DE2944819A1 - METHOD AND DEVICE FOR INITIATING ULTRASOUND IN ELECTRICALLY CONDUCTIVE MATERIAL - Google Patents

Description

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Method and device for introducing ultrasound into electrically conductive material

The invention relates to a method for introducing electromagnetically generated ultrasound in electrically conductive material.

The invention also relates to an ultrasound-damped electromagnet which, like the method, is intended to do so is mainly used to carry out non-destructive tests in electrically conductive material by means of electromagnetic generated ultrasound to be used.

With electromagnetic ultrasonic testing, ultrasound is converted into an electrically conductive material without contact a strong magnetic field, which is generated by an electromagnet and in which a transmitter coil is provided, which is fed with electricity of ultrasonic frequency.

An ultrasonic wave introduced and reflected in the material is received by means of a receiver that also has an electromagnet that generates a strong magnetic field generated in which a receiving coil is provided. A signal is generated in the receiving coil when the signal to be tested Material vibrates in the magnetic field of the receiver.

When currents flow through a transmitter coil and into the test material, they exert forces on the transmitter's electromagnet off, especially in the core of the magnet. This introduces ultrasound into the core. The ultrasound is sent to the Boundary surfaces of the core reflect, with the result that it takes a relatively long time for the ultrasound

030020/0866

BATH ORIGINAL

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has completely subsided. The magnetic field generated by the transmitter's electromagnet vibrates as a result in the same way, and therefore the magnetic field induces a voltage corresponding to the variations in the receiving coil. This creates a disturbance in the receiving coil, which significantly worsens the reception conditions.

In certain cases, the core of the receiver's electromagnet can also begin to vibrate, which additionally causes the Interferes with reception conditions.

The invention is intended to reduce these disturbances or to eliminate them entirely.

The method according to the invention results from claim 1, and the device according to the invention results from the claim

If electromagnetic ultrasound with a non-magnetic Test material is used, the signal / interference ratio is unfavorable, which makes it even more difficult find or record a received ultrasonic echo.

An example of the application of the invention is the display of defects in workpieces or products made of steel, which are heated to a temperature above the Curie temperature.

The invention offers significant advantages through improved reception conditions, which of course also in the case of magnetic Test material to be improved.

030020/0860

BATH ORIGINAL

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The invention thus relates to a method and a device primarily for carrying out a non-destructive Testing in electrically conductive material with the help of electromagnetically generated ultrasound. When an ultrasonic pulse emitted from a coil placed in the magnetic field of an electromagnet are ultrasonic waves generated in the core as a result of currents in the transmitter coil and the test material, causing both the core as well as its magnetic field vibrate at ultrasonic frequency. Such a vibrating magnetic field is disturbing a receiving coil.

According to the invention, a core is proposed which consists entirely or partially of a composite material which is in the consists essentially of solid particles of magnetic material and an elastic binder. This composite material has a strong dampening effect on the ultrasound. According to one embodiment, at least the outer Part of each pole piece of the core is made from the composite material. According to another embodiment is the whole core made of composite material. According to a preferred In the exemplary embodiment, the composite material consists essentially of iron powder and an epoxy resin.

Embodiments of the invention are described below with reference to the drawing.

Fig. 1 shows schematically an electromagnetic test arrangement with an embodiment of the invention,

Fig. 2 shows a core for an electromagnet according to a first embodiment,

3, 4, 5 show cores according to other exemplary embodiments.

C30020 / 08G8

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29U819

In Fig. 1 there are two electromagnets ^ 1, 2 with associated windings 3, 4 shown. The first electromagnet 1 is used to transmit a strong magnetic field Generate ultrasonic signal by means of a transmitter coil 5. The second electromagnet 2 is used to create a strong magnetic Generate field for receiving an ultrasonic echo by means of a receiving coil 6.

In this exemplary embodiment, the windings 3, 4 of the electromagnets I ₁ 2 are fed via conductors 7 from the same generator arrangement, not shown. The transmitter coil is fed via the conductor 8 from a generator, not shown, which generates the ultrasonic frequency. The receiving coil 6 is connected to amplifiers and detection circuits via conductors 9. In short, the function of this electromagnetic test arrangement is as follows:

The electromagnets 1, 2 are activated, whereupon an im essentially sinusoidal ultrasonic pulse is passed from the generator to the transmitter coil 5. The current in the transmitter coil induces a correspondingly variable current in the surface of the test material 10. There is a magnetic one in a conductor Field B exists and at the same time a current 1 flows in the conductor, i.e. in the test material, is applied to the Head of a force F, the so-called Lorentz force exerted as is expressed as follows:

F = IxB,

2
where 1 has the dimension A / m and B has the dimension Tesla.

In this case, the force oscillates at an ultrasonic frequency, whereby elastic ultrasonic waves are introduced into the test material will.

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When the ultrasonic waves arrive at the receiver, it becomes a corresponding one according to Faraday's law of induction electrical signal generated in the receiving coil, which is in a magnetic field of the second electromagnet is arranged.

In known devices of this type, vibrations occur at an ultrasonic frequency in the core of the electromagnet 1 of the Transmitter due to currents in the transmitter coil 5 and in the test material 10. That generated by the core magnetic field also oscillates, and thereby this magnetic field induces a voltage with corresponding Variations in the receiving coil 6.

In Fig. 1, the two electromagnets are relatively tight shown arranged side by side. However, the distance between them is within normal limits for such test devices not essential to eliminating the aforementioned problems.

The core 11 of the first electromagnet 1 in FIG. 1 is, as will be described below with reference to FIG. 2, formed, whereby the problems mentioned are eliminated.

