DE202011105809U1 - Device for measuring the mass flow of a gas - Google Patents

Abstract

Device for measuring the mass flow of a gas, comprising a tube (1) with an iris diaphragm (4) provided therein for changing a flow cross-section, a first flow guide element (6) provided on one side of the iris diaphragm (4) and one on the one side opposite other side of the iris diaphragm (4) provided second flow guide element (7), wherein in the center (Z) of at least one of the flow guide elements (6, 7) a sensor (11, 13) for measuring the mass flow of the gas is attached.

Description

The invention relates to a device for measuring the mass flow of a gas.

It is generally known in the art that the mass flow of a gas, for example air or natural gas, can be measured by means of different measuring methods. For example, today sensors are used in particular in motor vehicles, which operate on the principle of a hot wire anemometer. In addition, it is also known to measure the mass flow of a gas, for example, by the differential pressure method with a Pitot tube, a Prandl probe or the like.

Especially in the field of gas meters, the problem arises that with conventional mass flow measuring devices for detecting the amount of gas consumed for lack of sufficient dynamics caused by a leak very low mass flow can not be detected. To detect a leak, a special device must be provided.

The object of the invention is to eliminate the disadvantages of the prior art. In particular, a device for measuring the mass flow of a gas with improved dynamics should be specified.

This object is solved by the features of claims 1, 13 and 14. Advantageous embodiments of the invention will become apparent from the features of claims 2 to 12.

According to the invention, an apparatus for measuring the mass flow of a gas is proposed, comprising a tube with an iris diaphragm provided therein for altering a flow cross-section, a first flow guiding element provided on one side of the iris diaphragm and an other side of the iris diaphragm opposite the one side provided second flow guide, wherein in the center of at least one of the flow guide a sensor for measuring the mass flow of the gas is mounted.

With the proposed device can be measured in a surprisingly simple manner with a very high dynamics of the mass flow of a gas. For this purpose, a flow cross-section in the tube can be set with the iris diaphragm so that the mean flow velocity of the gas is optimal for the respective measuring range of the sensor. The proposed device can be produced easily and inexpensively. She is robust.

According to one embodiment of the invention, the tube is formed of a first and a second portion and the iris diaphragm is mounted between the two sections. This facilitates the installation of the iris diaphragm. For example, the two sections can be screwed together. The iris diaphragm can be received in a suitable recess between the sections and held for example by clamping. The flow guide elements are advantageously arranged adjacent to the iris diaphragm on both sides thereof. They can be clamped together with the iris diaphragm between the two sections. This facilitates the manufacture of the device.

According to an advantageous embodiment, the first flow guide is formed from a plurality of concentrically arranged first cylindrical ring elements and the second flow guide from a plurality concentrically arranged second cylindrical ring elements. By providing the first and second flow guide elements, a mechanical stabilization of the iris diaphragm against undesired deflection in the direction of the tube axis or axial direction can be achieved. The iris diaphragm is expediently arranged concentrically with respect to the tube axis.

The first cylindrical ring elements may be held by means of radially extending first spokes on a first outer ring of the first ring member. The second cylindrical ring elements may be held by means of radially extending second spokes on a second outer ring of the second ring element. The outer rings expediently have a profile which allows attachment of the respective flow-guiding element to an inner side of the tube or to a section.

To be particularly advantageous, it has proven to perform the first and the second flow guide identical. This further reduces the manufacturing cost. Apart from that, it is thus possible according to a further advantageous embodiment, at least to arrange the ring elements of the first and the second flow guide in the axial direction substantially congruent in the pipe. Thus, a substantially laminar flow can be achieved by the flow guide.

The sensor may be a hot wire sensor, a pitot tube sensor or a Kármán vortex sensor.

Other sensors suitable for measuring the mass and / or volumetric flow can also be used.

In particular, a two-wire sensor can be used as the hot wire sensor, wherein a first wire is attached to the first flow guide element and a second wire is attached to the second flow guide element. Conveniently, electrical connecting leads connected to the sensor are guided along at least one of the spokes. This can be avoided that an additional flow resistance is generated by the electrical connection lines.

According to a further particularly advantageous embodiment, an adjusting device for the stepwise adjustment of the iris diaphragm is provided, wherein with each stage an annular gap formed by two adjacent ring elements with respect to the axial direction can be covered. Thus, a substantially laminar flow can be ensured by the flow guide for each stage. This improves the measuring accuracy.

According to a further advantageous embodiment, a control is provided for the automatic adjustment of the iris diaphragm as a function of the mass flow measured with the sensor. This allows the sensor to be operated in the optimum measuring range. If the sensor measures a mass flow that is outside the optimum measurement range, the controller will automatically change the iris diaphragm to appropriately increase or decrease the average flow rate of the gas and adjust the mass flow to the optimum sensor range ,

The device according to the invention can be part of a gas meter. It is suitable both for measuring the amount of gas consumed and for detecting a, z. B. caused by a leak low, mass flow. Furthermore, the device according to the invention can advantageously be part of an internal combustion engine, for example for a motor vehicle. In this case, for example, the mass flow of a quantity of air supplied to an internal combustion engine can be measured.

Embodiments of the invention will be explained in more detail with reference to the drawings. Show it:

1 a perspective view of a device,

2 a side view according to 1 .

3 a front view according to 1 .

4 a sectional view along the section line AA in 3 .

