EP1180235A2

EP1180235A2 - Device for measuring at least one parameter of a flowing medium

Info

Publication number: EP1180235A2
Application number: EP01919143A
Authority: EP
Inventors: Thomas Lenzing; Wolfgang Mueller; Anke Fleischer; Uwe Konzelmann
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2000-02-26
Filing date: 2001-02-23
Publication date: 2002-02-20
Also published as: CN1232804C; JP2003524173A; CN1372631A; KR20020000634A; US20020148303A1; WO2001063218A2; US6722196B2; WO2001063218A3; DE10009154A1

Abstract

The invention relates to a device for measuring at least one parameter, especially the volume flow, of a medium flowing in a conduit, especially the intake air volume flow of an internal combustion engine, with at least one measuring element being situated in the flow. It is known from the prior art that constrictions that extend radially in the conduit cause acoustic disturbances that can be perceived as a whistling noise. The inventive constrictions (35, 40, 79) do not evenly reduce the cross-section of the conduit (14) and therefore do not cause swirling turbulences that are acoustically perceived as a whistling noise.

Description

Device for measuring at least one parameter of a flowing medium

State of the art

The invention is based on a device for measuring at least one parameter of a medium flowing in a line according to the preamble of claim 1.

DE 196 52 753 A1 discloses a device with a measuring element for measuring a mass of a flowing medium, which has a flow straightener with a grating upstream of the measuring element. The flow straightener with the grille is installed in a carrier tube in the line and leads to a narrowing in the line.

From DE 197 38 337 AI or US Pat. No. 5,892,146 a hot wire air mass meter is known which has an aperture upstream of the measuring element, which is formed in one piece with a wall of the line. This leads to a narrowing in the line and an increase in the flow rate of a forward mass flow with pulsating flow downstream of and within the diameter of the orifice without the flow closing to destroy .

Such ring-shaped constrictions in devices of the mentioned documents can cause acoustic disturbances, which are noticeable by whistling, in certain flow conditions in the line.

These disturbances are triggered by ring-shaped vortices, which arise downstream behind an edge of the constriction and spread in the direction of flow of the line.

DE 198 156 58 A1 discloses a device with a measuring element for measuring a mass of a medium flowing in a line, a flow tube being located in the line and the measuring element being arranged in the flow tube. Loud, annoying whistling noises are reduced by structure grooves on the end face of the flow pipe.

Advantages of the invention

The device according to the invention with the characterizing feature of claim 1 has the advantage that acoustic disturbances can be avoided in a simple manner, since the formation of annular vortices is reduced by interference suppression elements.

The measures listed in the dependent claims allow advantageous developments and improvements of the device mentioned in claim 1. It is advantageous to integrate the at least one prevention element with a support tube of a flow rectifier or in a second support tube, since this simplifies production.

If there is no flow equalizer or support tube at the front, it is advantageous for simple manufacture to integrate the at least one prevention element in a wall of a line.

An advantageous arrangement of interference suppression elements is given if they are uniformly distributed and uniform in the circumferential direction of the line, since this does not distort the velocity profile of the flow.

For simple manufacture, it is advantageous to design the at least one interference suppression element as an elevation in the line.

An advantageous design of the interference suppression elements is provided by an aperture which has different sections whose radial distances from a center line of the line are different.

It is advantageous to round the prevention elements in the opposite direction to the main flow direction, since this does not distort the velocity profile of the flow.

It is particularly advantageous to use a pipe body of the line in order to avoid a measurement characteristic deviation of a measuring element caused by exposure to liquid or solid particles. It is also advantageous to integrate a protective grille in the line or in the tubular body.

drawing

Embodiments of the invention are shown in simplified form in the drawing and explained in more detail in the following description.

Show it

1 shows a device according to the invention with a flow straightener and a grille, in which at least one prevention element according to the invention is arranged, FIG. 2a, 2b shows a detail from FIG. 1,

Figure 3a to 3d several embodiments of

Preventing members,

Figure 4 shows an inventive device with a tubular body.

