This application claims the benefit under 35 USC 119 of foreign application 102009053682.5 filed in Germany on Nov. 19, 2009, and which is hereby incorporated by reference in its entirety.
The invention concerns an oil pan for an internal combustion engine.
JP 2003278519 A discloses that the interior of an oil pan for an internal combustion engine is to be separated by a partition into two separate chambers of approximately the same size that are each fillable with oil. The oil is drained through a drain passage that is provided in one of the two chambers. This separation into two chambers has the advantage that, as a result of the reduced oil volume for each chamber, the oil can be heated in a shorter time to the operating temperature. In the partition between the two chambers several overflow openings are provided wherein each overflow opening can be opened or closed by a correlated temperature-dependent switching valve. When a limit temperature is surpassed, the switching valves are opened so that through the overflow openings a fluid communication between the two chambers is produced and the oil volume of the two chambers can be supplied to the oil circulation.
It is therefore an object of the present invention to embody with simple measures and a compact configuration an oil pan for an internal combustion engine such that the oil temperature can be brought to operating temperature within a time that is as short as possible. Moreover, according to a further aspect, the drainage of the oil pan for servicing purposes should be performable with minimal additional constructive expenditure.
In accordance with the present invention, this is achieved in that at least two overflow openings in the partition are to be opened or closed by a common closure element.
The oil pan according to the invention for an internal combustion engine has in the interior at least two separate oil chambers that are separated by an intermediately positioned partition wherein in the partition at least two overflow openings are provided. For opening and closing the overflow openings, an adjustable closure element is provided wherein, according to the invention, at least two overflow openings are to be opened and closed by a common closure element.
With this embodiment, a significant constructive simplification and a more compact configuration are provided because the number of closure elements is smaller than the number of overflow openings. For example, in an embodiment with two overflow openings in the partition between the two oil chambers in the oil pan, only a single closure element is required with which the two overflow openings, preferably simultaneously, are opened or closed. As an alternative to simultaneous opening and closing, a temporally delayed opening and closing of the two overflow openings is possible also in order to provide, for example, for improved control of the flow exchange between the oil chambers, in particular, as a function of the current oil temperature.
The closure element is in particular a thermal switching valve that, below a switching temperature, is in closed position so that the two volumes in the oil chambers are separated and that is switched upon surpassing the switching temperature from the closed position into an open position so that an exchange between the oil chambers is possible through the overflow openings.
The partition between the oil chambers is expediently designed such that two opposed wall sections are formed each provided with an overflow opening, respectively, wherein the closure element is arranged in the intermediate space between the wall sections. In this way, several design possibilities in regard to the geometry of the oil chambers are provided wherein even for complex geometries only one closure element for at least two overflow openings is required. Positioning of the closure element in the intermediate space between the opposed wall sections of the partition enables closing and opening of both overflow openings with only one closure element. For example, the partition is U-shaped so that the opposed wall sections of the U-shape extend at least approximately parallel and the overflow openings can be opened or closed by means of the intermediately positioned closure element. Possible in principle are also angled arrangements between the wall sections of the partition. In this variant, opening and closing is possible also with only one closure element. Since advantageously each wall sections in the partition has correlated therewith at least one overflow opening, oil chamber geometries with undercuts can be formed without there being the risk that oil collected in partial areas of an oil chamber will no longer participate in the flow exchange or flow transfer into the second chamber. Instead, it is ensured that the oil from all areas of the closed chamber will flow into the second chamber upon opening of the closure element.
As a closure element an oil drain screw may be provided also that is adjustable between a closing position and an open position. According to an advantageous embodiment, it is provided that the oil drain screw is passed additionally through a drain opening in the exterior wall of the oil pan so that, on the one hand, the overflow openings in the partition between the oil chambers can be opened and closed and, on the other hand, for servicing purposes, the drain opening in the exterior wall can also be opened and can be closed again after termination of the servicing work. All openings, i.e., the overflow openings in the partition and the drain opening in the exterior wall, are closed with a common closure element in form of an oil drain screw. The oil drain screw has, axially spaced, several sealing locations that, in the closed position, project into correlated sealing seats in the openings and close them off.
