DE102017103647A1 - Oil sump for an internal combustion engine with a thermo sump valve - Google Patents

Abstract

To reduce the required installation space for a thermal oil sump valve in an oil sump for collecting a lubricant moving in an internal combustion engine in a lubricant circuit by means of a lubricant pump, comprising a hot oil chamber having a first sump volume and a main sump having a second sump volume, a thermal sump valve, formed to release after reaching a certain operating temperature, an inlet of the lubricant from the hot oil chamber into the main oil pan by means of closing element, wherein on the closing element acting in a first direction of actuation coil spring and a FGL spring () in one of the first actuating direction opposite acting second operating direction is proposed, the coil spring and the FGL spring are formed to cause a rotation of the closing element.

Description

The invention relates to an internal combustion engine comprising an oil circuit moved by means of an oil pump, the oil of the oil circuit from the internal combustion engine dripping first into a first oil pan with a first oil pan volume and after reaching a certain operating temperature with a thermo-oil pan valve an inlet of the oil into a second oil pan a second sump volume, which is greater than the first sump volume releases.

The thermo-sump valve operates temperature-dependent and releases an inlet to the second sump volume, so that even for the full-load operation of the internal combustion engine sufficient lubricant is present.

State of the art

From the prior art it is known to equip these thermal oil sump valves with two mutually acting on a closing piston springs, namely a conventional coil spring and a spring of a shape-memory alloy (FGL), which preferably act against each other against the closing piston, the closes an inlet in the second oil pan and releases. Shape-memory alloys assume a previously trained shape starting from a limit temperature determined by the composition of the alloy while performing work, whereas these can be designed almost arbitrarily below this limit temperature. Particular preference is given to using FGL alloys for wires which are used for the production of compression springs. Usually, these wires whose length changes or compression springs that produce a hub.

All solutions have in common that the work done by the FGL spring is performed against a similar element of spring steel, e.g. a closing piston in a housing. The counter-element made of regular spring steel is required to return the FGL element to a defined state as soon as the limit temperature is reached again.

Industrial FGL valves typically use an FGL compression spring and an oppositely-disposed, spring steel compression spring designed to maximize the working capacity of the FGL spring to fully open the valve.

A well-known thermo-sump valve or thermostatic valve separates the separate smaller hot oil chamber integrated in an oil sump from the larger sump. When starting the engine, first only the oil of the hot oil chamber is used for the oil supply of the vehicle and thus only this gradually heated. When the temperature of the lubricant in the hot oil chamber reaches a defined limit, the thermo-sump valve opens, freeing up the lubricant needed to operate the entire engine. From this time, the vehicle is supplied from both cavities and thus with the total capacity of the oil. If the temperature falls below the limit, the thermo-sump valve closes again and the chambers are separated again. Typically, wax-based thermostatic valves are used for this type of application, comprising a housing in which a bellows or container is received with wax, at one end of which a plunger protruding from the container is secured, which is connected to the thermostatic closing valve. Oil pan valve is connected.

Disadvantages of the prior art

A disadvantage of existing FGL valves is the height. Because these are basically constructed vertically, these include a surrounding cylinder with a lower compression spring disposed therein, acting on this lower compression spring lock cylinder and acting on the top of the lock cylinder FGL spring. This "vertical" structure requires appropriate space in the engine compartment, which is sometimes not available.

Technical problem (task)

Based on this prior art, the present invention seeks to at least partially avoid these disadvantages and in particular is constructed much smaller than existing thermal oil sump valves.

invention

According to the invention, this object is essentially already achieved with an oil sump for an internal combustion engine of the type mentioned above in that it is designed so that the closing element executes a rotational movement.

The inventive construction has significant advantages. Since the movement of the closing element is no longer translational, ie linear but rotating, considerably less height is required for the thermal oil sump valve. In the simplest case, only a disk rotatable by the springs is required as the closing element, which opens and closes an opening for the heated lubricant.

Preferably, the closing element is thus formed as a valve disc, which may be further included in an additional receptacle on the oil pan, in particular on the hot oil chamber.

In particular, this is done by the coil spring and the FGL spring are arranged directly above one another, preferably collinear along a common central axis, where they can be fixed with a first end - the inner end - and with a second end - the outer end - either are fastened to the closing element in the case of the FGL spring or to the oil pan in the case of the spiral spring.

Preferably, the spiral spring is formed of a flat steel and helically wound with a continuously increasing radius around a center, whereas the FGL spring preferably consists more of a circular wire, but also worm-shaped with continuously increasing radius around a center outwardly and bent. In a preferred embodiment, the valve has a total diameter of 30 to 50 mm, so has a radius of 15 to 25 mm, with a height of only 12 - 15 mm. By virtue of this configuration, the FGL spring and the spiral spring can be arranged together one above the other, e.g. on the inside of the hot oil pan and fixed to a common central centering pin, e.g. by means of a slot for inserting the coil spring and an opening for receiving the inner end of the FGL spring. The respective outer ends of the springs are preferably inserted into receiving slots, which are provided or formed webs or projections on the oil pan or hot oil pan.