Description of the embodiments

In FIG. 1, a device 1 for measuring at least one parameter of a medium flowing in a line 14, in particular the intake air mass of an internal combustion engine, is shown in a partial sectional view. Parameters of a flowing medium are, for example, the volume flow for determining a mass, a temperature, a pressure or a flow rate, which are determined by means of suitable sensors. The device 1 can be used for measurements of further parameters. The flowing medium can be air A gas mixture or a liquid. The internal combustion engine can be, for example, a mixture-compressing, spark-ignited or also an air-compressing, self-igniting. The device 1 has at least one measuring part 4, which can be plugged into a measuring connection 7 of the device 1, for example, and in which a measuring element 25 is arranged. The measuring element 25 can, for example, be a temperature sensor as known from DE 42 28 484 AI, a pressure sensor as used in DE 34 35 794 AI, or an air mass sensor that determines the corresponding parameters. An air volume flow sensor is selected here as an example for the various sensors. The measuring part 4 has, for example, a slim, rod-shaped, cuboid shape that extends in the direction of a plug-in axis 10 and is inserted, for example, in an opening that is recessed from a wall 13 of the measuring nozzle 7. The wall 13 has an inner wall 15 and delimits a flow cross section of the line 14, which for example has a circular cross section, in the center of which extends in the direction 18 of the flowing medium, parallel to the wall 13, a central axis 21 which is oriented perpendicular to the plug axis 10 is. The direction of the flowing medium is identified in FIG. 1 by corresponding arrows 18 and runs from left to right there.

The measuring element 25 is introduced with the measuring part 4 into the flowing medium. A measuring channel 27 is formed in the measuring part 4 of the device 1, in which the measuring element 25 for measuring the medium flowing in the measuring nozzle 7 is accommodated. The construction of such a measuring part 4 with measuring element 25 is known to the person skilled in the art, for example from DE-OS 44 07 209 sufficiently known, the disclosure of which is to be part of the present patent application.

Provided upstream of the measuring element 25 is a grid 32 and a sleeve-shaped flow straightener 30, which is fastened, for example, to a carrier tube 33. The carrier tube 33 has a smaller inner diameter than the line 14 and thus forms a constriction 35.

The flow straightener 30 is made, for example, of plastic and is produced, for example, by injection molding and has a multiplicity of flow and flow directions

Example of rectangular openings 34.

The construction of such a flow rectifier 30 with

Grid 32 is well known to the person skilled in the art, for example from DE 196 52 753 AI, the disclosure of which is to be part of the present patent application. For example. to the support tube

33 of the flow straightener 30 is at least an acoustic one

Preventing element 40 arranged integrally.

For the final assembly of the device 1, the

Flow straightener 30 and grating 32 are formed in a mounting unit provided at the upstream end of the measuring nozzle 7, for example circular opening 47, until the flow straightener 30 rests with its ring wall 50 against a stop 52 of the measuring nozzle 7 that reduces the cross section of the opening 47. For permanent fastening of the flow straightener 30 in the opening 47, the latter has on the support tube 33, for example, barb-shaped hook elements 57 which protrude somewhat radially outwards from its outer surface 55 and which latch correspondingly in a groove 60 provided in an inner wall of the opening 47 of the measuring nozzle 7 can. FIG. 2 a shows an enlarged detail from FIG. 1 identified by a dashed line. The latching hooks 63 are resilient and have a latching head 65 that extends radially inward. In the installed state of the grating 32, the locking heads 65 grip around an edge of the grating 32 like pliers and lie against a surface 68 of the grating 32 facing the measuring part 4, so that the grating 32 is pressed by the locking heads 65 against a peripheral projection formed by the inner surface 70 74 to hold the flow straightener 30.

A second support tube 72 is located downstream behind the support tube 33. The second support tube 72 is at the same radial distance from the center line 21 as the inner surface 70. At the downstream end of the second support tube 72, for example, at least one acoustic prevention element 40 is arranged in one piece, which is located in extends in the radial direction in line 14. The second carrier tube 72 is pressed against the stop 52 by the carrier tube 33, for example. However, it can also be fastened in the line 14 like the carrier tube 33. The acoustic interference suppression element 40 acts mechanically on the flow in the line 14 and thus prevents annular vortices which arise downstream behind an edge of a constriction and spread in the direction of flow of the line and are otherwise noticeable as whistles. In cross section along the main flow direction 18 through the prevention element 40, the prevention element 40 has, for example, a rounded shape 41 upstream and a tear-off edge 42 downstream. The at least one interference suppression element 40 leads to a narrowing of the line 14 by 2% to 30%. Figure 2b shows how the second support tube 72 is made in one piece with the support tube 33. The support tube 33 continues downstream from the grille 32 with an extension arm 77 along the inner wall 15. At its end 78 there is the acoustic prevention element 40, which extends in the radial direction into the line 14. The grid 32 is installed, for example, by the support tube 33 being bent radially outward in the region of the extension arm 77 and then the grid 32 being used.

