DE102016207557B3 - Grid cage via oil level gauge tube - Google Patents

Abstract

Oil level sensor (1) for measuring the oil level (11) in an oil tank (19) with
an oil level measuring chamber (16), which has a geodätisch bottom arranged oil inlet opening (5) in the planned installation position, and
a geodetically arranged at the top air outlet opening (6),
wherein the oil level measuring space (16) is arranged to determine the oil level (11), and
wherein the oil inlet opening (5) is arranged to allow an oil volume flow into the oil level measuring chamber (16), and the air outlet opening (6) is provided to allow an air volume flow from the oil level measuring chamber (16).
characterized in that
the oil level sensor (1) has a grid structure (4) for protecting the oil level measuring chamber (16),
in that said grid structure (4) is arranged in such a way that it is arranged upstream of the oil inlet opening (5) relative to an oil volume flow from outside the oil level sensor into the oil level measuring chamber (16).

Description

The invention relates to a device for measuring an oil level in an oil reservoir. A device according to the preamble of the first claim is known from the prior art, in particular from DE19653879A1 ,

The invention will be described below with reference to a motor vehicle drive system. The oil level in a motor vehicle drive system is of essential importance for the operation of the drive system and thus of the motor vehicle. Both too high and too low oil levels can lead to the destruction of the drive system or damage to it, so that the measurement of the correct oil level is of great importance.

The DE19653879A1 deals with a measuring sensor to determine the level in an oil reservoir, with oil in a geodetic lower area through an oil inlet opening into the sensor and so the oil level of the oil reservoir is measurable. With such an oil inlet opening there is the danger of clogging, so that a correct measurement of the oil level is difficult.

The DE 83 10 272 U1 deals with an oil level indicator for automotive internal combustion engines. The DE 195 11 995 C1 deals with a device for measuring the oil level in an oil pan of an internal combustion engine. The DE 199 42 502 A1 deals with a device for measuring at least one parameter of a flowing medium in a conduit. The DE 694 01 677 T2 deals with a chemically sensitive optical cable and the DE 10 2012 109 580 A1 deals with a sensor arrangement and a method for producing a sensor arrangement.

Furthermore, measuring sensors are known from applications which, based in each case on the planned installation position of the measuring sensor, have an oil inlet opening arranged in the geodetically lower area of the sensor and an air outlet opening arranged in a geodetically upper area. In this case, this outlet opening is set up so that air can escape from the measuring sensor and thus oil can flow unhindered through the oil inlet opening in this, whereby the measurable oil level changes in a Ölmessinnenraum the sensor. If one of these opening sets or the flow is hindered by this, the measurement of the oil level is impaired. Preferably, the oil level sensor has one or more oil inlet openings and one or more air outlet openings.

It is an object of the invention to develop known oil level sensors such that the reliability of this is increased. This object is achieved by a sensor according to the first claim, preferred developments are the subject of the dependent claims.

For the purposes of the invention, an oil level sensor means a device for measuring the oil level in an oil tank. In this sense, the level of a level in this oil tank is to be understood in this sense as the oil level. The oil level sensor has an oil level measuring range within which the measurement of the oil level is feasible. To measure the oil level while various physical approaches are known.

This oil level measuring chamber has an oil inlet opening and an air outlet opening. In this case, the oil inlet opening, in particular in a geodetically lower lying region of the oil level sensor, and the Ölniveaumessraums arranged. Through the oil inlet opening, the oil level measuring chamber can be fluid-conductively connected to the environment surrounding the oil level sensor. The air outlet opening is arranged in particular in a geodetically overhead region of the oil level sensor or of the oil level measuring chamber. The oil level sensor is particularly applicable to an oil tank, an oil pan, or the like (oil tank), and the environment surrounding the oil level sensor is formed by the oil sump stored in this oil tank.

The geodetic information always refers to the planned installation position of the oil level sensor.

The air outlet opening is in particular configured to fluidly connect the oil level measuring chamber with the environment surrounding the oil level sensor. Functionally, it is possible in particular by such an embodiment of the oil level sensor that when the oil level rises in an oil tank, an oil volume flow flows through the oil inlet opening into the oil level measuring chamber. If the oil level in the oil level measuring chamber rises, an air volume flow out of the oil level measuring chamber forms through the air outlet opening. In particular, this makes it possible that changes within the Ölniveaumessraums the oil level with the oil level in the oil reservoir. The sensor principle described above is already known from the prior art.

