WO1992022792A1

WO1992022792A1 - Indicator unit for testing the emitter surface of an ultrasonic oscillator

Info

Publication number: WO1992022792A1
Application number: PCT/EP1992/001314
Authority: WO
Inventors: Jürgen MORGENSTERN
Original assignee: Morgenstern Juergen
Priority date: 1991-06-11
Filing date: 1992-06-11
Publication date: 1992-12-23
Also published as: DE4119147A1; AU2319892A

Abstract

The invention concerns an indicator unit for checking whether the emitter surface of an ultrasonic oscillator, in particular one used in the medical field, is in fact emitting. The indicator unit has a casing (30), designed to be hand-held, containing a piezo-oscillator (20) which is joined on the receive side to a frontal body (22) which extends out on the receive side of the receiver surface, tapering to form at its tip a small surface (24) located outside the housing. In addition, the piezo-oscillator is connected electrically to a receiver circuit (26) which is connected in turn to an indicator (28), such as an LED or buzzer.

Description

Description: Detection device for active radiation surfaces of ultrasonic transducers

The invention relates to a detection device for actively radiating surfaces of ultrasonic transducers, in particular for transducers used in the medical field. Ultrasound devices are widely used nowadays and serve to make hidden structures recognizable in any form. In the medical field there are, for example, imaging ultrasound devices such as u. a. used by internists and gynecologists, or z. B. Cardiococographs, in which a frequency shift caused by the Doppler effect in the ultrasound echo signal is used to prove cardiac activity. Furthermore, ultrasonic devices are widely used in material testing, reference is made here to the DE book by J. and H. Krautkrämer "Material testing with ultrasound", 4th edition.

In the case of such ultrasound devices, there is a need to be able to prove whether a transmitting piezoelectric oscillator actually also emits ultrasound waves and, if it does so, whether the emitted ultrasound waves are still of sufficient intensity. A lack of ultrasound emissions or a drop in the transmitted power can have various causes, e.g. B. Piezo oscillators age, mechanical damage occurs because the transducers break when they fall or the wires become loose. During material testing, the activity of an ultrasonic vibrator is usually monitored via the entrance echo, rear wall echo or the like; the presence of the corresponding echo provides reliable information that the transmitting part of the ultrasonic testing device is still in order, but is the case with ultrasonic devices used in the medical field such a check is not possible. In the case of a cardiotocography device, for example, according to the prior art, the transducer consists of a plurality of smaller, disk-shaped individual oscillators which are connected in parallel. If a connection line to one of the individual oscillators breaks, an individual oscillator breaks or ages more than any other, this is difficult to determine in practical operation, in particular slow changes usually do not appear.

This is where the invention begins. It has set itself the task of creating a detection device for actively radiating surfaces of ultrasonic transducers, which can be used to determine whether the transducer is located directly in contact with the surface of the transducer in which the transducer is located located ultrasonic vibrator actively emits or not.

This object is achieved by a detection device with the features of patent claim 1.

This detection device is preferably designed as a hand-held device, for example in the form of a pen. The front surface of the forward body on which the acoustic coupling takes place is so small that the device can be moved back and forth over the surface of a transducer during detection. In this way, active, less active or inactive areas of the radiating surface of a transducer in which at least one ultrasonic oscillator is located can be detected. In the case of a transducer for a cardiotocograph, for example, the individual, slit-shaped ultrasonic vibrators located below can be localized on the front circular area of the transducer. If one of these oscillators broken Runaway ^¬, a radiation can no longer be on the entire circular area, but only nachwei¬ sen on a part of the circular area. If one of the ultrasonic transducers has become completely inactive, the device can no longer be used to prove it. Differences between the individual ultrasonic vibrators can be recognized by the strength of the ultrasonic signal received with the detection device, for example a deflection of an analogue measuring instrument, a light-emitting diode chain, the volume or pitch of a buzzer or the like. The detection device according to the invention thus enables a simple, practical test for transducers in which there is at least one transmitting ultrasonic oscillator. The verification can be carried out on the device itself. For the coupling, those means are used that are also used for coupling, for example gels, oils or the like. It is not necessary to move the ultrasound machine away from the installation site for the test. The test itself takes a very short time. The detection device of the type according to the invention is therefore suitable, for example, for service technicians who check ultrasound devices at certain time intervals, but also for users of such ultrasound devices who think they have found irregularities or only want to ensure that their ultrasound device is still working properly is working.