According to a first embodiment variant, the oil drain screw is embodied in a conventional embodiment with sealing locations that are axially fixedly positioned relative to one another. In an advantageous embodiment variant, it is provided that the oil drain screw in addition has a thermal expansion section that has the function of a thermal element and that, based on the oil temperature, expands or contracts so that the axial length of at least one section of the oil drain screw will change as a function of temperature. In this embodiment, the oil drain screw has two functions. On the one hand, the oil drain screw can be removed manually in order to release the drain opening in the exterior wall for draining the oil and, at the same time, to release the overflow openings in the partition so that the entire oil can drain from the oil pan. On the other hand, the oil drain screw in operation remains in its position and closes the externally positioned drain opening, while the wax thermostatic element will axially move the sealing locations on the oil drain screw that close off the overflow openings. In this way, as a function of temperature, opening and closing of the overflow openings in the partition is possible, even when the oil drain screw remains in the inserted position in the drain opening.
Inasmuch as the closure element is embodied as a thermal switching element that does not additionally have the task of an oil drain screw, different embodiment variants may be considered, for example, an embodiment as a rotary slide with a bimetal spring that, as a function of temperature, produces a rotational movement that is used as an adjusting movement for opening and closing the overflow openings. Alternatively, a wax thermostatic element can be employed as thermal switching element.
According to a further aspect of the invention, the oil pan has also a partition for separating the interior into two oil chambers wherein in the partition at least one overflow opening is introduced that is to be closed by an oil drain screw. In this embodiment, the oil drain screw also has the function of opening and closing the drain opening in the exterior wall as well as the overflow opening in the partition. Basically, a single overflow opening in the partition is sufficient that is closed by the oil drain screw. The oil drain screw, as described above, can be provided as is conventional with sealing locations that are axially fixedly positioned for closing the drain opening and the overflow opening, or with a wax thermostatic element that, as a function of temperature, axially moves the sealing location for the overflow opening in order to open or close the overflow opening as a function of the oil temperature.
According to further aspect, in the partition between the oil chambers at least one overflow opening is provided whose cross-sectional surface area and/or cross-sectional geometry is matched to the viscosity of the oil in such a way that only oil with a viscosity below a temperature-dependent viscosity limit can pass the overflow opening. Since the oil at low temperatures has a higher viscosity than at higher temperatures, by means of the design of the cross-sectional shape and the cross-sectional surface area of the overflow opening the flow through the opening can be controlled which has the advantage that a thermal switching valve or other closure element as a separately embodied component for closing the overflow opening is no longer needed. For example, the overflow opening is designed as a slot in order to prevent oil exchange at low temperatures because the slot shape cannot be passed by high-viscosity oil at low temperatures. With increasing temperature, the viscosity of the oil decreases until upon surpassing a switching temperature at which the viscosity limit is reached, the oil can be exchanged through the overflow opening between the oil chambers. Alternatively, the overflow opening can be round, oval or rectangular.
As an alternative to the embodiment with reduced cross-sectional surface area or slot-shaped cross-sectional geometry, it is also possible to arrange within the overflow opening a nonwoven that has a permeability that is matched to the viscosity of the oil in such a way that below a temperature-dependent viscosity limit the oil can pass the nonwoven while highly viscous oil that is above the viscosity limit cannot pass through the nonwoven so that the overflow opening is closed and the oil volumes in the chambers are separated from one another. This embodiment has the advantage that the overflow opening may have a large cross-sectional surface area because the overflow behavior is determined by the nonwoven in the overflow opening. Several overflow openings may be provided that are covered by the nonwoven or by several nonwoven sections.