The oil level sensor has a grid structure for protecting the oil level gauge. In the context of the invention, a lattice structure is to be understood as meaning a structure which has a large number of free ones Having areas, these free areas are flowed through by a volume flow. Furthermore, these free areas are surrounded by footbridges. Colloquially, such a lattice structure may be referred to in particular as a network or sieve. Preferably, this grid structure is spaced from the oil level sensor and surrounds these sections or completely.

Furthermore, this grid structure is arranged in such a way that, with reference to an oil volume flow from outside the oil level sensor into the oil level measuring chamber, it is arranged upstream of the oil inlet opening. In other words, a volumetric flow that flows into the oil level measuring chamber, as it forms when the oil level rises in an oil container, must flow through the grille structure before it flows into the oil level measuring chamber. When flowing through the grid structure, in particular particles which exceed a certain size are retained by the grid structure, so that this grid structure acts like a filter or retaining screen. In particular, by such a lattice structure, the clogging or clogging of the oil inlet opening is at least made difficult or prevented and thereby the reliability of the oil level sensor is improved. Further, the grid structure is spaced from the oil inlet port, and preferably, the grid structure is spaced from an oil inlet port that connects the oil inlet port to an environment surrounding the oil level sensor.

Furthermore, the proposed oil level sensor has a further lattice structure. This further lattice structure is designed to protect the air outlet opening or to protect the oil level measuring chamber with respect to a volumetric flow that forms through the air outlet opening or a volumetric flow in the opposite direction. In particular, the further lattice structure can be set up so that with this an oil foam entry over the air inlet opening can be prevented.

Preferably, this further lattice structure is arranged such that, relative to an air volume flow from the oil level measuring chamber to the outside of the oil level sensor, downstream of the air outlet opening is arranged and more preferably, this further lattice structure is arranged spaced from the air outlet opening. Turned another way, an outgoing air flow from outside the oil level sensor first flows through the further grid structure before it enters the oil level measuring chamber through the air outlet opening.

Studies have shown that in particular by foam or bubbling on the oil in an oil reservoir, the air outlet of the oil level sensor may be added or temporarily obstructed the flow of air therethrough. This clogging of the air outlet opening can be reduced or prevented in particular by the further lattice structure, and thus an improved oil level sensor can be represented. In particular, by a complaint of the lattice structure or the other lattice structure of the respective opening, in contrast to an arrangement in or at the opening, more flow paths for the volume flow or the result and thus better operational reliability can be achieved.

In a preferred embodiment of the invention, the further lattice structure and the lattice structure are integrally formed with each other, preferably they form a common, one-piece lattice structure. In the context of the invention, a lattice structure is preferably to be understood as meaning a net-like, preferably a latticed or particularly preferably a sieve-like component.

Further preferably, such a component has a regular structure and more preferably an irregular structure. For the purposes of the invention, a mesh structure is preferably also understood to mean a mesh of a plurality of threads or preferably wires, in particular an irregular structure is formed by such a mesh. The threads or wires form the webs of the lattice structure / further lattice structure and the spaces between the free areas, which can be flowed through.

Preferably, in a regular structure of a volume flow durchmömbare adjacent areas preferably have the same geometric shape and particularly preferably the same size. In particular, by an integrally formed lattice structure, a particularly simple construction of the oil level sensor is possible.

In a preferred embodiment, the lattice structure or the further lattice structure or both, at least in sections or completely, two, based on a flow through this structure, arranged one behind the other lattice. A grid arranged spatially closer to the oil level sensor may be referred to as an inner grid and a grid further away from the oil level sensor may be referred to as an outer grid. Preferably, such a configuration of the grid structure with an inner and an outer grid results in a double-walled grid structure. In particular by means of a double-walled lattice structure, a particularly reliable protection of the oil level measuring chamber can be achieved.

In a preferred embodiment of the invention, the grid structure is formed as a double-walled grid structure having an inner grid and an outer grid. Further preferably For example, these two gratings are aligned such that a free region of the inner lattice is at least partially covered by a lattice of the outer lattice. In particular, by means of such an orientation of the inner to the outer grid, a particularly good protection of the Ölniveaumessraums can be achieved.

In a preferred embodiment, the grid structure or the further grid structure or both has an average hole size (free, permeable area), which is selected from a range which is greater than 0.001 mm and less than 4 mm. In this sense, the largest dimension of one of the previously described free areas is to be regarded as the hole size.

