DE102006023479A1 - Flow channel for receiving the flow sensor - Google Patents

Abstract

The invention relates to a flow channel having an opening for receiving a flow sensor, which has a first and a second sound transducer, wherein in each case a sound transducer is arranged at the end of a measuring section and is connected to a downstream evaluation, which from the duration of one of the transducers emitted and received sound wave determines the flow velocity of a fluid. In order to specify a flow channel which allows the inclusion of a compact, easily assembled flow sensor, wherein the flow sensor to deliver good measurement results even in a compact design, a sound reflector is formed in the flow channel, which directs a sound wave from one transducer to the other.

Description

The The invention relates to a flow channel with an opening for receiving a flow sensor having a first and a having second transducer, wherein in each case a sound transducer on End of a measuring section is arranged and with a downstream Transmitter is connected, consisting of the running time of a the sound transducers emitted and received the sound wave flow rate of a fluid.

Flow Sensors For example, they are called Mass Air Flow sensors in the intake system used by internal combustion engines, the intake air mass to determine and fuel the internal combustion engine accordingly to supply. The intake tract here forms the flow channel.

A flow sensor and a flow channel for receiving the flow sensor are out of the DE 33 31 519 A1 known. In the known device for measuring the flow velocity of fluids with the aid of ultrasound side sockets are formed on a flow channel, in each of which ultrasonic transducers are arranged. The ultrasonic transducers define a measuring path that runs at an angle to the flow direction. An evaluation circuit connected downstream of the ultrasound transducers determines the transit time of the ultrasound signals along the measurement path and calculates therefrom the flow velocity of the fluid in the flow channel.

One Disadvantage of the known device is that the assembly and adjustment the transducer is expensive in the nozzle of the flow channel. To the One has to make sure that the transducers are on top of each other are aligned. For another the supply lines for the sound transducers through the wall of the neck through to the outside and from there to the evaluation unit become. It must the cable strands often around the flow channel be led around to the evaluation. Because the length the measuring section between the one and the other sound transducer of high importance for the quality the measurement result is the sound transducers in as possible great distance be positioned from each other. Those known from the prior art Flow sensors based on the ultrasonic principle are relatively large and bulky Components.

outgoing From this prior art, the invention is based on the object a flow channel to create, the inclusion of a compact, easy to assemble Flow sensor allows. The flow sensor should be well measured even with a compact design walked.

These Task is through the flow channel with those in the independent Claim specified features solved. In dependent claims are indicated advantageous embodiments and developments.

If in the flow channel a sound reflector is formed, which forms a sound wave from the one Transducer deflects to the other, the flow sensor aüßerst compact be designed. Nevertheless, there is a relatively long measuring distance between the sound transducers available, so that a high-quality Messersbnis is achieved.

at An advantageous development is the sound reflector on or in the wall of the flow channel educated. Here the sound reflector influences the fluid flow least and he is easy in the production of the flow channel in or on the wall of the flow channel with educable.

at Another development is the sound reflector by means of brackets with the flow channel is connected and arranged away from the wall of the flow channel. Here it is possible the sound reflector in any position in the flow channel to position.

in the Focused frame of an advantageous embodiment of the invention the sound reflector the sound wave to at least one of the sound transducer out. This focusing effect of the sound reflector allows the Use of sound waves of lower intensity, with the measurement results in their quality be further improved.

at In another advantageous embodiment, the sound reflector compensates the blowing of the sound wave. This is very important for measuring high Flow rates, because without the drift compensation the arriving at the transducer Sound wave has a very low intensity. By the compensation drift with the help of the favorably designed surface of the reflector, can even at high flow rates the fluid a very good measurement result can be achieved.

The Sound transducers can each separate transmitter or receiver or combined Sender and receiver be. Preferably, the emitted from the transducers and received sound signals ultrasonic signals.

Further Details and advantages of the invention will become apparent from the following Description forth, in the embodiments The invention will be explained in detail with reference to the accompanying drawings. Show it:

1 a cross section through a flow sensor mounted in a flow sensor;

2 a flow sensor for determining the flow velocity of a fluid flowing in a flow channel;

3 the out 2 bekanten flow channel, the fluid flows at a much higher speed;

4 a further embodiment of the flow sensor;

5 a precise representation of the sound reflector;

6 a sound reflector, which is supported by brackets.

