EP0526687A1 - Oil cooler - Google Patents

Abstract

In an oil cooler (10), which can be used in particular for automatic gearboxes, its nest of tubes (11) is connected at each end to a collecting chamber (12, 13). The oil to be cooled can be led through the tubes (4) and the nest of tubes (11) can be made to exchange heat with a heat exchange medium, for example air, in order to cool the oil. The two collecting chambers (12, 13) are connected to one another, at least on one side of the nest of tubes (11), by way of a bypass line (23) running along this side, the passage of which can be controlled whilst bypassing the nest of tubes (11). The respective bypass line (23) is designed as the side part (33) closing off the nest of tubes (11) on the one side running between the two collecting chambers (12, 13) and is kept in thermally conductive connection with the adjacent tube (14) of the nest of tubes (11), thermally conductive intermediate members (37) being arranged between the bypass line (23) and the adjacent tube (14). <IMAGE>

Description

The invention relates to an oil cooler of the type defined in the preamble of claim 1.

Oil coolers of this type are particularly suitable for gearboxes, engines, internal combustion engines and e.g. can be used with advantage for automatic transmissions. As is known, many oils tend to become viscous at low ambient temperatures. It also happens that in the oil cooler circuit and especially at those places where the flow cross-sections are small, oil plugs form on cooling, which close the passage at this point. Due to these circumstances, cold oil that is introduced into the oil cooler cannot flow through it or only under high pressure, so that the oil circulation and the cooling are sometimes considerably disturbed in this phase, which could cause damage.

To deal with these problems, an oil cooler of the type mentioned above has already been proposed. This has on one long side a separate feed line which causes the oil to flow into a collecting chamber, which runs at a considerable distance from the long side of the pipe network and into which a collecting chamber opens. Furthermore, the oil cooler is provided on the opposite long side of the pipe network with an Öberbrükkungsungsleitung, which also runs at a substantial transverse distance from the pipe network and forms a short-circuit line from one collecting chamber to the other collecting chamber, through which the oil can be guided up to the outlet connected to it . The passage through the last-mentioned bypass line bypassing the tube bundle is by means of e.g. pressure-dependent valve controllable. Is used at a low ambient temperature and e.g. cold oil cooler via the oil supply line, which has a low temperature, to a collection chamber, the valve mentioned can open due to the increased pressure in the oil cooler and open the passage through the bypass line between the one collection chamber and the other collection chamber, so that the oil bypassing the tube bundle from one collecting chamber through the bypass line to the other collecting chamber and back to the outlet. This ensures oil circulation. Only when the tube bundle and the viscous oil contained therein has gradually warmed up after some time, whereby any oil plugs contained have been liquefied and dissolved, does the pressure in the system drop, so that the valve in the bypass line closes automatically and the oil now from one collecting chamber through the tube bundle to the other collecting chamber and back to the outlet. The oil cooler can now develop its cooling effect.

It has been shown that in this known oil cooler considerable time passes before the oil cooler can switch from bypass operation to normal cooling operation and develop its cooling effect. During this time, the gradually warming oil is insufficiently cooled, and the oil is heated too much, which can impair its physical properties, e.g. lubricity. Also in the part to be cooled, e.g. Set the engine, transmission, especially the automatic transmission, to a dangerous build-up of heat that could result in damage.

The invention has for its object to provide an oil cooler of the type mentioned in the preamble of claim 1, which can quickly develop its full cooling function.

