DE102008027367B4 - Device for measuring the ultrasound emission of ultrasound devices - Google Patents

Abstract

Device for measuring the ultrasound emission of different ultrasound devices, namely ultrasound therapy transducers, wherein a piezoelectric element (5) is arranged in the device, characterized in that the device has a measuring pot (2), which is provided for receiving a coupling medium and in the the transducer to be measured is insertable from above, that the piezoelectric element (5) is arranged centrally in the bottom area (3) of the measuring pot (2), and that the measuring pot (2) has a positioning device with two exchangeable positioning elements (10, 11), which position a radiating surface of the transducer with a defined distance and parallel to the piezoelectric element (5), whereby by selecting the first positioning element (10) which is adjacent to the piezoelectric element (5) as a spacer, the distance between the transducer and the piezoelectric element ( 5), and that d the second positioning element (11) forms a cover of the measuring pot (2) with a central guide hole serving as a receiving opening so that the measuring pot (2) can be changed by changing the receiving opening, in particular by exchanging the second positioning element (11), to different transducers to be tested is adaptable.

Description

The invention relates to a device for measuring the ultrasonic radiation of ultrasound devices, for. B. of medical ultrasound therapy transducers, wherein in the device, a piezoelectric element is arranged.

Ultrasound therapy is a procedure that is used for therapy and sometimes for the treatment of pain in various indications. Ultrasound creates an inner tissue massage that promotes basal metabolism, blood flow, and better oxygenation. Therefore, ultrasound is often used to treat arthrosis, arthritis, spinal syndromes, myogelosis, achillodynia, heel spurs and other ailments. The piezo-generated ultrasound vibrations are delivered via a transducer to the human tissue. In human tissue heat is then generated by molecular vibrations, which results in increased blood circulation and thus an accelerated healing effect. Ultrasound therapy devices are used in rehabilitation and are an integral part of every physical therapy practice, orthopedic practice and orthopedics hospital department. The ultrasound heads currently in operation operate on the order of 1 MHz to 3 MHz and with output powers in the order of 5 to 50 watts. An object of the invention is to provide a device for the periodic inspection of such ultrasound devices with which the output power of the transducers can also be measured and evaluated.

An initially mentioned device is z. B. from the DE 41 19 147 A1 known. In the disclosed there detection device for ultrasound transducer used in the medical field, a piezoelectric vibrator is arranged, which is connected at its receiving side surface with a tapered lead body and which is electrically connected to a receiver circuit, in turn, a detection unit, for. B. a light emitting diode or a buzzer is connected downstream. The front region of this detection device is thereby brought into direct contact with the active surface of a transducer to be tested of the ultrasound device by interposing a coupling agent, such as oil or gel.

From the DE 28 24 629 A1 For example, a calibration device for ultrasonic inspection devices for checking tanks or nuclear reactor boilers or the like is known. Weld seams are tested with these devices. The subject of this application is the orientation and position adjustment of the ultrasonic inspection device. For this purpose, a spherical reflector is used in the reactor. Since the spherical reflector has an angle-dependent amplitude, by moving the transducer array, the ultrasonic transducer can be brought into a position in which the signal reflected by the reflector is the largest possible received signal. In this way, a calibration of the orientation of the ultrasonic inspection device for checking nuclear reactor boilers is achieved.

The US 4,989,446 A describes an arrangement for calibration of ultrasonic equipment, with which the flow rate in liquids is measured. For this purpose, an ultrasound transmitter is immersed in a reservoir filled with fluid. The ultrasound emits and receives ultrasound. The flow rate of the liquid in the channel can be measured. This measured result is compared with the known flow rate result. The overall apparatus serves, in particular, to generate a defined flow velocity in the channel, so that the flow velocity is known and can be compared with the result measured by the ultrasound generator. In this way, the ultrasonic transducer is calibrated.

Internal adjustments and calibrations within a specific device are from the WO 97/46159 A1 . EP 0 146 707 B1 . WO 2000/015115 A1 . US 6543272 B1 and US 5196343 known.

The invention is based on the object to provide a device of the type mentioned, with the most reliable and reproducible results can be achieved.

The solution of this object is achieved with a device having the features of claim 1. Advantageous developments of the invention are described in the subclaims.

In a device for measuring the ultrasound emission of ultrasound devices, in particular medical ultrasound therapy transducers, wherein a piezoelectric element is arranged in the device, it is provided according to the invention that the device has a measuring pot, which is provided for receiving a coupling medium that the piezoelectric element is arranged in the bottom region of the measuring pot, and that the measuring pot has a positioning device for positionally accurate recording of the ultrasonic device to be measured with respect to the piezoelectric element. With such a device, a precise and reproducible measurement of ultrasound devices is made possible.

In a preferred embodiment of the invention, the coupling medium is liquid, especially water. The measuring pot is therefore preferably designed so that in this the liquid medium can be received. The device therefore preferably also has a footprint and is designed overall in such a way that the measuring pot has a horizontal upper orientation when the device is placed on the footprint and the device to be measured can be inserted from above into the measuring pot. The positioning device is preferably designed in such a way that the ultrasound device to be measured is positioned with an ultrasound emitting area inside the measuring pot. This is particularly important for the ultrasound radiating area to be detected by the coupling medium. According to the invention, the positioning device has two positioning elements. In this case, a positioning element is arranged adjacent to the piezoelectric element. This is in particular formed as a disk-shaped spacer with central receiving hole. As an alternative to the disk-shaped spacer element, spacer balls or spacers can also be arranged on the bottom of the measuring pot, on which the ultrasonic device to be measured rests.

A second positioning element is arranged close to the open end region of the measuring pot and is designed as a cover with a central guide hole.