1 shows a cross section through a flow channel 1 , which has a side-mounted nozzle 2 with an opening 3 having. The flow channel 1 is designed here as a tube. Through the opening 3 can be a flow sensor 4 in the interior of the pipe 1 be introduced. The flow sensor 4 has a headboard 5 on, in which is a circuit board 6 located on one for operation of the flow sensor 4 required evaluation electronics 17 , the construction elements 7 comprises, is arranged. At the headboard 5 is also an electrical connection 18 attached, with the flow sensor 4 can be connected to external, not shown devices.

At the headboard 5 of the flow sensor 4 are also sidebars 9 attached after the assembly of the flow sensor 4 on the pipe 1 inside the tube 1 extend. The sidebars 9 keep sound transducer 10 and 11 that a measuring section 12 define. The measuring section 12 is at an acute angle φ to a flow direction 13 one in the pipe 1 flowing fluid 14 aligned. The angle φ between the measuring section 12 and the flow direction 13 is preferably between 40 and 45 degrees.

When operating the flow sensor 4 For example, the transducer sends 10 a first ultrasonic wave 16 out. This first ultrasonic wave is from the sound transducer 11 receive. The sound transducer 11 then sends a second ultrasonic wave 16 from the sound transducer 10 Will be received. The running time of the first and the second ultrasonic wave 16 is from a transmitter 17 determined on the circuit board 6 can be integrated or the outside of the flow sensor 4 is arranged.

The flow velocity v of the fluid 14 in the pipe 1 is apart from various disturbing effects that can falsify the measurement result, proportionately Δt / t _up t _down , where Δt is the difference of the transit times and t _up and t _down respectively the transit times in the flow direction 13 or against the flow direction 13 are. The one with 13 denoted arrow symbolizes below the flow direction and the flow velocity of the fluid 14 , From the flow velocity v of the fluid 14 can take into account the temperature on the mass of the pumped fluid 14 getting closed. So can the flow sensor 4 be used for example as air mass meter in the intake of an internal combustion engine.

With the fluid 14 it is preferably a gaseous medium, in particular air. The fluid 14 however, it may also be a liquid such as gasoline.

2 shows a flow sensor 4 for determining the flow velocity 13 one in a flow channel 1 flowing fluid 14 , The flow sensor 4 consists of a headboard 5 with a first and a second sound transducer 10 . 11 , Each of these sound transducers 10 . 11 is at the end of a test section 12 arranged and with a downstream evaluation 17 connected. The connection of the transmitter 17 with the sound transducer 10 . 11 via electrical lines 8th , The sound transducer 10 . 11 are symmetrical to the evaluation electronics 17 arranged, whereby the electrical wires 8th have approximately the same length, which has a considerable improvement in the measurement result in time measurements result, since the signals from the transducers 10 . 11 reach the measuring electronics over approximately equal distances. The measuring electronics 17 is in turn via electrical conductors 8th with an electrical connection 18 connected, which can be designed as a plug and which represents the connection to the subsequent electronics.

In the flow channel 1 opposite flow sensor 4 is a sound reflector 15 educated. For example, send the first sound transducer 10 a sound wave 16 out, it gets to the sound reflector 15 and is redirected there and on the second transducer 11 directed. The second sound transducer 11 registers the impact of the first sound wave 16 and generates a corresponding signal via the electrical line 8th to the transmitter 17 arrives. After that, the second sound transducer 11 a second sound wave 16 send out via the sound reflector 15 to the first sound transducer 10 arrives. This also registers the impact of the sound wave 16 and generates an electrical signal to that of the transmitter 17 is supplied. The measuring section 12 sets itself out of the way of the first sound transducer 10 to the sound reflector 15 and the way from the sound reflector 15 to the second sound transducer 11 and vice versa. From the measured time differences can now on the flow velocity 13 of the fluid 14 getting closed. Will the flow sensor 4 used in the intake passage of an internal combustion engine, the mass of the intake air can be determined.

Due to the structure shown here is a long measuring distance 12 feasible, wherein the flow sensor 4 can be made very compact and the sound transducer 10 . 11 can be arranged symmetrically very advantageous.

In 2 is the flow sensor 4 in its installation position in the flow channel 1 shown. In the flow channel 1 is the fluid 14 which can be a gas, in particular air. The fluid 14 flows in the flow direction and at the flow velocity, which is indicated by the arrow 13 is indicated. The flow sensor 4 is here in an opening 3 of the flow channel 1 built-in. In 2 is a relatively small flow rate through the arrow 13 indicated. In 3 is the arrow 13 much larger and stronger, which should indicate a much higher flow rate. At high flow rate 13 The phenomenon of bleeding (also called blowing) occurs in the surge wave 16 on. The sound wave 16 propagates due to atomic and molecular collisions of the fluid particles in space. If the individual fluid particles move at very high speed, the sound wave becomes 16 clearly distracted from their straight propagation direction and with the vector of flow velocity 13 transported. The propagation line of the sound wave 16 results as a vectorial superposition of the speed of sound and the flow velocity 13 of the fluid 14 , which is indicated by the slightly curved dashed lines.