In an oil cooler of the type defined in the preamble of claim 1, the object is achieved according to the invention by the features in the characterizing part of claim 1. Because the at least one bridging line is held in heat-conducting connection with the tube of the tube bundle adjacent thereto, a faster heating of the tube bundle and thus a quicker reaching of the continuous operating state is possible, so that the oil cooler already reaches operating temperature faster at low ambient temperatures and can develop its full cooling function more quickly, so that an excessive initial heating of the oil due to the late use of the cooling effect of the oil cooler is prevented and the physical properties, e.g. the lubricity, of the oil remain unaffected for a long time Dangerous heat build-up and possible damage to the part to be cooled, e.g. engine, transmission, especially automatic transmission, are avoided. It is also advantageous that the area of the at least one bridging line, which is held in heat-conducting connection with the adjacent tube of the tube bundle, also contributes to the heat exchange when the oil cooler is operating in normal cooling mode, as a result of which the cooling capacity is increased. Overall, the at least one bypass line, which is held in heat-conducting connection with the adjacent tube of the tube bundle, contributes to increasing the heat transfer, on the one hand in the cold state and before reaching the cooling function, and on the other hand in the warm state and in the cooling function of the oil cooler. Characterized in that the at least one bridging line is also formed as a side part that closes the tube bundle on one side, which runs between the two collecting chambers and is usually a longitudinal side, is in the In this area, an otherwise provided separate side part can be dispensed with, the bridging line thus fulfilling the double function of being a part of the pipe that participates in the circulation of the oil in the oil cooler and a mechanical closure on the relevant side of the bundle of pipes that not only protects the rest , but also gives the oil cooler greater strength in this area. It goes without saying that, for example in accordance with the features of claim 7, heat-conducting intermediate elements, preferably made of heat-conducting metal, for example aluminum, can be arranged between the at least one bridging line and the tube of the tube bundle adjacent thereto, these, for example, made of conductive fins, for example air fins, can be formed, which are in each case in preferably large-area, heat-conducting contact with the bypass line and the tube adjacent thereto and can be acted upon by the heat exchange medium. These fins can be the same meandering or zigzag-shaped fins, which are arranged in the tube bundle between the individual tubes to increase the heat transfer performance and are in heat-conducting contact with the individual tubes of the tube bundle. Such fins increase the heat conduction from the bridging line to the adjacent tube of the tube bundle, as a result of which the heat transfer performance, namely the heating output or cooling output, is further increased overall in this edge region. Since these fins can be the same as in the tube bundle, these fins do not mean much additional effort. They also have the advantage that they support at least one bypass line during soldering in the manufacture of the oil cooler, for example when soldering as a pre-assembled and assembled package. Likewise, the at least one bridging line in the form of the side part via the intermediate members, in particular lamellae, supports the tube bundle during soldering. The oil cooler can therefore also be produced inexpensively in this design. It is a stable component that can be designed completely ready for connection. Further features of the invention and advantageous embodiments of this oil cooler result from claims 2 to 6 and 8 to 23.

Further details and advantages of the invention result from the following description.

The full wording of the claims is not reproduced above solely to avoid unnecessary repetition, but instead is referred to only by mentioning the claim numbers, whereby, however, all of these claim features are to be regarded as being explicitly disclosed at this point and essential to the invention. All of the features mentioned in the above and the following description, as well as the features that can only be inferred from the drawing, are further components of the invention, even if they are not particularly emphasized and are not mentioned in the claims.

In a known oil cooler (DE-OS 37 14 230), at least one valve-controlled bypass line of increased cross section is arranged approximately in the middle of the tube bundle within the oil cooler and is connected to both collecting chambers. Such a bridging line provided in the middle of the tube bundle is disadvantageous. On the one hand, this makes the manufacture of the entire pipe network considerably more difficult. Another disadvantage is that when the valve is closed in the bypass line and thus the bypass line, which is then no longer flowed through by the oil, this area of the tube bundle hardly or not at all takes part in the heat transfer, in particular cooling. Thus, in normal cooling operation of the oil cooler with the bypass line closed, the central region of the tube bundle of the oil cooler, which is important for cooling, is not involved in the cooling. That is why the oil cooler has a reduced cooling capacity. The same also applies to an oil cooler according to DE-OS 38 06 888.

• Fig. 1 eine schematische, teilweise geschnittene Seitenansicht eines Ölkühlers gemäß einem ersten Ausführungsbeispiel,
• Fig. 2 einen vergrößerten Schnitt entlang der Linie 11 - 11 in Fig. 1,
• Fig. 3 einen vergrößerten Schnitt entlang der Linie 111 - 111 in Fig. 1,
• Fig. 4 einen schematischen Schnitt etwa entsprechend demjenigen in Fig. 3 eines zweiten Ausführungsbeispieles,
• Fig. 5 einen schematischen Schnitt etwa entsprechend demjenigen in Fig. 2 eines dritten Ausführungsbeispieles,
• Fig. 6 einen schematischen Schnitt eines Ausschnitts VI gemäß Fig. 1, jedoch eines vierten Ausführungsbeispieles,
• Fig. 7 eine schematische, teilweise geschnittene Seitenansicht etwa entsprechend derjenigen in Fig. 1 eines Ölkühlers gemäß einem fünften Ausführungsbeispiel.