Detection devices for ultrasound are known in principle, but they serve to measure a field of an ultrasound transducer, reference is made, for example, to the US journal J. Acoust. Soc. At the. 69 (3), March 1981, S 853 "piezoelectric polymer probe for ultrasonic applications", where a hydrophone for measuring the field distribution of an ultrasonic transmitter is described. However, a handy detection device corresponding to the device according to the invention is not possible with such a hydrophone.

The detection unit can provide a simple yes-no display, but it can also give an approximate or even precise statement about the strength of the received ultrasound signal. In the first case, a threshold value is specified in the receiver circuit, the received signal reaches or exceeds this threshold value, a diode lights up or a buzzer is activated. In the second case, the receiver circuit has an analog output. A light-emitting diode connected to it lights up more or less strongly; in another embodiment, a light-emitting diode line is provided, whereby a more objective statement is already possible. Finally, an analog indicating instrument, for example a moving coil instrument, can be installed in order to give precise statements.

In a preferred embodiment, the detection device preferably has one cylindrical, elongated, in particular pin-shaped housing, on one surface of which the lead body protrudes. It is preferably no larger than a pencil; the lead body forms the tip of the pencil. The detection device is therefore very handy, can be carried anywhere and is quick to use.

It has also proven to be advantageous to design the detection device as a disposable device. An on or off switch is omitted, measures for exchanging or recharging a battery are not provided, and accordingly the detection device can be constructed very inexpensively.

Piezo crystals are preferably used as the piezo oscillator of the detection device. With them, however, the frequency is opposite. Since the ultrasound devices usually also have a predetermined frequency, for example the cardiotocographs mentioned are in the range from 1 to 2 MHz, it is proposed to design a corresponding detection device for a specific device, for example a detection device for 2 MHz. in another embodiment, the piezo oscillator of the detection device is so strongly damped that it is broadband. Furthermore, suitable as a piezoelectric oscillator of a post ^¬ pointing device according to the invention, a hydrophone in accordance with the above-mentioned U.S. Journal article, it has to have the advantage in a frequency range of 1 to 10 MHz nearly constant SENS ^¬ friendliness.

Further advantages and features of the invention emerge from the remaining claims and the following description of non-limiting exemplary embodiments, which are explained in more detail with reference to the drawing. In this show:

1 is a perspective view of a detection device of the 2-urt invention with a pin-shaped housing, which is shown in dash-dotted lines for better illustration,

2 shows an axial section through the tip of a detection device corresponding to FIG. 1, but with a film vibrator,

Fig. 3 is a sectional view similar to FIG. 2, but for an oscillator with a wedge shape and

REPLACEMENT LEAF Fig. 4 is a sectional view through the lower region of a detection device with a plug-in unit that can be optionally connected to the main device.

Fig. 1 shows a handheld device in the form of a slim, essentially cylindrical pin for the detection of actively radiating surfaces of ultrasonic transducers. It has a cylindrical, essentially disk-shaped piezo oscillator 20 made of ceramic material. On its receiving-side surface pointing downward to the left in FIG. 1, it is cemented with a truncated cone-shaped lead body 22. Starting from the surface of the piezo oscillator 20 on the receiving side, this tapers to a front surface 24 with a surface area of approximately 2 m ^2, which is considerably smaller than this and is freely accessible at the bottom. The lead body 22 is made of a cast resin.

The piezo oscillator 20 is provided with electrodes on its two end faces, these are connected to a receiver circuit 26 via lines shown in FIG. 1. This is known per se, so that it need not be discussed in more detail here. The ultrasonic pulses picked up by the piezo oscillator 20 and converted into electrical signals are amplified in the receiver circuit.