The mean hole size is to be understood in particular as the mean value of a multiplicity of hole sizes of the lattice structure, or of the further lattice structure or of both structures. Preferably, the hole sizes for forming the average hole size in a height direction, ie in the direction of a rising or falling oil level, arranged at the same height. In particular, the mean hole size is selected from a range which is larger than 0.001 mm and smaller than 4 mm. Further preferably, the area from which the hole size can be selected is> 0.01 mm, preferably> 0.1 mm and particularly preferably greater than 0.2 mm and very particularly preferably greater than 0.3 mm and more preferably this area is smaller than 2 mm, preferably <1.5 mm and more preferably less than 1 mm. In particular, the aforementioned range for selecting the hole size of the lattice structure has proven to be particularly favorable.

Preferably, in a double-walled lattice structure, the inner and the outer lattice have the same mean hole size, whereby in particular a particularly simple production can be achieved. Preferably, in the case of a double-wall-thick lattice structure, the inner and the outer lattice have different mean hole sizes, whereby a good adaptation of the protective function for the oil level measuring chamber can be achieved.

Further preferably, the mean hole size of the lattice structure in the lower region of the lattice structure is different than in the upper region. Preferably, the grid structure is formed in the region of the air inlet opening such that the mean hole size is greater in this area than in the underlying area of the grid structure. Such a different lock size can be achieved by arranging two or more grids one behind the other in the area with a low average hole size (double-walled grid structure). The extent of these ranges depends on the oil level with which the oil level sensor is to be used.

In a preferred embodiment, the grid structure or the further grid structure or both, at least in sections, has a cylindrical cross-section. In particular, by means of such a configuration of one or more of these structures, a particularly simple construction of these is made possible.

The above-described oil level sensor is intended for use in a container, in particular oil container for receiving lubricant, preferably for use in an engine oil pan in a motor vehicle. In this case, this oil level sensor is completely or partially inserted into an interior of the oil tank, said interior of the oil tank for receiving the oil, in particular engine or transmission oil, is set up. In particular, the oil level sensor is arranged in the container such that a change in the level, that is the oil level, in this oil container, leads to a change in the oil level in the oil level measuring chamber of the oil level sensor. Further preferably, the part of the oil level sensor located in the oil tank is completely covered by the grid structure.

In a preferred embodiment of the oil tank, the oil level sensor is arranged in scheduled operation at an at least locally or globally lowest location in the interior of the oil tank. Preferably, at least the oil inlet opening is arranged at such a location or arranged at least in the vicinity of such a location. In particular, by the arrangement of the oil level sensor in such a place a particularly good measurement of the oil level in the oil tank is possible.

In a preferred embodiment of the oil container, the oil level sensor, preferably at least the region of the oil level sensor which extends into the interior of the oil container, is preferably partially or preferably completely covered by the lattice structure or the further lattice structure.

The invention is based in particular on the basic idea that a larger flow-through surface is created by the lattice structure, which is arranged at a distance from the actual oil level sensor, than with an arrangement of a filter or grille in the oil inlet or the air outlet opening. The lattice structure makes it achievable, on the one hand, that no or at least fewer particles and oil foams reach the sensor, and, on the other hand, that the surface which can be flowed through is so large that clogging of the latter is virtually ruled out and an increase in operational reliability can be achieved.

The invention is described below with reference to the figures in a partially schematic manner. Showing:

1 FIG. 2: a schematic representation of an oil level sensor, FIG.

2 : the alignment of an inner and an outer grid against each other,

3 an oil tank with an oil level sensor.

1 shows a schematic representation of an oil level sensor 1 , The oil level sensor has a pedestal 2 and a measuring tube 3 on. Inside the measuring tube 3 is the Ölniveaumessraum (not shown) arranged. In this oil level gauge, oil can pass through the oil inlet 5 flow. Incoming oil increases the oil level in the oil level gauge and air from this oil level gauge can flow through the air outlet 6 escape from this.

Inside the measuring tube 3 appropriate means for measuring the oil level in the Ölniveaumessraum are arranged. The measuring tube 3 is of a lattice structure 4 surround. Through the grid structure 4 are both the air outlet 6 as well as the oil inlet 5 and thus the level of the oil level is protected.

In 2a is a double-walled lattice structure 4 with an inner grid 9 and an outer grid 10 shown in plan view. For better distinguishability of the two grids 9 . 10 , is the inner grid 9 represented by dashed lines, this does not mean that the crosswise arranged webs 17 of the inner lattice 9 are interrupted. The outer grid 10 has crosswise arranged webs 18 on. Between the bridges 17 . 18 Free areas are formed, which are flowed through by a volume flow. Here is the inner grid 9 opposite the outer grid 10 aligned so that the webs 17 of the inner lattice 9 , the free areas of the outer grid 10 partially cover.