Various exemplary embodiments of the prevention element 40 are shown in FIGS. 3a to 3d. For the same or equivalent parts, the same reference numerals are used as in the previous figures. FIG. 3a shows a prevention element 40, which is designed as a radial elevation 79 to the center line 21 and has a rectangular cross section transverse to the main flow direction 18. The elevations 79 are, for example, of the same size and are evenly distributed along a circumferential line 80 of the line 14, which is shown in broken lines.

The radial elevations 79 in FIG. 3b have an arcuate cross section transverse to the main flow direction 18. FIG. 3c shows that the radial elevations 79 can have different geometries in one embodiment of the device. These are, for example, trapezoidal in the radial cross section or circular arc shaped. The elevations 79 are evenly distributed and arranged symmetrically. FIG. 3d shows a prevention element 40, which is designed as an aperture 82 and whose radial boundary line 81 does not have a constant inside diameter and is designed, for example, as a wave. The prevention elements 40 are, for example, in one piece with the Measuring nozzle 7 executed.

Figure 4 shows the device 1 in a line 14 in which a medium flows. For the same or equivalent parts, the same reference numerals are used as in the previous figures. In the line 14 there is, for example, a tubular body 85 which runs at a radial distance from the line 14 and around which the medium flows and which serves as an element 84 to reduce the exposure of the measuring element 25 to liquid or solid particles.

The prevention elements 40 are arranged in the main flow direction 18 in such a way that their tear-off edges 42 are located at or at the same height in the axial direction with a tube inlet opening 88 of the tube body 85. The prevention elements 40 are connected in one piece to the measuring connection 7, for example. However, they can also be arranged additionally or only on the tubular body 85.

Prevention elements 40 can also be arranged in the tubular body 85, for example.

The at least one prevention element 40, 79, 82 is connected in one piece, for example, to the tubular body 85. The tubular body 85 has a throughflow channel 87 and, in the region of its upstream end, a protective grille 90, as an element 84 for reducing the

Application of the measuring element 25 with liquid or

Solid particles.

The protective grid 90 can be designed, for example, as a wire mesh or a plate-shaped grid. Any other shape is also possible. Plastic, metal, ceramic or glass can be used as the material for the protective grid 90 both for the wire mesh and for the plate-shaped protective grid 90 become. The plate-shaped protective grid 90 made of plastic can, for example, be produced entirely by injection molding or by introducing the grid openings 94 into a plate-shaped base body by means of a material-removing process. The plate-shaped protective grid 90 made of metal can be produced, for example, from sheet metal by stamping, eroding, drilling, etc.

In the flow channel 87 there is a flow direction 98 downstream of the protective grille 90 somewhat downstream. The flow direction 98 runs approximately parallel to the

Main flow direction 18. The line 14 has the center line 21, which for example is also the center line of the tubular body 85. For example, the measuring part 4 extends into the tubular body 85. A plug end of the measuring part 4 receiving the electrical connections, for example in the form of plug tongues, remains, for example, outside the line 14. In the known part 4, the measuring element 25 is provided in a known manner is in contact with the air flowing through the flow channel 87 and by means of which the air mass drawn in by the internal combustion engine is determined. The measuring element 25 can be designed in a known manner, for example in the form of at least one temperature-dependent resistor. In particular, it is possible, as is shown, for example, in DE 43 38 891 AI or US Pat. No. 5,452,610, to design the measuring element 25 as a micromechanical component which has a dielectric membrane on which resistance elements are formed. It is also conceivable to introduce the measuring element 25 into the line 14 or the tubular body 85 without a measuring body. On the tubular body 85 there are, for example, at least two struts 101 which serve to hold the tubular body 85 in the line 14. In addition to holding the tubular body 85 in the air flow between the line 14 and the tubular body 85, the struts 101 cause an increase in the pressure drop, so that the amount of air flowing through the flow channel 87 increases, and on the other hand the struts 101 intentionally rectify the air the intake air flow.

