DE8124270U1 - MECHANICAL-ELECTRIC CONVERTER FOR MEASURING PRESSURE IN A FLOW FIELD - Google Patents

Description

* · 7220

July 3, 1981 Bt / Thu

ROBERT BOSCH GMBH, 7OOO Stuttgart 1

Mechanical-electrical converter for measuring a pressure i

in a flow field J

; State of the art

The invention is based on a mechanical-electrical
Transducer for measuring a pressure in a flow field,
especially in the intake duct or in the fuel line
an internal combustion engine, according to the genre of the main claim.

From DE-OS 28 42 140 a pressure transducer is known, der- jj

a corrugated membrane made of magnetically non-conductive material |

having. A permanent magnet is attached to this membrane, |

facing a second permanent magnet, the one I

same polarity on opposite end faces |

exhibit. There is a Hall element between the two magnets

ment provided, depending on the location of the |

Hall element prevailing magnetic induction a f

-a-, 72 2

electrical quantity supplies. This "known pressure transducer cannot enter the flow field directly, e.g. B. in the intake duct, but the pressure in prevails in the flow channel, is fed to the pressure transducer via an additional bore.

Advantages of the embodiment

The pressure transducer according to the invention with the characterizing features of the main claim now has the advantage over this that the pressure is measured directly in the flow field. It is particularly advantageous to use amorphous metal for the spring element, as amorphous metals have a very high permeability and have a high tensile strength. Therefore, amorphous metal is especially for Suitable for spring steels. Furthermore, due to the special material composition, the temperature coefficient is amorphous Metal very little.

Further advantageous designs and improvements are specified in the subclaims. Through special training An arbitrary magnetic field distortion can be caused by the counterpart, so that an arbitrary context is adjustable between pressure and electrical measured variable.

drawing

Embodiments of the invention are shown in the drawing and explained in more detail in the description below. 1 shows a first exemplary embodiment in which a coil is provided as a magnetic field-dependent sensor Fig. 2 shows a special embodiment of the counterpart and Fig. 3 shows a second embodiment with a Hall element as a magnetic field dependent sensor.

Description of the exemplary embodiments

The pressure transducers shown schematically in FIGS. 1 to 3 are particularly suitable for measuring dynamic pressure for measuring fuel or air volume. In FIG. 1, the flow channel, which can be the intake channel or the fuel line of an internal combustion engine, is denoted by 1. A spring element 2, which is designed as a leaf spring, is fastened in or on the wall of the flow channel 1 in such a way that it can oscillate freely within the flow channel 1, where the broad side of the leaf spring-like spring element 2 is the direction of flow indicated by the arrows opposed to the flowing medium. The spring element consists of amorphous metal, ie a metal which, after being heated, has been subjected to extremely rapid cooling and has therefore retained its amorphous state. This amorphous metal is magnetically conductive and also has a very high permeability (Uc _r % 200,000). In addition, amorphous metal has a high tensile strength, so that it is particularly suitable for the spring element 2. Outside the flow channel 1, a counterpart 3 "is the spring element 2 also made of magnetically conductive Mate () rial, opposite. The counterpart 3 and the spring element 2 are connected via a bracket 4 made of magnetically conductive material and which extends outside the flow channel 1. Integrated into the bracket 4- or attached to the bracket 4- is a permanent magnet 5 which builds up a magnetic field over the bracket 4-, the counterpart 3, the air gap between the counterpart 3 and spring element 2 and the spring element. A coil 6 is arranged around the permanent magnet 5 as a magnetic field-dependent sensor. When the pressure in the flow field changes, the position of the spring element 2 changes. The magnetic flux through the coil changes and thus the coil inductance of the coil 6 also changes. The electrical signal emitted by the coil 6 then corresponds to the changed pressure in the flow field.

7220

In Fig. 2 is a detail with the spring element 2 and the counterpart 3 shown. The counterpart can have any shape and suspension. Due to the special Shaping as it z. B. is indicated in Fig. 2 for the counterpart 3, a certain field distortion is caused. In this way, any curve between pressure and measured variable can be produced.

In the cases of FIGS. 1 and 2, the counterpart 3 is outside of the flow channel 1. It is also possible to use the counterpart j> to let into the flow channel. Included can e.g. B. the counterpart 3 to the spring element may be designed to overlap.

A further exemplary embodiment is shown in FIG. 3, a Hall element 7 serving as a magnetic field-dependent sensor. As in FIG. 1, the spring element is attached to or in the wall of the flow channel 1. Two counterparts are let into the flow channel A , the spring element being arranged between the two counterparts 3. The counterparts 3 are each connected to a pole of a permanent magnet, with guide plates 9 ″ being attached to the magnet 8. The guide plates 9 lead to the spring element 2 and are magnetically connected to one another via the Hall element 7 If the pressure in the flow channel 1 changes, the magnetic flux through the Hall element 7, which then emits an electrical signal dependent on the magnetic flux, changes in turn. The permanent magnet 8 can also be integrated directly in the wall of the flow channel 1.

ti ■ · ■ «,

_e _ 7220

July 3, 1981 Bt / Thu

ROKEET BOSCH GMBH, 7000 Stuttgart 1

Mechanical-electrical converter for measuring a pressure in a flow field

summary

A mechanical-electrical wander for measuring a pressure in a flow field of a flow channel, in particular in the intake channel or the fuel line of an internal combustion engine _; Suggested · The transducer has at least one spring element that can be acted upon by the pressure to be measured, a magnetic field-dependent sensor and a magnet system. The magnetic field of the magnetic system delivers an electrical variable that changes depending on the pressure at the output of the magnetic field-dependent sensor. The spring element is arranged directly in the flow channel and consists of amorphous metal.

Claims (1)

R. 72 2 0 3.7.1981 Bt / Thu ROEERT BOSCH GMBH, 7000 Stuttgart 1 Expectations 1. Mechanical-electrical converter for measuring a pressure in a flow field, in particular in the intake duct or the fuel line of an internal combustion engine, with at least a spring element that can be acted upon by the pressure to be measured, with a magnetic field-dependent sensor and with a magnet system whose magnetic field at the output of the magnetic field-dependent sensor is a function of the Pressure supplies changing electrical quantities, characterized in that the spring element (2) is located directly in the flow channel (1), in particular in the intake duct or in the fuel line, is arranged and made of amorphous metal consists. 2. Converter according to claim 1, characterized in that the spring element (2) faces at least one counterpart (3), wherein the counterpart (3) is connected to the spring element (2) in a magnetically conductive manner. ο β " ² " 72 2 3. Converter according to claim 2, characterized in that the Counterpart (3) is arranged outside the flow channel (1) 4. Converter according to claim 2, characterized in that the counterpart (3) is arranged within the flow channel _B 5. Converter according to claim 2 or claim 4, characterized in that that the counterpart (3) and the spring element (2) overlap each other 6. Converter according to one of claims 1 to $, characterized in that that the counterpart (3) is shaped in such a way that the distance between the counterpart (3) and the spring element (2) is a function of deflection. 7. Converter according to one of claims 1 to 6, characterized in that that the magnet system (5, 8) is integrated in the flow channel (1). 8. Converter according to one of claims 1 to 7> characterized in that that the counterpart (3) made of a material with a permeability much greater than 1 is.