The invention is explained in more detail below with reference to exemplary embodiments shown in the drawings. Show it:

• 1 is a schematic, partially sectioned side view of an oil cooler according to a first embodiment,
• 2 shows an enlarged section along the line 11-11 in FIG. 1,
• 3 shows an enlarged section along the line 111-111 in FIG. 1,
• 4 shows a schematic section approximately corresponding to that in FIG. 3 of a second exemplary embodiment,
• 5 shows a schematic section approximately corresponding to that in FIG. 2 of a third exemplary embodiment,
• 6 shows a schematic section of a section VI according to FIG. 1, but of a fourth exemplary embodiment,
• Fig. 7 is a schematic, partially sectioned side view approximately corresponding to that in Fig. 1 of an oil cooler according to a fifth embodiment.

1 to 3, an oil cooler 10 is shown according to a first embodiment, which is basically suitable for a wide variety of uses net, in particular, for example, for engines, internal combustion engines, gearboxes or the like. The oil cooler 10 can, for example, be used advantageously for cooling the oil of an automatic transmission, for example a motor vehicle.

The oil cooler 10 has at least one tube bundle 11 which is connected at one end to a first collecting chamber 12 and at the other end to a second collecting chamber 13, namely in that the individual tubes 14 of the tube bundle 11 into the collecting chambers 12 and 13 lead in there and are firmly and tightly connected to them, the tubes 14 opening into the interior of the collecting chambers 12, 13. The oil to be cooled can be passed through the pipes 14. To cool the oil that is passed through, the tube bundle 11 can be brought into heat exchange with a heat exchange medium, not shown here, which e.g. consists of air, which in the arrangement according to Fig. 1 e.g. passed approximately perpendicular to the plane of the drawing through the spaces in the tube bundle 11, e.g. is blown through.

The design of the tubes 14 of the tube bundle 11 is in principle arbitrary, although the tubes 14 of the tube bundle 11 are designed as flat tubes 15 with particular advantage in the first exemplary embodiment. These flat tubes, which are not shown further, can also contain turbulence inserts or similar elements in the interior in the usual way. The two collecting chambers 12 and 13 are designed, for example, as flat boxes 16 and 17, respectively, which each consist of shell-shaped parts 18 and 19, e.g. Halves are assembled, as Fig. 3 shows. It can be seen from this that the tubes 14, in particular flat tubes 15, are guided through an adapted opening 20 in a bowl-shaped part 18 into the interior of the flat box 16 and are fastened in this opening 20 with sealing.

In the second exemplary embodiment shown in FIG. 4, the collecting chambers are not designed as flat boxes, but instead as cylinders 66, which in a particularly simple design are each formed from tubes 68, which are used for passing the respective tube 14, in particular flat tube 15, accordingly Opening 70 included.

The tube bundle 11 has between the individual tubes 14 running, thus in heat-conducting contact, conductive fins 21, e.g. Air fins, which are arranged in the space between two adjacent tubes 14, in particular flat tubes 15, and run approximately in a zigzag shape, the fins 21 being in contact with both adjacent tubes 14, in particular flat tubes 15, and thus also being able to be firmly connected, e.g. can be soldered. Such slats 21 and their arrangement are known in principle.

The two collecting chambers 12 and 13 are connected to one another at least on one side of the tube bundle 11, that is to say on the lower and / or upper side in FIG. 1, which extends between the collecting chambers 12 and 13, via a bridging line running along this side, wherein In the first exemplary embodiment in FIG. 1, two such bypass lines 22 and 23 are provided, of which the bypass line 22 serves as an inlet line in FIG. The passage through the bypass lines 22 and 23 and the collecting chambers 12 and 13 connected thereto, bypassing the tube bundle 11, can be controlled by at least one valve 24, which is only indicated schematically in FIG. 1 and is designed as a pressure-dependent valve, which opens automatically at high pressure and closes at low pressure. The pressure-controlled valve 24 consists in a simple manner of a valve member 25 which is loaded by a spring 26 and can be pressed by the latter against the end of the bridging line 23 located at the top left in FIG. 1, which opens into the collecting chamber 13. In this embodiment of the oil cooler 10 according to the first exemplary embodiment, the valve 24 is in the return flow of the oil which is led back from the bypass line 23 back into the collecting chamber 13. It goes without saying that the valve 24 can just as well be arranged in the region of the connection of the bypass line 23 to the collecting chamber 12.