On the output side, the receiver circuit 26 is connected to a detection unit 28, which is designed here as a light-emitting diode. If it lights up, it means that the piezo oscillator has received 20 ultrasonic waves. The strength of the lighting is also a measure of the strength of the received ultrasonic vibration.

A dash-dotted line shows a housing 30, which is essentially cylindrical, in order to make the inner parts of the detection device recognizable. Its size is essentially determined by a battery 32. By choosing a smaller battery, the detection device can be made much smaller. The light-emitting diode 28 is arranged at the end opposite the front surface 24; it can also be provided at another suitable location.

An on and off switch is not provided. If the receiver circuit 26 receives a signal of a certain level in terms of input, their power section switches on automatically and a display is shown on the light-emitting diode 28. If no further ultrasound signal is then received during a predetermined time unit, for example 60 or 120 seconds, the power section of the receiver circuit 26 switches off again automatically . As a result, only a very small current is drawn from the battery 32 in the long run, which corresponds approximately to the discharge current. The battery 32 is loaded only when the power unit is switched on.

The piezo oscillator 20 in the exemplary embodiment according to FIG. 1 is designed for a fixed reception frequency, for example 2 MHz. In practical use, the active surface of a transducer to be tested is wetted with a coupling agent, for example a gel. The front surface 24 of the hand-held detection device is then brought into direct contact with the active surface of the transducer to be tested. The device is moved back and forth so that its front surface 24 sweeps over the surface of the transducer and moves away. In this way, the active and inactive areas of the tested transducer can be determined.

In the two exemplary embodiments according to FIGS. 2 and 3, the piezo oscillator 20 used in each case is broadband, so that the detection device can be used not only for ultrasound devices of one frequency, but also for different ultrasound devices. In the exemplary embodiment according to FIG. 4, a larger frequency range is achieved in that the piezo oscillator 20 and the lead body 22 are combined to form a pluggable unit 34, of which pluggable units several are available with piezo oscillators 20 with a fixed but different frequency . These exemplary embodiments are now discussed in detail:

The in turn frustoconical lead body 22 has an axial recess which is open to the receiving side of the piezo oscillator 20 and is rotationally symmetrical. Oil 34 is filled into it, on top of which the piezo oscillator 20 in the form of a PVD film is placed in such a way that air or foreign bodies are not trapped anywhere. The PVD film, which forms the piezo oscillator 20, is attached to the lead body 22 in a circular manner and on the edge outside the recess. The PVD 3-

Foil has an active area of about 1 mm in diameter, it is on the axis. For example, a piezo oscillator 20 as used in the above-mentioned. US Journal Article is known.

The lead body 22 is made of plexiglass, the speed of which is approximately twice the speed of sound in oil. The arrangement shown ensures that ultrasound waves running on the axis, which geometrically have the shortest path from the front surface 24 to the active region of the piezoelectric oscillator 20, must pass through the longest running distance in the oil. Overall, this results in focusing on the active surface of the piezo oscillator 20. The advantage of the arrangement is that the piezo oscillator used has a uniform sensitivity in the range from 1 to 10 MHz, for example.

In the exemplary embodiment according to FIG. 3, broadband is achieved by not using a piezo oscillator of constant thickness (as in the exemplary embodiment according to FIG. 1), but a wedge-shaped piezo oscillator 20. In the exemplary embodiment shown here, the main surface of the piezo oscillator 20 opposite the receiving-side surface has a conical shape. Other shapes, for example a concave design of this surface, are possible.

In the exemplary embodiment according to FIG. 4, lead body 22 and piezoelectric oscillator 20 are connected to form a plug-in unit 36. It also consists of a housing part 38 which is essentially cylindrical and has the same outer diameter as the main housing 40. A coaxial connector is arranged on a plate on the end region of the housing part 38 opposite the lead body 22 so that its central contact lies on the axis of the detection device. A corresponding socket in the part of the main housing 40 shown is assigned to this plug. The connection of plug 42 and socket 44 ensures not only an electrical but also a mechanical fastening between the plug-in unit 36 and the main housing 40. If the mechanical fastening achieved in this way is not sufficient, couplings of a suitable type, for example a screw, can be used - Or bayonet coupling can be provided.

