EP0166867A2 - Bell - Google Patents

Abstract

A bell having a mantle which is fully broken through by a plurality of gaps longitudinally and axially formed along the circumference of the mantle and dimensioned to tune the bell to a predetermined tonal frequency range.

Description

The invention relates to a bell which is made of aluminum or an aluminum alloy and in which the pitch is determined and which has a long-lasting reverberation.

Bells have been used for centuries to produce musical tones, to signal the time or to announce an event, as well as in orchestras, as a melodic percussion or puncturing musical instrument. The bells in their familiar forms actually serve as idiophonic musical instruments.

The bell can be viewed as a three-dimensional plate which, when struck, causes two-dimensional vibrations. In the course The two-dimensional vibration is formed by two node line systems, namely the system of longludinal node lines and the system of circular node lines.

The longitudinal knot line system consists of knot lines located in vertical planes, the vertical planes containing the vertical longitudinal axis of the bell (in its freely hanging position on the hanger); the node lines have an approximately identical shape to the generatrix of the bell shell. The longitudinal knot lines divide the bell mantle into 4 to 12 zones along the periphery. Of the longitudinal nodal lines, the vibrations on that nodal line have the greatest amplitude that the impact means, e.g. from the bell handle that receives the attack.

The other node line system which arises during the oscillation consists of circular node lines in planes perpendicular to the longitudinal axis of the bell along the longitudinal axis at intervals from one another, the center points of the circular node lines lying in the longitudinal axis.

At the points of the longitudinal and circular knot lines, the bell casing practically does not vibrate. The vibration moduli of the longitudinal and circular node lines are freely combined.

At the bell, the vibration with the greatest amplitude takes place at the lower edge of the bell, on the flange. The flange can be viewed as if it were the free edge of a clamped beam or plate. The vibration, the sound, emanate from the flange. In practice, the whole bell oscillates, with the exception of the clamping point, which is in the middle at the top.

The resulting tone consists of two parts. The first to appear is the beat tone, which is a single short tone with a fixed pitch and metallic sound. The bell sound is considered to be the bell sound. The impact sound stops after a short time, the decay takes place extremely quickly. The beat sound is the result of an overtone sequence, ie its subjective Basic voice. The so-called bell button, which can be identified with the designed vibration condition of the bell casing and which has the character of a polyphonic sound and sounds very slowly, sounds in front of the complete reverberation of the beat tone. This sound is composed of several components, generally the undertone, the fundamental, the third, the fifth and the upper octave, of which the undertone is the longest; the others weaken relatively quickly.

The two bell sounds have two tones; if the impact sound is largely metallic, which means numerous non-harmonic overtones, the pitch is uncertain.

The sound is softer and quieter. As a result of the gradual decay, the sound becomes clearer, the tones (overtones) decay one after the other; finally only the undertone is audible.

The sound image described here depends exclusively on the design of the bell casing; it is not influenced by the strength of the stroke nor by the composition of the bell material, since these only determine the number and strength of the overtones.

Compared to a good quality bell, the demand is made that the pitch be determined and that the reverberation time is long. From the point of view of the manufacture of the bells, there is the further requirement that the production is economical and easy to implement, with the addition of whether one produces individual pieces or series. With bells in the well-known design, the requirements mentioned cannot be met at the same time.

In the known bell types, matching the basic tone and the pitch tone is a difficult task. The main reason for this is that the bell casing swings around two node line systems, the two node line systems being practically perpendicular to one another and having a mutual effect on their surroundings. It does not exist Possibility to determine the tone composition in advance.

The pitch is mainly determined by the material and the diameter of the bell, the weight of the bell being proportional to the diameter. It is considered to be advantageous if the prescribed or desired pitch can be achieved with a bell with the smallest possible diameter and the lowest possible weight. The smallest diameter and the lowest weight can be achieved with gold as the material at a given pitch, with a larger diameter and weight the desired pitch can be achieved with silver as the basic material. Due to the high prices, neither silver nor gold can be used as raw materials.

From the point of view of the achievable low weight and a small diameter, bronze from Cu and Sn, the so-called bell bronze, then brass from Cu and Zn and a copper alloy with silicon (Cu + Si + Zn) or silicon-containing bronze can be used. These raw materials are still very expensive; their high price can be attributed to the fact that their use for a bell demands the highest purity. For example, if a few hundredths of a percent aluminum gets into the bell bronze, the reverberation times are already reduced to a third. Another shortcoming of copper alloys is that it takes an extremely long time to cast the bell, often a few months, regardless of whether the bell weighs several tons or a few kilos. It often happens that the bell that has been finished after such a long time does not give the desired tone.