The valve 24, which is controlled in a pressure-dependent manner in the first exemplary embodiment, can additionally or instead also be temperature-controlled. In the fourth exemplary embodiment in FIG. 6, a temperature-controlled valve 74 is shown schematically in the same region VI of the oil cooler 10 as is shown in FIG. 1. Such temperature dependent valves 74 are known per se, e.g. as a thermostatic valve, and therefore require no further explanation.

The respective bridging line 22 and 23 is designed as the tube bundle 11 on the side part 32 and 33 which terminates between the two collecting chambers 12 and 13 and is in heat-conducting connection with the adjacent tube 14, that is to say the bottom and top tube in FIG. 1 , the tube bundle 11 held. In this embodiment, as a respective side part 32, 33, this thus closes the tube bundle 11 on the associated side. The respective bridging line 22, 23 is, as shown in particular in FIG. 2 with regard to the bridging line 22 in the form of a side part 32, in the form of a tube 42 or 43 which, for example, consists of the same material as the tubes 14 of the tube bundle 11, in particular from a Material with high thermal conductivity, e.g. made of aluminum. In the first exemplary embodiment in FIGS. 1 to 3, the respective tube 42 or 43 is designed as a square tube which is visible in FIG. 2. In the third exemplary embodiment shown in FIG. 5, the tube 92 instead consists of a round tube. It can be advantageous if the respective bypass line 22, 23 is formed from an extruded profile part. One such is the tube 42, which is shown in cross section in FIG. 2, this extruded profile part, for example, also having the profile-supporting, thus one-piece intermediate webs 44, which at the same time can increase the heat transfer performance of the tube 42. It goes without saying that bridging lines 22, 23, which are designed as side parts 32 and 33, in particular as tubes 42 and 43, can also be provided with differently shaped tubes. The bypass line 22, 23 has a passage cross section that is larger, preferably substantially larger, than the passage cross section of the entire tube bundle 11 or at least one tube bundle part. In this way, the bypass lines 22 and 23 designed as side parts 32 and 33 perform their function as bypass lines when the supplied oil is at a low temperature and / or in the system, for example in the tube bundle 11, when oil plugs are present in the cold state fair. The bridging lines 22, 23 not only serve as elements which conduct the oil through them and the collecting chambers 12 and 13, bypassing the tube bundle 11, but at the same time form the supporting and securing side parts 32, 33 covering the tube bundle 11 on both sides.