Preferably, the spring steel of the FGL spring has a material thickness of 1-2 mm with a width of about 4-5 mm. The FGL spring is actuated within seconds, so it acts abruptly. The spring rate and the resulting spring force of the steel spring are to be adapted to the empirically determined working capacity of the FGL spring. The essential advantage of the design according to the invention is that the thermal oil sump valve can be made flatter by up to 80 percent than the thermo-valves on the market, ie has a significantly lower overall height and thus can be integrated more easily into other components. This has decisive advantages. Above all, no separate housing for the oil pan valve is more necessary, so that this can thus be integrated into the walls of the oil pan.

In the following detailed description, reference is made to the accompanying drawings which form a part of this specification and in which is shown by way of illustration specific embodiments with which the invention may be practiced. In this regard, directional terminology such as "top", "bottom", "front", "back", "front", "rear", etc. is used with reference to the orientations of the figure (s) described. Because components of embodiments can be positioned in a number of different orientations, the directional terminology is illustrative and is in no way limiting. It should be understood that other embodiments may be utilized and structural or logical changes may be made without departing from the scope of the present invention. The following detailed description is not to be construed in a limiting sense.

As used herein, the terms "connected," "connected," and "integrated" are used to describe both direct and indirect connection, direct or indirect connection, and direct or indirect integration. In the figures, identical or similar elements are provided with identical reference numerals, as far as this is expedient.

• 1 einen Längsschnitt durch eine erfindungsgemäße Ölwanne;
• 2 eine vergrößerte perspektivische Draufsicht der Federn des Ölwannen-Ventils; und
• 3 eine Draufsicht auf das Ölwannenventil gemäß 1.

Reference lines are lines connecting the reference to the part concerned. On the other hand, an arrow that does not touch any part refers to an entire entity to which it is directed. Incidentally, the figures are not necessarily to scale. To illustrate details, certain areas may be exaggerated in size. In addition, the drawings may be simplistically simplified and do not include every detail that may be present in the practice. The terms "top" and "bottom" refer to the illustration in the figures. Show it:

• 1 a longitudinal section through an oil pan according to the invention;
• 2 an enlarged perspective top view of the springs of the oil pan valve; and
• 3 a plan view of the oil pan valve according to 1 ,

The oil sump, marked 2 in its entirety, comprises a smaller hot oil chamber, that is, with a smaller volume 4 , which has a receiving space with a lower bottom, extending transversely extending to the surface of this bottom surface circumferentially on the side walls upwards and thus the cup-shaped hot oil chamber 4 with a capacity of 3 liters.

The oil pan 2 , which also has a volume of about 3 liters, is complementary to the hot oil chamber 4 designed, but larger, so that it includes the hot oil chamber 4 and the hot oil chamber 4 in the oil pan 2 can be used.

In the bottom 4a of the hot oil chamber 4 is a separator 6 used, in which the inventive thermal oil sump valve is integrated, which has a total height of 12 - 15 mm.

This thermo sump valve 6 includes a valve disc 6a, a steel coil spring 6b made of spring steel and a FGL spiral spring 6c made of a FGL metal with its inner ends in the same central, pin-shaped axis 6e the valve disc 6a are plugged in. The hot oil chamber 4 has an opening in the bottom 6d on that through the valve disc 6a is closable.

Is the limit temperature of the lubricant in the hot oil chamber 4 exceeded, so takes the FGL coil spring 6c their trained form, working against the steel spiral spring 6b , leaving a segmental opening with one of the opening 6d corresponding size in the valve disc 6a with the opening 6d in the hot oil chamber 4 Aligns and the lubricant from the hot oil chamber 4 in the oil pan 2 flows.

If the limit temperature falls below again, then the spring force of the steel coil spring 6c stronger again than the spring force of the FGL spring 6c , so that the steel coil spring 6b immediately moves back into the closed position and the valve disc thus the opening 6d closes.

The subject matter of the present invention results not only from the subject matter of the individual claims, but also from the combination of the individual claims with one another. All information and features disclosed in the documents - including the abstract - in particular the spatial design shown in the drawings are claimed as essential to the invention, as far as they are new individually or in combination with respect to the prior art.

It is understood by those skilled in the art that the application also claims the thermal oil sump valve itself, without the sump itself.

LIST OF REFERENCE NUMBERS

2

oil pan

4

Hot oil chamber

6

Thermo-sump valve

6a

valve disc

6b

Steel coil spring

6c

SMA coil spring

6d

opening

6e

axis

Claims (5)

An oil pan (2) for collecting a lubricant moved in an internal combustion engine by means of a lubricant pump in a lubricant circuit, comprising a hot oil chamber (4) having a first sump volume and a main sump having a second sump volume, a thermal sump valve configured to move therethrough Reaching a certain operating temperature to release an inlet of the lubricant from the hot oil chamber (4) in the main oil pan by means of a closing element, wherein on the closing element has a acting in a first direction of actuation coil spring and the first direction of actuation counteracting FGL spring, thus marked , That the coil spring and the FGL spring are formed to cause rotation of the closure member. Oil pan (2) after Claim 1 CHARACTERIZED THAT the FGL spring and the spiral spring are fixed to common force application elements . Oil pan (2) after Claim 2 , CHARACTERIZED IN THAT the force- applying element comprises a common axis. Oil pan (2) according to one of the preceding claims, characterized in that the spiral spring comprises a flat steel and the FGL spring is designed as a spring wire. Oil sump according to one of the preceding claims, characterized in that the closing element is designed as a valve disk (6a).

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