Arrangement and field device of process measurements technology

The invention claimed is: 1. An arrangement, comprising: an ultrasonic transducer; and a damping element with a longitudinal axis, which damping element connects said ultrasonic transducer with a housing- or measuring tube wall, wherein: said ultrasonic transducer has an end piece with a medium-contacting surface, from which ultrasonic signals are transferred into a gaseous or liquid medium; said damping element has at least two annular grooves and an annular mass segment arranged therebetween; said damping element has a first eigenfrequency, in which said annular mass segment executes an axial movement parallel to the longitudinal direction of said damping element; this first eigenfrequency is the highest eigenfrequency, in the case that a plurality of eigenfrequencies are present, in the case of which said annular mass segment executes an axial movement and said damping element has a second eigenfrequency, in which the annular mass segment executes a rotary movement; this second eigenfrequency is the lowest eigenfrequency, in the case that a plurality of eigenfrequencies are present, in the case of which said annular mass segment executes a rotary movement; and the ratio of the first eigenfrequency to the second eigenfrequency is less than 0.75; wherein: said damping element has at least in the region of a first of the at least two annular grooves a first average separation from the outer wall of a hollow cylindrical portion to the longitudinal axis; said damping element has at least in the region of the first of the at least two annular grooves a second average separation from the inner wall of the hollow cylindrical portion to the longitudinal axis; said damping element has in the region of the annular mass segment between the annular grooves an average length, wherein the expression 0.093 ⁢ ( r 2 - r 1 ) 1 ⁢ ⁢ mm + 0.0016 ⁡ [ ( l 3 / 1 ⁢ ⁢ mm ) - 12.5 ] 2 + 0.057 is less than 0.55, wherein the data for r 1 , r 2 and l 3 are in millimeters. 2. The arrangement as claimed in claim 1 , wherein: the ratio of the first eigenfrequency to the second eigenfrequency is less than 0.55. 3. The arrangement as claimed in claim 1 , wherein: said hollow-cylindrical portion is rotationally symmetric. 4. The arrangement as claimed in claim 1 , wherein: said ultrasonic transducer and said damping element are connected with one another by material bonding. 5. The arrangement as claimed in claim 1 , wherein: said damping element has less than five annular grooves. 6. The arrangement as claimed in claim 1 , wherein: the lengths of said at least two annular grooves in the axial direction are equally long and the length of said annular mass segment is greater than the length of one of said two annular grooves. 7. The arrangement as claimed in claim 1 , wherein: said ultrasonic transducer has terminally a bending plate, which has said medium-contacting surface, from which the ultrasonic signal is transferred into the medium, which bending plate is embodied edgewise to freely oscillate. 8. The arrangement as claimed in claim 1 , wherein: the arrangement has in a frequency range, in which the ratio of the wanted frequency f n to the first eigenfrequency f a is greater than 1.6 and in which the ratio of the wanted frequency f n to the second eigenfrequency f r is less than 0.7, no axial eigenfrequency or rotational eigenfrequency. 9. An ultrasonic, flow measuring device for measuring gaseous media, wherein the ultrasonic flow device has a measuring tube or a supply container, on which an arrangement as claimed in claim 1 is placed, said arrangement comprises: an ultrasonic transducer; and a damping element with a longitudinal axis, which damping element connects said ultrasonic transducer with a housing- or measuring tube wall, wherein: said ultrasonic transducer has an end piece with a medium-contacting surface, from which ultrasonic signals are transferred into a gaseous or liquid medium said damping element has at least two annular grooves and an annular mass segment arranged therebetween; said damping element has a first eigenfrequency, in which said annular mass segment executes an axial movement parallel to the longitudinal direction of said damping element; this first eigenfrequency is the highest eigenfrequency, in the case that a plurality of eigenfrequencies are present, in the case of which said annular mass segment executes an axial movement and said damping element has a second eigenfrequency, in which the annular mass segment executes a rotary movement; this second eigenfrequency is the lowest eigenfrequency, in the case that a plurality of eigenfrequencies are present, in the case of which said annular mass segment executes a rotary movement; and the ratio of the first eigenfrequency to the second eigenfrequency is less than 0.75.