One tried to produce bells from aluminum or aluminum alloys, but with the known bell constructions aluminum and aluminum alloys proved to be completely unsuitable, since bells with an even larger diameter and weight would be required to reach a given pitch than when using the conventional copper alloys.

From the standpoint of a long reverberation time is from the copper alloy the bell bronze with the Cu + Sn composition was the cheapest; the other copper alloys do not lead to the desired result. The bells made of aluminum or aluminum alloys in the known construction showed unacceptably short periods in terms of reverberation times; the sound wasn't pleasant either.

The invention solves the problem of creating a bell construction which enables the use of the relatively cheap aluminum or aluminum alloys for their production and which, as a success, allows the production of bells, either as a single piece or in series, quickly and with a significant reduction in costs . Another requirement is that the bell can be tuned in easily and quickly and that its desired pitch can be set. Furthermore, the reverberation time should be brought to a value that corresponds to or exceeds the reverberation time of the bells made from bell bronze.

The object is achieved according to the invention with a bell, the base material of which is aluminum or an aluminum alloy, and which can be characterized in that gaps are provided along the bell jacket at a distance from one another and are essentially equally spaced in the longitudinal direction of the bell.

In one embodiment of the bell according to the invention, the center lines of the column lie in the planes containing the longitudinal axis of the bell.

However, the gaps in the side view or part thereof may also be arcuate and the curvatures of the arcuate column may be in one or two directions.

In an advantageous embodiment of the bell according to the invention, the width of the column and / or the size of the distance between two columns is the same.

A design is also possible in which the width of at least one part the column and / or part of the distances between two columns is different.

It can be advantageous if the gaps have different lengths.

The bell according to the invention is explained using an advantageous exemplary embodiment, which can be seen in the drawing in a perspective view.

The outline of the bell or bell casing shown in the figure is customary. Between the flange 1 and the hanger 2 of the bell, gaps 4 are formed in the casing 3 of the bell, which in the example shown here have a shape that follows the longitudinal generatrices of the bell casing and are spaced apart along the circumference of the bell casing. The widths of the column can match, but can also be different. Similarly, the circumferential distances between the columns 4 can be the same or different. Columns 4 can begin at their ends with the hanger 2 on the same circumferential circle or on different circumferential circles, whereby the lower ends can also end at the same circumferential circle or on different circumferential circles and one or more columns 4 can also extend to the edge of the flange 1 . In addition, the column 4 - in the side view of the bell shell - can be designed in an arc shape, wherein the arc shape can be curved on one or both sides, in a wavy line. Furthermore, as can be seen from the figure, column 4 can consist of straight lines. In the embodiment shown, a total of ten gaps 4 are uniformly distributed on the circumference of the bell casing 3, the width of the webs of the bell casing 3 between the gaps 4 being greater than the gap width.

The main advantage of the bell according to the invention is that a bell with good sound properties can be made from aluminum or aluminum alloys. The material price and the time required for production are significantly reduced, which means the production costs if less. The working time from modeling to casting is only a few days instead of a few months. Orders with a short delivery time can be accepted. Small series will also be delivered within a short time. The pitch can be adjusted easily and with little tuning work; coordination is quick and accurate. The reverberation time is practically the same as that of the bells made from bell bronze and can even be set to a higher value. Good bell sound and sound can be achieved with an aluminum or aluminum alloy bell due to the relatively small diameter and light weight gaps.

The invention is not limited to large and heavy bells. The construction of the bell according to the invention results in favorable tone parameters and good economy even with small and light bells and bells.

Claims (6)

1. bell made of an aluminum alloy, with a bell casing (3), characterized in that in the bell casing (3) along its circumference spaced apart, in the longitudinal direction of the bell casing (3) extending column (4) are formed. 2. Bell according to claim 1, characterized in that the center lines of the column (4) lie in the longitudinal axis of the bell-containing planes and viewed from a point of this plane, the column (4) are rectilinear. 3. Bell according to claim 1, characterized in that the column (4) or part thereof run in an arc in the side view of the bell, wherein the arcuate column (4) can be curved in one or in two directions. 4. Bell according to one of claims 1 to 3, characterized in that the width of the column (4) and / or the size of the distance between two columns is the same. 5. Bell according to one of claims 1 to 3, characterized in that at least in part of the column (4) the column width and / or the distance between two columns is different from each other. 6. Bell according to one of claims 1 to 5, characterized in that the length of the column (4) is different.

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