It is particularly advantageous that between the respective bridging line 22, 23 on the one hand and the tube 14 adjacent thereto, in particular flat tube 15, of the tube bundle 11 on the other hand, i.e. the lowest and uppermost tube 14 in FIG. 1, heat-conducting intermediate members 34 and 35 are arranged, which are preferably made of heat-conducting metal, e.g. made of aluminum. The intermediate members 34, 35 are advantageously formed from conductive fins 36 and 37, e.g. from air fins, these fins 36, 37 on the one hand directly with the adjacent tube 14, in particular flat tube 15, and on the other hand directly with the bypass line 22 or 23 in preferably large-area heat-conducting contact and from the heat exchange medium, e.g. of air, that the tube bundle 11 e.g. penetrated approximately at right angles to the drawing plane of FIG. 1. These fins 36, 37 can be the same fins 21 that are present in the tube bundle 11 between the individual tubes 14, in particular flat tubes 15. These slats 21 and 36 and 37 run approximately meandering, zigzag or in some other way, as is known in principle. The lamellae 36, 37 each abut a flat-plane contact surface 38 or 39 of the associated bridging line 22 or 23, in particular of the side part 32 or 33, as in particular also in FIG. 2 for the bridging line 22 shown there in FIG Design as a side part 32 is shown. The fins 36 and 37 arranged between the respective bridging line 22, 23 on the one hand and the facing pipe 14 of the tube bundle 11 on the other hand have the advantage of good heat conduction from the respective bridging line 22, 23 to the adjacent tube 14 of the tube bundle 11. If cold oil is first passed through, in particular through the bridging line 22, the collecting chamber 12, the bridging line 23 and the collecting chamber 13, bypassing the tube bundle 11, the thermal energy of the oil which gradually warms through is transferred to the tube bundle 11 on all four sides of the oil cooler 10, thus the fins 36 and 37 perform a heat-conducting task in the area of the bypass lines 22 and 23, respectively. Later and then, when the oil passed through the oil cooler 10 is at operating temperature and flows through the bypass line 22, the collecting chamber 12, the tube bundle 11 and the collecting chamber 13, and the oil is to be cooled by the oil cooler, the bypass lines 22 and 23 and the fins 36, 37, which are in heat-conducting contact with the latter and the adjacent tubes 14 of the tube bundle 11, participate in the heat dissipation and thus in the cooling, so that this results in an increased cooling capacity. Moreover, the fins 36 and 37 have the advantage in the production of the oil cooler that the fins 36 and 37 support the bypass lines 22 and 23 formed as side parts 32, 33 when soldering the entire oil cooler.

Each bypass line 22 and 23 opens at one end, for example the right end in FIG. 1, into the first collecting chamber 12 there and with its opposite end into the other collecting chamber 13. In the area of the collecting chamber 13, the oil inlet 27 and, separated from it by an inner partition 28 in the collecting chamber 13, the oil outlet 29 are provided. In the exemplary embodiment shown, the oil inlet 27 opens into the collecting chamber 13, but this is not mandatory. The bypass line 22 is thus in communication with the oil inlet 27, here within the collecting chamber 13, and with the other collecting chamber 12. The second bridging line 23 on the opposite side, for example the long side, of the tube bundle 11 is connected to both collecting chambers 12 and 13 and serves the return of the oil in the bypass operation shown in FIG. 1 from the collecting chamber 12 to the collecting chamber 13 and through this back to the oil outlet 29.

In another embodiment, not shown, the oil inlet 27 and the oil outlet 29 are interchanged such that the oil in the bypass operation is initially from the oil inlet, which is located at the location of the oil outlet 29, through the collecting chamber 13 and from this via the bypass line 23 to the other Collection chamber 12 and from the latter via the bridging line 22 is led back to the oil outlet, which is located at the location of the oil inlet 27 and, like the oil inlet 27, can be provided either outside of the collection chamber 13 or instead also within it, which then forms a flow connection between the oil inlet 27 and the subsequent bypass line 22.

The oil cooler 10 according to the first embodiment is single-flow, so that when the oil is at operating temperature and is to be cooled and instead of the bypass line 23 flows through the tube bundle 11 in the return, the entire tube bundle 11 is filled with oil from the collecting chamber 12 in the direction of the other Flow chamber 13 is flowed out. All flat tubes 15 of the tube bundle 11 are thus flowed through by the oil in one direction.