According to a further aspect of the invention the partition is connected with the inner bottom of the oil pan according to the tongue-and-groove principle. This embodiment has the advantage that additional fixation or fastening measures of the partition in the oil pan are not required. The connection between partition and oil pan is realized only means of the tongue-and-groove principle, in particular in such a way that on the inner bottom of the oil pan a groove is provided into which the end face of the partition is inserted. The groove at the inner bottom of the oil pan is comprised either of the same material as the oil pan or of a softer material, for example, a thermoplastic elastomer that is applied to the inner bottom, for example, by way of injection molding.
The connection of the partition with the inner bottom of the oil pan according to the tongue-and-groove principle can be provided optionally with a desired play or clearance that, with respect to the size or cross-sectional design, is configured in analogy to the slot-shaped overflow openings such that only oil below the viscosity limit can pass through the clearance. Since the viscosity depends on the oil temperature, by means of the defined clearance a switching function can be realized so that oil transfer at low temperatures is prevented and at higher temperatures is enabled. In addition or as an alternative to the play or clearance, in the area of the tongue-and-groove arrangement also overflow openings can be provided that with regard to their cross-sectional design and cross-sectional surface area are matched to a temperature-dependent oil exchange.
In the Figures, same components are identified with the same reference numerals.
The oil pan 1 illustrated in
In order to a enable a flow exchange between the oil chambers 2 and 3, in the partition 4 overflow openings 5, 6, 7, 8 are introduced that are to be closed by the closure elements 9 and 10. The partition 4 has a U-shaped section wherein the overflow openings 5 to 8 are provided in the approximately parallel extending wall sections 4a and 4b of the U-shaped section. The oppositely positioned overflow openings 5 and 6 are closed by the closure element that is embodied as a thermal switching valve 10 and the overflow openings 7 and 8 also oppositely positioned relative to each other by a closure element that is embodied as an oil drain screw 9. Overflow openings 5, 6 or 7, 8 that are immediately positioned opposite one another are closed or opened by a common closure element 10 or 9.
The thermal switching valve 10 switches temperature-dependent and is moved into a closed position at an oil temperature that is below a switching or limit temperature. When the oil temperature surpasses the switching temperature, the thermal element 10 is moved into the open position and the overflow openings 5, 6 are opened so that the oil exchange between the chambers 2 and 3 is enabled.
Both closure elements, i.e., the oil drain screw 9 as well as the thermal switching valve 10, are arranged in the U-shaped intermediate space between the parallel wall sections 4a, 4b. Upon opening the closure elements, complete drainage or exchange of oil is possible, particularly even from sections of the separated oil chamber 3 that, as a result of the complex geometry of the oil chamber 3, may be located in undercut areas.
The oil drain screw 9, as is shown in
As can be seen in the detail illustration according to
As can be seen in
Optionally, the overflow openings 15 are covered by a nonwoven attached to the partition 4. The nonwoven has a permeability that is matched to the viscosity of the oil. Advantageously, the nonwoven is designed such that only oil at a viscosity below a limit value can pass through; the viscosity limit value is determined as a function of the oil temperature and the resulting viscosity. This embodiment has the advantage that even larger overflow openings can be provided because the passage of oil is determined by the nonwoven.
In
It may be expedient to provide in the area of the tongue-and-groove connection or arrangement 16 an opening 18 that, similar to the slot-shaped overflow openings 15, has the task to enable an oil transfer as soon as a limit temperature is surpassed. The opening 18 is either introduced into the groove into which the end face of the partition is inserted or is embodied as a recess in the area of the end face or as an opening in the inner bottom 17 below the groove. Moreover, it is possible to provide the tongue-and-groove connection at least sectionwise with play or clearance so that the gap that is caused by means of the play or clearance also enables a flow transfer as soon as the oil has surpassed a limit temperature and the viscosity has dropped below a correlated limit value.
In
While specific embodiments of the invention have been shown and described in detail to illustrate the inventive principles, it will be understood that the invention may be embodied otherwise without departing from such principles.
Number | Date | Country | Kind |
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102009053682.5-13 | Nov 2009 | DE | national |