Overall, the positioning device is preferably designed so that the sound-emitting side of the transducer parallel to the piezoelectric element and at a distance of about 2 to 20 millimeters, preferably 3 to 15 millimeters, especially 4 to 10 millimeters and more preferably at a distance of 5 to 7 Millimeter is arranged. According to the invention, the positioning device is exchangeable, and in particular the first and the second positioning element are interchangeable, so that different ultrasound devices of different make and of different dimensions can be measured with the device.

The piezoelectric element is preferably part of a measuring cell. In this case, the piezoelectric element is preferably fixed on one side in the measuring cell. Alternatively, the piezoelectric element can also be accommodated in a free-floating manner in the measuring cell via lateral connections. Preferably, however, the attachment fixed on one side within the measuring cell, so that the expansion direction is essentially predetermined and tolerances are narrowed, thus minimizing sources of error and the reproducibility of the results is increased. The measuring cell is preferably arranged detachably or exchangeably in the measuring pot, so that the piezoelectric element is exchangeable with the entire measuring cell.

In a preferred embodiment of the invention, the invention is associated with an evaluation electronics, with which the measurement data, which are in the form of voltage signals, detected and evaluated. The detection or evaluation takes place via a microcontroller. The prepared voltage signals are displayed via a display as power end values.

The invention will be further explained with reference to an exemplary embodiment shown in the drawing. In detail, the schematic representations in:

1 : A plan view of a measuring pot according to the invention with arranged in the bottom region piezoelectric element.

2 a plan view of a measuring pot with inserted therein positioning device;

3 Three different examples of a first positioning of the positioning;

4 : an example of a second positioning element of the positioning device.

In 1 is a device 1 with a measuring pot 2 shown. The measuring pot 2 has a floor area 3 and walls extending substantially perpendicularly from the floor area 4 on. The measuring pot 2 is formed circular or cylindrical with bottom and forms a vessel for receiving a coupling medium, in particular a liquid. The vessel may also have other shapes, eg. B. be angular. In the area of the soil 3 of the measuring pot 2 is centrally a circular piezoelectric element 5 , which is also referred to as quartz crystal arranged. This is preferably part of a measuring cell. In the embodiment shown here is the piezoelectric element with an adhesive surface 6 directly on the ground 3 attached. The electrical contacting takes place here with a Lötkontaktierung 7 , About the cable 8th an evaluation and control unit is connected, with which the voltage signals of the piezoelectric element 5 recorded, evaluated and displayed.

In 2 is a plan view of the measuring pot according to the invention shown in the here additionally the positioning device is arranged, which in the embodiment shown from a first, ground-level element 10 , which is designed here as a spacer plate, and a second positioning element 11 exists at the open end of the measuring pot 2 is arranged and is formed here in Figure 7 as a lid with a central guide hole. The device to be measured is determined by the positioning elements 10 and 11 In a precise position to the quartz crystal 5 In particular, a front radiation surface with a defined distance and parallel to the quartz crystal is positioned 5 positioned.

Through in 3 illustrated positioning elements 10 , which are exemplified as spacer plates of different thickness, the distance between the transducer of the device to be measured and the piezoelectric element 5 be selected defined. Depending on the intensity of the transducer, ie the output power of the ultrasound therapy device, the distance between the transducer and the piezoelectric element 5 by selecting a spacer plate 10 with a certain thickness, ie by the first positioning element 10 be enlarged or reduced. The combination of the first positioning element 10 with the second positioning element 11 At the same time, this allows compliance with the parallelism of the transducer to the piezoelectric element 5 ,

In 4 is a view of the second positioning element 11 given alone. By variation of the second positioning element 11 , Especially by changing the central receiving opening, the measuring pot 2 be adapted to a variety of ultrasound equipment to be tested with little effort.

Claims (8)

Device for measuring the ultrasound emission of various ultrasound devices, namely ultrasound therapy transducers, in which device a piezoelectric element ( 5 ), characterized in that the device comprises a measuring pot ( 2 ), which is provided for receiving a coupling medium and in which the transducer to be measured is insertable from above that the piezoelectric element ( 5 ) centrally in the floor area ( 3 ) of the measuring pot ( 2 ) and that the measuring pot ( 2 ) a positioning device with two exchangeable positioning elements ( 10 . 11 ), which has an emitting surface of the transducer in positional accuracy at a defined distance and parallel to the piezoelectric element ( 5 ), wherein by selecting the first positioning element ( 10 ) which is adjacent to the piezoelectric element ( 5 ) is formed as a spacer element, the distance between the transducer and the piezoelectric element ( 5 ) and that the second positioning element ( 11 ) a cover of the measuring pot ( 2 ) forms with central, serving as a receiving opening guide hole, so that the measuring pot ( 2 ) by changing the receiving opening, in particular by replacement of the second positioning element ( 11 ), to various, to be tested transducers is adaptable. Apparatus according to claim 1, characterized in that the coupling medium is liquid, in particular water. Device according to claim 1 or 2, characterized in that the one positioning element ( 10 ) is formed as a disk-shaped spacer with central receiving hole. Device according to one of the preceding claims, characterized in that the positioning device is designed such that the ultrasound device, in particular the transducer, with a distance of 3 to 20 millimeters, in particular 3 to 15 millimeters, 4 to 10 millimeters and in particular 5 to 7 millimeters Distance to the piezoelectric element ( 5 ) is arranged. Device according to one of the preceding claims, characterized in that the piezoelectric element ( 5 ) Is part of a measuring cell. Apparatus according to claim 5, characterized in that the measuring cell is replaceable. Device according to one of the preceding claims, characterized in that the piezoelectric element ( 5 ) on one side in the measuring pot ( 2 ), in particular in the measuring cell, is fixed. Device according to one of the preceding claims, characterized in that the device is associated with an electronics for operation and evaluation of the device.

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