In Fig. 2 is a core 11 according to the first preferred embodiment with the yoke 12 and legs 13, 14 layered, for example. The outer part of each pole piece of the core 11 consists of a part 15, 16 made of a material that has a high damping effect on ultrasound exercises. This material 15, 16 is a composite material that consists essentially of small solid particles of magnetic material surrounded by an elastic binder are. Such a composite material has a strong

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Damping effect on ultrasound. The binder in the Composite material consists of a material that will readily direct the ultrasound from the core into the parts 15, 16, preferably made of an epoxy resin such as that sold under the registered trademark "Araldite". The solid particles are preferably made of iron powder, which maintains good magnetic permeability can be.

Through the parts 15, 16 ultrasound, which is introduced into the core, is directed against the boundary surfaces of the core reflects and flows into parts 15, 16 because of the good Ultrasonic contact. However, the ultrasonic waves are attenuated in the parts 15, 16, and therefore only a lot flows small part of the ultrasound that has arrived in these parts back into the nucleus 11. The result is thus, iaß ultrasound introduced into the core is quickly decayed.

Another advantage of the damping material is that the elastic binding agent is an electrical insulator, thereby preventing the formation of eddy currents.

According to a second embodiment of the invention, the is shown in Fig. 3, the yoke also has a part made of the material mentioned, which is partially used to to dampen the introduced ultrasound, and partly to enlarge the magnetic cross-section of the yoke.

According to a third exemplary embodiment shown in FIG. H , the outer walls 17 of the entire magnetic core 11 consist of the aforementioned ultrasound-damping material.

030020/0866

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2 9 A A 8

This last-mentioned embodiment causes a greater attenuation of introduced ultrasound than that Embodiments according to FIGS. 2 and 3.

In the above embodiments, the core is designed so that the damping material has a thickness of 1 to 20 mm, preferably 3 to 5 mm. The thickness must, however, depend on the strength of the magnetic fields and the strength of the Ultrasonic signals are adapted.

According to a further preferred exemplary embodiment, which is shown in FIG. 5, the entire core 18 is made from the aforementioned damping material. In this embodiment, the core is preferably made of a material composed of iron powder of 2 or more sizes and the aforesaid elastic binder. By using iron powder of different sizes, a higher iron content is achieved in the core. The magnetic saturation limit of the core is up to 70 % of the saturation limit of a conventional core.

In addition to the several exemplary embodiments described, further exemplary embodiments are conceivable, for example a core which consists of iron lamellas, which by said damping material are interconnected, or a core, which consists of iron rods, through the said material are connected to each other.

In most cases it is sufficient to have the electromagnet 1 of the transmitter with a core 11, 18 according to the invention to provide. In some cases, however, it is necessary or advantageous to also use the electromagnet 2 of the receiver to be provided with a core according to the invention.

030020/0 863

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The advantages of the invention are significant because interference in reception caused by the core 11, 18 of the electromagnet of the transmitter are generated, significantly reduced or eliminated entirely, with the formation of eddy currents at the same time is prevented.

The invention is not restricted to the exemplary embodiments described. The composite material can e.g. another solid magnetic material and another elastic binder.

Q30020 / 086S

Claims (7)

PATENT LAWYERS HELMUT SCHROETER KLAUS LEHMANN DIPL.-PHYS. DIPL.-INC. STUDSVIK ENERGITEKNIK FROM no-en-12 L / Bi. Method and device for introducing ultrasound into electrically conductive material PATENT CLAIMS Method for introducing electromagnetically generated ultrasound into electrically conductive material at Non-destructive testing, in which a magnetic field is generated and a coil with a pulse of ultrasonic frequency is fed, characterized in that that the magnetic field is generated with the help of an electromagnet, which is damped against ultrasound Has magnets which is wholly or partially made of a composite material that is substantially consists of solid particles of magnetic material and an elastic binder. 2. Electromagnet damped against ultrasound, in particular intended for use in devices for implementation non-destructive tests in electrically conductive material with the help of electromagnetically generated ultrasound, with a core and a winding, characterized in that the core (11, 18) is entirely or made partially of composite material consisting essentially of solid particles of magnetic Material and an elastic binder. D-7070 SCHWABISCH GMÜND H; Fm4iWAmE ACCOUNTS: D-βΟΟΟ MÜNCHEN 7O Telephone: (07171) 56 90 Deutsche Bank AC Postal checking account K. LEHMANN Telephone: (089) 7252071 H. SCHROETER Telegrams: SitutH'pat Munich 70/37 369 Munich Lipowskyitrillc 10 Telegrams: Schrotpal Uodisgauc 49 Telex: 7 241868 pagd d (BLZ 7OO7OOIO) 167941-804 Tel «: 5 212 24t pjw« d - 2 - no-en-12 294A819 3. Electromagnet according to claim 2, characterized in that the composite material is substantially consists of iron powder and an epoxy resin. 4. Electromagnet according to claim 2 or 3, characterized in that at least part of the Core (11), which is the outer part of each pole piece (15, 16), is made of the composite material. 5. Electromagnet according to claim 2, 3 or 4, characterized in that the outer walls (17) of the entire core (11) consist of the composite material. 6. Electromagnet according to one of claims 2 to 5, characterized in that the core (11) is designed is that the composite material has a thickness of 1 to 20 mm, preferably 3 to 5 now. 7. Electromagnet according to one of claims 2 to 5, characterized in that the entire core (18) consists of a composite material comprising two or more sizes of iron powder and a binder.