In 2 B is a sectional view of the outer grid 10 and the inner grid 9 the lattice structure 4 shown. Here are the two grids 9 . 10 shown spaced apart from each other in the illustrated embodiment.

Regardless of the remainder of the invention, it also enables the two grids 9 . 10 are arranged without a gap to each other and then lie directly on each other.

The measuring tube 3 indicates the measuring tube wall 7 on. Outside the measuring tube 3 is the oil level 11 in front. Through the oil inlet opening (not shown) and the air outlet opening (not shown) forms in the interior of the measuring tube 3 , so in the oil level gauge 16 , the oil level 8th This rises and falls with the oil level 11 ,

In 3 is a sectional view of an oil container 19 with the oil tank wall 20 shown. The oil tank 19 has an oil drain plug 13 and an oil level sensor 1 on. The oil level sensor 1 is at the global lowest point of the oil reservoir 19 arranged. In the oil tank 19 can get dirt 12 especially in the area where the oil level sensor 1 is arranged, accumulate. These pollutions 12 be through the grid structure 4 from the measuring tube 3 kept away. About fasteners 14 can the oil tank 19 be attached to another structure.

Claims (9)

Oil level sensor ( 1 ) for measuring the oil level ( 11 ) in an oil container ( 19 ) with an oil level measuring chamber ( 16 ) inside a measuring tube ( 3 ), which in the planned installation position a geodetic down in the measuring tube ( 3 ) arranged oil inlet opening ( 5 ) and a geodetically arranged at the top air outlet ( 6 ), whereby the oil level measuring chamber ( 16 ) for determining the oil level ( 11 ), the oil inlet opening ( 5 ) for allowing an oil volume flow into the oil level measuring space ( 16 ) and the air outlet ( 6 ) for allowing an air volume flow from the oil level measuring chamber ( 16 ), characterized in that the oil level sensor ( 1 ) a lattice structure ( 4 ) for the protection of the oil level gauge ( 16 ), that this grid structure from the measuring tube ( 3 ) is arranged at a distance and surrounds this grid structure ( 4 ) is arranged such that, in relation to an oil volume flow from outside the oil level sensor into the oil level measuring chamber ( 16 ), upstream of the oil inlet ( 5 ) and that the oil level sensor ( 1 ) has a further lattice structure which, for the protection of the air outlet opening ( 6 ) and based on an air volume flow from the oil level measuring chamber ( 16 ) to the outside of the oil level sensor ( 1 ), downstream of the air outlet ( 6 ) is arranged. Oil level sensor according to claim 1, characterized in that the further grid structure and the grid structure are integrally formed with each other. Oil level sensor according to one of the preceding claims, characterized in that the lattice structure ( 4 ) and / or the further lattice structure, sections or completely, double-walled, so that they form an inner grid ( 9 ) and an outer grid ( 10 ) exhibit. Oil level sensor according to claim 3, characterized in that the inner and outer grids ( 9 . 10 ) in each case by a volume flow through free areas and that these free areas by webs ( 17 . 18 ) of the grid are separated from each other, that one or more such free areas of the inner grid ( 9 ) of one or more such webs ( 18 ) of the outer grid ( 10 ), with respect to a volume flow from outside the oil level sensor ( 1 ) to the oil inlet port ( 5 ) or in relation to a volume flow from the air outlet opening ( 6 ) to the outside of the oil level sensor ( 1 ), at least partially covered. Oil level sensor according to one of the preceding claims, characterized in that the lattice structure ( 4 ) and / or the further grid structure has a mean hole size selected from a range greater than 0.001 mm and less than 4 mm. Oil level sensor according to one of the preceding claims, characterized in that the lattice structure ( 4 ) and / or the further grid structure at least partially have a cylindrical cross-section. Oil tank with an oil level sensor according to one of the preceding claims, wherein the oil level sensor ( 1 ) in an interior of the oil container ( 19 ) is arranged, which is adapted to receive the oil. Oil tank according to claim 7, characterized in that the oil level sensor ( 1 ) in scheduled operation at an at least locally geodetically lowest location in the interior of the oil container ( 19 ) is arranged. Oil container according to one of claims 7 or 8, characterized in that the grid structure ( 4 ) the measuring tube ( 3 ) completely covered in the interior of the oil tank.

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