1 shows a state of the oil cooler 10 in which the oil supplied and introduced via the oil inlet 27 is still at a low temperature. The oil remaining in the tube bundle 11 is cold. In addition, it may be that oil plugs may have formed in the tubes 14 of the tube bundle 11, which block the passage. In order to protect the oil cooler 10 and to transfer the thermal energy of the supplied oil to the tube bundle 11 as large as possible and to heat it quickly and to dissolve any oil plugs, so that oil can flow through the tube bundle 11 as early as possible and the oil cooler 10 perform its cooling function as quickly as possible With the valve 24 open, the oil introduced at the oil inlet 27 is thus returned to the oil chamber through the bridging line 22 which causes the flow, through the collecting chamber 12 and not yet through the tube bundle 11, but rather because of the opened valve 24 through the bridging line 23 acting as a return line 13 and from there to the oil outlet 29. Due to the low flow resistance in the bypass line 23, it is ensured that the oil is not yet pressed through the flat tubes 15 of the tube bundle 11. The high pressure generated in the system automatically causes the pressure-controlled valve 24 to open and to keep it open as long as this increased pressure is present in the system. The oil passed in the manner described gives its thermal energy on all four sides of the oil cooler 10 to the cooling network, formed by the tube bundle 11 with the tubes 14, the side parts 32, 33 and the fins 21 and 36 and 37, so that the heat is transferred to the oil in the tubes 15 and any oil plugs contained therein are dissolved as quickly as possible and oil still to be viscous in the tube bundle 11, because it is too cold, is liquefied, so that the oil through the tubes 14, in particular Flat tubes 15 of the tube bundle 11 can flow through instead of through the bypass line 23. This results in a pressure drop in the system, due to which the spring 26 moves the valve member 25 from the open position according to FIG. 1 to the closed position. When the valve 24 is closed, the connection between the bypass line 23 and the collection chamber 13 is thus interrupted. The oil, which is passed through the inlet 27 and through the bypass line 22 to the collecting chamber 12, now flows through the tubes 14, in particular flat tubes, of the tube bundle 11 in FIG. 1 from right to left to the other collecting chamber 13, from which the oil passes the outlet 29 is discharged.

Because of the design described, the continuity of the tubes 14, in particular flat tubes 15, for the oil which is initially still at a low temperature is achieved with oil condenser 10 according to the invention, with very rapid liquefaction of the oil contained and dissolution of any oil plugs contained which block the flow. The oil cooler 10 is thus very quickly able to achieve the full and desired large cooling capacity, which is achieved very quickly, so that e.g. An initial excessive heating of the oil - due to the late use of the cooling effect of the oil cooler - is prevented and the physical properties of the oil remain unaffected for a long time. In operation, the oil cooler has an increased cooling capacity, since the bridging lines 22 and 23 designed as side parts 32, 33 together with the fins 36 and 37 are additional components of the cooling network and participate in the heat exchange and thus in the cooling. It is also advantageous that the bridging lines 22, 23 each have a double function due to their design as side parts 32 and 33, which laterally cover the tube bundle 11 and protect it. The oil cooler 10 is simple to manufacture, a compact component that can be completely built in and is highly effective both as a heat-transferring element when the oil is cold and as a cooler, each with a high heat transfer capacity.

In the third exemplary embodiment shown in FIG. 5, the bypass line 22 is designed as a side part 32 from a tube 92, in particular a round tube. Since such an adjacent intermediate member 34, in particular fins, which serves for heat conduction offers only a small contact area, in this third exemplary embodiment the intermediate members 34, in particular fins 36, are arranged indirectly with a contact part 93, which increases the heat conducting area of the tube 92, with the Bridging line 22 brought into heat-conducting connection. The contact part 93 is e.g. from a U-profile part, which overlaps the bridging line 22, which is designed as a round tube, at three points, i.e. with both U-legs and with the U-web running between them. The contact part 93 has a flat, flat contact surface 94 on which the intermediate member 34, in particular the lamella 36, bears, so that a large contact surface is created for the best possible heat transfer.

In the fifth exemplary embodiment shown in FIG. 7, the oil cooler 110 is designed with two passages. This means that a tube bundle 111 causes the oil supplied via the oil inlet 127 to flow from the left collecting chamber 113 in FIG. 7 to the right collecting chamber 112 (reversing chamber) and that the second tube bundle 111 located above it causes the oil to return from the collecting chamber 112 to the collecting chamber 113 and from there to the oil outlet 129. In the collection chamber 113 between the inlet 127 and the outlet 129 there is a partition 128 for separation, e.g. the collection chamber 113 separates into approximately two sub-chambers of the same size.

As in the first exemplary embodiment, the two collecting chambers 112 and 113 are connected to one another via bridging lines 122 and 123, which are designed in the same way as in the previous exemplary embodiments and also here as side parts 132 and / or end pieces which terminate on the relevant side in each case as the respective tube bundle 111a and 111 133 are trained. A valve 124 is arranged between the bypass line 123 and the collection chamber 113 in accordance with the arrangement in the first exemplary embodiment. Furthermore, a corresponding valve 154 is also arranged in the flow between the bypass line 122 and the collecting chamber 112.