5 a detailed view of a first flow guide,

6 a detailed view of a second flow guide,

7 a plan view of an iris diaphragm,

8th a plan view of a flow guide and

9 a sectional view along the section line AA in 8th ,

In the apparatus for measuring the mass flow shown in the figures is a generally by the reference numeral 1 designated tube of two sections 2 . 3 composed. The pipe 1 or the cuts 2 . 3 can be made of metal or plastic. With the reference number 4 is an iris diaphragm, which is between the sections 2 . 3 is held. Out 4 It can be seen that a diaphragm plane with an adjustable opening perpendicular to a tube axis or axial direction a of the tube 1 runs. With the reference number 5 is a lever called, with an opening diameter D (see 7 ) of the iris diaphragm 4 can be changed.

As in particular from the 3 and 4 can be seen, are on both sides of the iris diaphragm 4 inside the pipe 1 a first 6 and a second flow guide 7 appropriate. As in particular from the 8th and 9 can be seen, have the preferably identical design flow guide 6 . 7 concentrically arranged cylindrical ring elements 8th on, which by means of radial spokes 9 with each other and with an outer ring 10 are connected. In a designated by the reference numeral Z center (see 5 and 6 ), a sensor for measuring the mass flow of a gas is arranged. At the in 5 shown first flow guide 6 If the sensor is a hot wire sensor 11 , whose electrical connection cables 12 along one of the spokes 9 are guided.

At the in 6 shown second flow guide 7 is a pitot tube sensor in the center Z as a mass flow sensor 13 taken, which also along one of the spokes 9 is connected to a (not shown here) located outside the device measuring peripherals.

As in particular from 4 are the first 6 and second flow guide elements 7 in the axial direction a arranged so that the ring elements 8th are congruent.

As in particular from 3 it can be seen, the flow guide 6 . 7 Furthermore, be arranged so that the spokes 9 are arranged congruently in the axial direction a.

Although it is not shown in the figures, can with the lever 5 For example, be connected to an electrically operated actuator with which the lever 5 in interaction with a (not shown here) control is adjustable. The input signals for the control can be from the sensor 11 . 13 supplied signals which are proportional to that through the pipe 1 are flowing mass flow. According to a predetermined algorithm, the controller may be programmed so that the iris bend 4 gradually the between adjacent ring elements 8th formed annular gap Rs successively covers or releases until an average flow velocity in the region of the center Z in the range of a measuring sensitivity of the sensor 11 . 13 located.

LIST OF REFERENCE NUMBERS

1

pipe

2

first part

3

second part

4

iris

5

lever

6

first flow guide

7

second flow guide

8th

ring element

9

spoke

10

outer ring

11

hot wire sensor

12

electrical connection line

13

Pitot tube sensor

a

axially

D

diameter

Rs

annular gap

Z

center

Claims (14)

Device for measuring the mass flow of a gas, comprising a tube ( 1 ) with an iris diaphragm provided therein for changing a flow cross-section ( 4 ), one on one side of the iris diaphragm ( 4 ) provided first flow guide ( 6 ) and one on the one side opposite the other side of the iris diaphragm ( 4 ) provided second flow guide ( 7 ), wherein in the center (Z) at least one of the flow guide elements ( 6 . 7 ) a sensor ( 11 . 13 ) is mounted for measuring the mass flow of the gas. Device according to claim 1, wherein the tube ( 1 ) from a first ( 2 ) and a second section ( 3 ), and the iris diaphragm ( 4 ) between the two sections ( 2 . 3 ) is attached. Device according to one of the preceding claims, wherein the first flow guide ( 6 ) of a plurality of concentrically arranged first cylindrical ring elements ( 8th ), and the second flow guide ( 7 ) is formed of a plurality of concentrically arranged second cylindrical ring elements. Device according to one of the preceding claims, wherein the first cylindrical ring elements ( 8th ) by means of radially extending first spokes ( 9 ) on a first outer ring ( 10 ) of the first flow guide element ( 6 ) are held. Device according to one of the preceding claims, wherein the second cylindrical ring elements by means of radially extending second spokes on a second outer ring of the second flow guide ( 7 ) are held. Device according to one of the preceding claims, wherein the first ( 6 ) and the second flow guide ( 7 ) are executed identical. Device according to one of the preceding claims, wherein at least the ring elements ( 8th ) the first ( 6 ) and the second flow guide elements ( 7 ) with respect to an axial direction (a) of the tube (FIG. 1 ) substantially congruent in the tube ( 1 ) are arranged. Device according to one of the preceding claims, wherein the sensor is a hot-wire sensor ( 11 ), a pitot tube sensor ( 13 ) or a Karman vortex sensor. Device according to one of the preceding claims, wherein as a hot wire sensor ( 11 ) is a two-wire sensor, wherein a first wire on the first flow guide ( 6 ) and a second wire on the second flow guide ( 7 ) is attached. Device according to one of the preceding claims, wherein with the sensor ( 11 . 13 ) connected electrical connection lines ( 12 ) along at least one of the spokes ( 9 ) are guided. Device according to one of the preceding claims, wherein an adjusting device ( 5 ) for the stepwise adjustment of the iris diaphragm ( 4 ) is provided, with each stage by a two adjacent ring elements ( 8th ) formed annular gap (Rs) with respect to an axial direction (a) of the tube ( 1 ) is coverable. Device according to one of the preceding claims, wherein a control for the automatic adjustment of the iris diaphragm ( 4 ) depending on the sensor ( 11 . 13 ) measured mass flow is provided. Gas meter with a device according to one of the preceding claims. Internal combustion engine with a device according to one of the preceding claims.

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