The tubular body 85 can also be arranged in the line 14 without struts 101, for example it is fastened to the measuring part 4.

The protective grid 90 consists, for example, of mutually perpendicular webs 105, for example perpendicular to the plug axis 10 and horizontally to the plug axis 10, the webs 105 which are horizontal to the center line 21 being set, for example, at an angle of approximately 30 degrees to the plug axis 10. As a result, the main flow direction 18 is downstream behind the

Protective grille 90 changed. The protective grid 90 can also be inclined with respect to the main flow direction 18. Dirt particles and liquid droplets are deposited on the protective grid 90 and are guided to an inner wall 107 of the line 14 or the tubular body 85 and thereby move past the inlet opening 110 of the measuring part 4 or past the measuring element 25.

Claims

Expectations

1. Device (1) for measuring at least one parameter, in particular a mass flow, of a medium flowing in a line (14) in a main flow direction (18), in particular an intake air mass flow of an internal combustion engine, with the following features: a) in the line (14 ) there is a measuring element (25) around which the medium flows, b) there is at least one constriction (35) in the line (14) which causes acoustic interference,

characterized in that

the constriction (35) is designed as a mechanical-acoustic prevention element (40).

2. Device according to claim 1, characterized in that

at least one element (84) is arranged in the line (14) which is used to reduce the exposure to the measuring element (25) Serves liquid or solid particles.

3. Device according to claim 2, characterized in

that in the line (14) as an element (84) for reducing the exposure of the measuring element (25) to liquid or solid particles there is a tubular body (85) with a through-flow channel (87) through which the medium flows, so that the measuring element (25) is located located in the tubular body (85).

4. Apparatus according to claim 2 or 3, characterized in that

as an element (84) for reducing the exposure to the

Measuring element (25) with liquid or solid particles, there is a protective grid (90) in the line (14) or in the tubular body (85).

5. The device according to one or more of the preceding claims, characterized in that

The at least one prevention element (40) is designed as a radial elevation (79) along a radial circumferential line (80) of the line (14).

6. The device according to claim 5, characterized in that

the at least one radial elevation (79) transverse to Main flow direction (18) has a rectangular cross section.

7. Apparatus according to claim 5 or 6, characterized in that

the at least one radial elevation (79) transverse to the main flow direction (18) has a trapezoidal cross section.

8. The device according to one or more of claims 5 to 7, characterized in that

the at least one radial elevation (79) transverse to the main flow direction (18) has an oval or circular cross section.

9. The device according to one or more of claims 5 to 8, characterized in that

the radial elevations (79) are evenly distributed at a distance from one another along a radial circumferential line (80) of the line (14).

10. The device according to one or more of claims 5 to 9, characterized in that

the radial elevations (79) have the same shape.

11. The device according to one or more of the preceding claims 1 to 3, characterized in that that the line (14) has a center line (21), and that in the line (14) as an acoustic prevention element (40) a diaphragm (82) is arranged, which has a radial boundary line (81), the radial distance from the center line (21) is different in the radial circumferential direction.

12. The apparatus according to claim 11, characterized in that

the radial boundary line (81) of the diaphragm (82) is wave-shaped.

13. The device according to one or more of the preceding claims, characterized in that

that the at least one prevention element (40) is rounded in the opposite direction to the main flow direction (18).

14. The device according to one or more of the preceding claims, characterized in that

that in the line (14) there is a flow straightener (30) which is integrated in a support tube (33) which can be introduced into the line (14), and that the at least one prevention element (40) on the

Carrier tube (33) of the flow straightener (30) is arranged in one piece.

15. The device according to one or more of the preceding claims, characterized in that that the at least one prevention element (40) is arranged in one piece on a second carrier tube (72) which can be introduced into the line (14).

16. The device according to one or more of the preceding claims, characterized in that

the at least one prevention element (40) is formed in one piece with the wall (13) of the line (14).