In this double-flow design, the one collection chamber 113 is thus divided into two sections, namely a collection chamber section which is connected to the oil inlet 127 and a bypass line 122 for the flow, and a section which is connected to the oil outlet 129 and to the second bypass line 123 is connected for the return.

If cold oil is initially passed through the oil inlet 127 into the lower part of the collecting chamber 113 in FIG. 7 and from there through the bridging line 122, the oil not yet being able to pass through the tube bundle 111a due to viscosity and / or any oil plug, this opens Valve 154 automatically due to the increased pressure, releasing the connection to the collecting chamber 112. Even if no flow is still possible in the tube bundle 111 due to excessive viscosity and / or any oil plug, the increased pressure in the collecting chamber 112 and in the bypass line 123 leads to automatic Opening of the valve 124 there so that the oil can pass from the collection chamber 112 through the bypass line 123 and from there to the upper section of the other collection chamber 113 and from there to the oil outlet 129. In this exemplary embodiment, too, the pipe network of the oil cooler 110 flows around on all four sides at this stage, it being in heat-conducting contact with these outer sides, so that the thermal energy of the oil is transferred very quickly to the pipe bundle 111a or 111b and the oil it warms up and becomes fluid and any oil plugs liquefy and dissolve,

so that valves 154 and / or 124 close. Then the oil passed through the oil inlet 127 and to the lower section of the collecting chamber 113 does not pass the bypass line 122, but in Fig. 7 from left to right the tube bundle 111 a. From there, the oil reaches the other collecting chamber 112 and from there it flows from right to left the tube bundle 111 to the upper section of the collecting chamber 113, from which the oil flows out via the oil outlet 129.

Claims (23)