REPLACEMENT LEAF As shown in FIG. 4, the frustoconical lead body 22 is held in an end projection of the housing part 38 and also has an axially extending guide ring with which it slidably abuts the inner wall of the essentially cylindrical housing part 38. The lead body 22 can thereby be moved in the axial direction relative to the housing part 38. It is held in the end position shown (pressed down as far as possible) by a spring body 46, which is made of foam rubber, for example. If there is excessive pressure on the lead body 22 in the upward direction, the lead body 22 springs inward. This avoids an excessive contact pressure, which could lead to damage to the transducer to be tested.

Instead of a light-emitting diode as a detection unit, other suitable detection devices can be used. It is also possible to provide a plug-in output to which an external detection device, for example a voltmeter or oscilloscope, can be connected. A charge amplifier is provided on the input side in the receiver circuit 26 and is connected to the piezo oscillator 20. In the case that a rechargeable battery 32 is used on the housing corresponding means are provided for enabling the charge to at ^¬ play, a plug contact or a receiver coil with nachgeschal ^¬ tetem rectifier.

Claims

Expectations

1. Detection device for actively radiating surfaces of ultrasonic vibrators, eg. B. vibrators used in the medical field, with a housing (30) in which a piezo oscillator (20) is arranged, which a) is connected at its receiving end to a lead body (22) which is based on the receiving end tapered towards a smaller front surface (24) projecting freely from the housing and which b) is electrically connected to a receiver circuit (26), which in turn has a detection unit (28), e.g. B. LED or buzzer is connected downstream.

2. Detection device according to claim 1, characterized in that it is designed as a hand-held device in which the required voltage supply as a battery (32), in particular a rechargeable battery, is located.

3. Detection device according to claim 2, characterized in that the hand-held device has an elongated, in particular pin-shaped housing (30), on one end surface of which the lead body (22) protrudes.

4. Detection device according to one of claims 1 to 3, characterized gekenn¬ characterized in that the lead body (22) and the piezo oscillator (20) are combined to form a plug-in unit (36) on which contacts of a first connector (42) are arranged, and that corresponding counter contacts (44) are provided in the main housing (40). ΛO

That Zvi ^¬ rule plug unit (36) and main housing (40) has a mechani¬ cal coupling, such as screw, bayonet or Steckver ^¬ bond is provided 5. Detection device according to claim 4, characterized.

6. Detection device according to claim 4 or 5, characterized in that different plug-in units (36) with piezo oscillators (20) of different frequencies are provided.

7. Detection device according to any one of claims 1 to 6, characterized labeled in ^¬ characterized in that the flow body (22) is conical, in particular truncated kegel¬ or Mason horn.

8. Detection device according to one of claims 1 to 7, characterized gekenn¬ characterized in that the front surface of the lead body (22) maximum

10 mm ² , preferably a maximum of 3 mm ² and in particular only 1 mm ² .

9. Detection device according to one of claims 1 to 8, characterized gekenn¬ characterized in that the detection unit (28) provides a display that is dependent, in particular proportional to the strength of the received ^¬ gene ultrasonic vibration, in particular that a plurality of graduated LEDs or an analog output available.

10. Detection device according to any one of claims 1 to 9, characterized labeled in ^¬ characterized in that the device designed as a hand detection device is a disposable device, not opened so after exhausting its voltage source (32) and can not be recharged.

11. Detection device according to one of claims 1 to 10, characterized gekenn¬ characterized in that an on and off device is provided which automatically activates the main part of the receiver circuit (26) when an input signal is present and switches off when for a predetermined period of time , for example 2 min, there is no input signal.

12. Method for the detection of actively radiating surfaces of ultrasonic transducers, in particular used in the medical field. Schw ter vibrator, with a detection device according to one of claims 1 to 11, characterized in that the detection device, optionally with the interposition of a coupling agent, such as oil or gel, in direct contact with the active surface of a transducer to be tested Is brought ultrasound device that this ultrasound device is put into operation and the active surface of the transducer is scanned with the detection device.