 are axially fixed by screwing of the fastening element 5 coupled to the connecting element 1 to the support 2. Separate sealing of the first annular piece 11 on the end of the first annular piece 11 that is remote from the second annular piece 12 is no longer necessary therefore.
Number | Date | Country | Kind |
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102007049932.0 | Oct 2007 | DE | national |