1. Oil cooler, in particular for gearboxes, engines, internal combustion engines or the like, with at least one tube bundle (11, 111 a, 111 b) connected at each end to a collecting chamber (12, 13; 112, 113), through the tubes ( 14) the oil to be cooled can be passed through and which can be brought into heat exchange with a heat exchange medium for cooling the oil, the two collecting chambers (12, 13, 112, 113) at least on one side of the tube bundle (11; 111 a, 111 b) are connected to one another via a bridging line (22 or 23, 122, 123) running along this side, the passage of which can be controlled by bypassing the tube bundle (11; 111 a, 111 b),
characterized,
that the bridging line (22 or 23; 122, 123) is designed as the tube bundle (11; 111 a, 111 b) on the side part (32, 33; 132, 133) which runs between the two collecting chambers (12, 13; 112, 113) and is in heat-conducting connection with the adjacent tube (14; 114) of the tube bundle (11; 111 a, 111 b) is held. 2. Oil cooler according to claim 1,
characterized,
that the at least one bypass line (22 or 23; 122, 123) is designed as a tube (42, 43; 92). 3. Oil cooler according to claim 2,
characterized,
that the tube (42, 43; 92) consists of the same material as the tubes (14; 114) of the tube bundle (11; 111 a, 111 b), for example made of aluminum. 4. Oil cooler according to one of claims 1 to 3,
characterized,
that the at least one bypass line (22 or 23; 122, 123) is formed from a round tube (92) or square tube (42, 43). 5. Oil cooler according to one of claims 1 to 4,
characterized,
that the at least one bypass line (22 or 23; 122, 123) has a preferably substantially larger passage cross section than the entire tube bundle (11; 111 a, 111 b) or at least one tube bundle part. 6. Oil cooler according to one of claims 1 to 5,
characterized,
that the at least one bypass line (22 or 23; 122, 123) is formed from an extruded section. 7. Oil cooler according to one of claims 1 to 6,
characterized,
that between the bridging line (22 or 23; 122, 123) and the adjacent tube (14; 114) of the tube bundle (11; 11 a, 111 b) thermally conductive intermediate members (34, 35; 134, 135), preferably made of thermally conductive Metal, such as aluminum, are arranged. 8. Oil cooler according to claim 7,
characterized,
that the intermediate members (34, 35; 134, 135) are formed from conductive fins (36, 37), for example air fins, which on the one hand directly with the adjacent tube (14; 114) and on the other hand directly or indirectly with the bridge
Kungsleitung (22 and 23; 122, 123), preferably large-area, heat-conductive contact and can be acted upon by the heat exchange medium. 9. Oil cooler according to claim 8,
characterized,
that between the intermediate links (34, 35;
134, 135), in particular fins (36, 37), and the bridging line (22 or 23, 122, 123) a contact part (93) enlarging the heat conducting surface is arranged, for example a U-shaped part, which has a bridging line designed as a round tube (92) (22) engages with contact. 10. Oil cooler according to one of claims 7 to 9, characterized in
that the intermediate links (34, 35; 134, 135), in particular the lamellae (36, 37), on a flat plane contact surface (38, 39; 94) of the bridging line (22 or 23, 122, 123) or the contact part (93 ) issue. 11. Oil cooler according to one of claims 1 to 10,
characterized,
that the tube bundle (11; 111 a, 111 b) has conductive fins (21; 121), for example air fins, running between the individual tubes (14; 114) and thus in heat-conductive contact, and that the between the bridging line (22 or 23, 122, 123) and the adjoining tube (14; 114) arranged intermediate members (34, 35; 134, 135) are designed as the same fins (36, 37). 12. Oil cooler according to one of claims 1 to 11,
characterized,
that on both opposite sides of the tube bundle (11; 111 a and 111 b) between the two collecting chambers (12, 13; 112, 113) bridging lines (22 and 23; 122, 123) of the same type as the tube bundle (11; 111 a and 111b) ) laterally closing side parts (32, 33) are arranged, which are each held in heat-conducting connection with the adjacent tube (14; 114) of the tube bundle (11; 111 a and 111 b). 13. Oil cooler according to one of claims 1 to 12, characterized in
that each bridging line (22 or 23; 122, 123) opens at one end into a collecting chamber (12; 112) and at the other end into the other collecting chamber (13; 113). 14. Oil cooler according to one of claims 1 to 13,
characterized,
that a bypass line (22; 122) communicates with the oil inlet (27; 127), for example within one collection chamber (13; 113), and with the other collection chamber (12; 112). 15. Oil cooler according to one of claims 1 to 14,
characterized,
that the second bypass line (23; 123) on the opposite side of the tube bundle (11; 11 and 111 b) with both collection chambers (12, 13; 112, 113) for returning the oil from one collection chamber (12; 112) back to other collection chamber (13; 113) is connected. 16. Oil cooler according to claim 14 or 15,
characterized,
that the oil inlet (27) and the oil outlet (29) are interchanged such that the oil first through a collecting chamber (13), from this via a bridging line (23) to the other collecting chamber (12) and from this (12) via a bridging line (22) can be conducted back to the oil outlet (27) which is arranged inside or outside of the one collecting chamber (13). 17. Oil cooler according to one of claims 1 to 16,
characterized,
that with double flow formation and corresponding subdivision of the tube bundle (111 a, 111 b), the one collection chamber (113) into a section which is connected to the oil inlet (127) and a bypass line (122) for the flow, and into a section is divided, which is connected to the oil outlet (129) and to a second bypass line (123) for the return. 18. Oil cooler according to one of claims 1 to 17,
characterized,
that the passage can be controlled by passing through the at least one bypass line (22 or 23; 122, 123) by means of at least one valve (24; 74; 124, 154). 19. Oil cooler according to claim 18,
characterized,
that the at least one valve is designed as a pressure-dependent valve (24; 124, 154) opening at high pressure and closing at low pressure and / or as a temperature-dependent controlled valve (74), for example a thermostatic valve. 20. Oil cooler according to one of claims 1 to 19,
characterized,
that the at least one valve (24; 74; 124, 154) is arranged in the flow and / or return. 21. Oil cooler according to one of claims 1 to 20,
characterized,
that the tubes (14; 114) of the tube bundle (11; 111 a, 111 b) are designed as flat tubes (15). 22. Oil cooler according to one of claims 1 to 21,
characterized,
that the collecting chambers (12, 13; 112, 113) are each formed as flat boxes (16, 17) composed of shell-shaped parts (18, 19), for example halves. 23. Oil cooler according to one of claims 1 to 21,
characterized,
that the collecting chambers (12, 13; 112, 113) are constructed as cylinders (66) each formed from tubes (68).

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