By blowing the sound wave reaches 16 at high flow velocity 13 no longer the center of the sound reflector 15 , Here is a situation in which the sound wave 16 due to a very high flow rate 13 of the fluid 14 the edge of the sound reflector 15 reached. The sound reflector 15 is designed to be the sound wave 16 so distracted that despite the drifts they are the center of the first transducer 10 reached. In the illustration in 3a it was assumed that the sound wave 16 from the second transducer 11 sent out, at the sound reflector 15 reflected and to the first sound transducer 10 to be led.

4 shows a further embodiment of the flow sensor 4 , At the headboard 5 is the electrical connection 18 now attached to the side. The sound transducer 10 . 11 are located below the transmitter 17 but again symmetrical to it. The flow sensor 4 to 5 now has two sound reflectors 15 on and a third sound reflector 15 is in the flow channel 1 arranged. It is also conceivable that all three sound reflectors are arranged in the flow channel. One from the first sound transducer 10 emitted sound wave 16 first reaches the right sound reflector 15 and there is the parabolic parabolic, in the flow channel 1 arranged sound reflector 15 led the wave to the left sound reflector 15 deflects where it is deflected again then the second transducer 11 to reach. In this way, a very long measuring distance 12 realized in a very compact flow sensor 4 Takes place.

5 shows a precise representation of the sound reflector 15 , The sound reflector 15 is in the wall of the flow channel 1 integrated. Important is the shape of the surface of the sound reflector 15 , The surface of the sound reflector 15 has a curvature K _L longitudinal to the flow direction 13 and a curvature K _Q transverse to the flow direction 13 of the fluid 14 on. The curvatures K _L , K _Q can be designed such that the sound wave 16 optimally to the center of the first and second sound transducer 10 . 11 is focused. In addition, the curvatures K _L , K _{Q of} the surface of the sound reflector 15 be designed such that the drift of the sound wave 16 is compensated, so even at high flow speed 13 the sound wave 16 the center of the sound transducer 10 . 11 reached. This advantageous embodiment of the surface of the sound reflector in conjunction with the long measuring section 12 enables the generation of very high quality and accurate measurement signals.

6 shows a sound reflector with the 5 have properties for focusing and compensating for drift. The sound reflector 15 is here by brackets 19 worn with the flow channel 1 are connected. Such holders 19 allow sound reflectors 15 in almost every position in the flow channel to position.

1

flow channel

2

Support

3

opening

4

Flow Sensor

5

headboard

6

circuit board

7

module

8th

electrical ladder

9

sidebar

10

first transducer

11

second transducer

12

measuring distance

13

flow direction and speed

14

fluid

15

sound reflector

16

sound wave

17

Ausweiteelektronik

18

electrical connection

19

bracket

K _L

Curvature along

K _Q

Curvature across

Claims (5)

Flow channel ( 1 ) with an opening ( 3 ) for receiving a flow sensor ( 4 ), a first and a second sound transducer ( 10 . 11 ), wherein in each case a sound transducer ( 10 . 11 ) at the end of a measuring section ( 12 ) is arranged and with a downstream evaluation ( 17 ), the duration of one of the transducers ( 10 . 11 ) emitted and received sound wave ( 16 ) the flow rate of a fluid ( 14 ), characterized in that in the flow channel ( 1 ) a sound reflector ( 15 ) is formed, which is a sound wave ( 16 ) from the one transducer ( 10 . 11 ) to the other one. Flow channel ( 1 ) according to claim 1, characterized in that the sound reflector ( 15 ) on or in the wall of the flow channel ( 1 ) is trained. Flow channel ( 1 ) according to claim 1, characterized in that the sound reflector ( 15 ) by means of holders ( 19 ) with the flow channel ( 1 ) and from the wall of the flow channel ( 1 ) is located away. Flow channel ( 1 ) according to one of claims 1 to 3, characterized in that the sound reflector ( 15 ) the sound wave ( 16 ) to at least one of the sound transducers ( 10 . 11 ) focused. Flow channel ( 1 ) according to one of claims 1 to 4, characterized in that the sound reflector ( 15 ) the blowing of the sound wave ( 16 ) compensated.