Wind chime

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A metal wind chime Wchime.jpg
A metal wind chime

Wind chimes are a type of percussion instrument constructed from suspended tubes, rods, bells, or other objects that are often made of metal or wood. The tubes or rods are suspended along with some type of weight or surface which the tubes or rods can strike when they or another wind-catching surface are blown by the natural movement of air outside.

Contents

They are usually hung outside of a building or residence as a visual and aural garden ornament. Since the percussion instruments are struck according to the random effects of the wind blowing the chimes, wind chimes have been considered an example of chance-based music. The tubes or rods may sound either indistinct pitches, or fairly distinct pitches. Wind chimes that sound fairly distinct pitches can, through the chance movement of air, create simple songs or broken chords.

History

Ancient Rome

Bronze tintinnabulum, Roman, 1st century AD, British Museum. Roman wind chime (tintinabulum) flying phallus with bells.jpg
Bronze tintinnabulum, Roman, 1st century AD, British Museum.

Roman wind chimes, usually made of bronze, were called tintinnabula and were hung in gardens, courtyards, and porticoes where wind movement caused them to tinkle. Bells were believed to ward off malevolent spirits and were often combined with a phallus, which was also a symbol of good fortune and a charm against the evil eye. [1] The image shows one example with a phallus portrayed with wings and the feet of an animal, and a phallus for a tail. These additions increased its protective powers. [2]

Eastern and Southern Asia

Wind-powered bell or wind chime under temple eaves,. Banna-ji. Ashikaga, Tochigi. Japan Wind-powered bell under temple eaves,. Banna-ji. Ashikaga, Tochigi.jpg
Wind-powered bell or wind chime under temple eaves,. Banna-ji. Ashikaga, Tochigi. Japan

In India during the second century CE, and later in China, extremely large pagodas became popular with small wind bells hung at each corner; the slightest breeze caused the clapper to swing, made in bronze too, producing a melodious tinkling. It is said that these bells were originally intended to frighten away not only birds but also any lurking evil spirits. Wind bells are also hung under the corners of temple, palace and home roofs; they are not limited to pagodas. [3] Japanese glass wind bells known as fūrin (風鈴) have been produced since the Edo period, [4] and those at Mizusawa Station are one of the 100 Soundscapes of Japan. Wind chimes are thought to be good luck in parts of Asia and are used in Feng Shui.

Wind chimes started to become modernized around 1100 C.E. after the Chinese began to cast bells. A bell without a clapper, called a yong-zhong, was crafted by skilled metal artisans and primarily used in religious ceremonies. Afterwards, the Chinese created the feng-ling( 風鈴 ), which is similar to today's modern wind bell. Feng-lings were hung from shrines and pagodas to ward off evil spirits and attract benevolent ones. Today, wind chimes are common in the East and used to maximize the flow of chi, or life's energy.

Sounds and music

Wind chime with the audible tones a1-d2-f2-g2-a2-d3-f3-a3. The bamboo cylinder is not only the case of the instrument, but at the same time it is the resonator. The eight tones are produced by eight metal rods within the cylinder which are centrally struck by a disk attached to the cord with the wind sail. Windglockenspiel.Koshi.jpg
Wind chime with the audible tones a1-d2-f2-g2-a2-d3-f3-a3. The bamboo cylinder is not only the case of the instrument, but at the same time it is the resonator. The eight tones are produced by eight metal rods within the cylinder which are centrally struck by a disk attached to the cord with the wind sail.

Chimes produce inharmonic (as opposed to harmonic) spectra, although if they are hung at about 2/9 of their length [5] (22.4% [6] [7] ), some of the higher partials are damped and the fundamental rings the loudest. [7] This is common practice in high-quality wind chimes, which are also usually hung so the centre ball strikes the centre of the wind chime's length, also resulting in the loudest sounding fundamental. [7] Frequency is determined by the length, width, thickness, and material. There are formulas [7] that help predict the proper length to achieve a particular note, though a bit of fine tuning is often needed.

Most chimes employ pentatonic or tetratonic scales as the basis for the pitches of their individual chimes as opposed to the traditional western heptatonic scale. This is largely due to the fact that these scales inherently contain fewer dissonant intervals, and therefore sound more pleasant to the average listener when notes are struck at random.

In instruments such as organ pipes, the pitch is determined primarily by the length of the air column, because it is the resonance of the air column that generates the sound. The pipe material helps determine the "timbre" or "voice" of the pipe, but the air column determines the pitch. In a wind chime, the vibrations of the pipe itself radiate the sound after being struck, so the air column has little to do with the pitch being produced.

Sound can be produced when the tubes or rods come in contact with a suspended central clapper in the form of a ball or horizontal disk, or with each other.

Wind chimes may be used to observe changes in wind direction, depending on where they are hung when they commence to sound.

Materials

A close-up of metal rods on a wind chime. Chime closeup.jpg
A close-up of metal rods on a wind chime.

Wind chimes can be made of materials other than metal or wood and in shapes other than tubes or rods. Other wind chimes materials include glass, bamboo, shell, stone, earthenware, stoneware, beads, keys and porcelain. [8] More exotic items, such as silverware or cookie cutters, can also be recycled to create wind chimes. [9] The selected material can have a large effect on the sound a wind chime produces. The sounds produced by recycling objects such as these are not tunable to specific notes and range from pleasant tinkling to dull thuds. The sounds produced by properly sized wind chime tubes are tunable to notes. [7] As aluminum is the common metal with the lowest internal damping, wind chimes are often made from aluminum to achieve the longest and loudest sounding chime.

The tone depends on factors such as the material, the exact alloy, heat treatment, and whether a solid cylinder or a tube is used. If a tube is used, the wall thickness also affects the tone. Tone may also depend on the hanging method. The tone quality also depends on the material of the object that is used to hit the chimes.

With clay wind chimes, the higher the final firing temperature, the brighter and more ringing the resulting tone. Earthenware clay fired at lower temperatures produces a duller sound than stoneware clay fired at higher temperatures. Stoneware wind chimes are also more durable and able to resist stronger winds without suffering chipping or damage.

Mathematics of tubular wind chimes

The mode 1 (lowest frequency) vibration of a free Euler-Bernoulli beam of length 1 Free-Free Euler-Bernoulli Beam animation.gif
The mode 1 (lowest frequency) vibration of a free Euler–Bernoulli beam of length 1

A wind chime constructed of a circular tube may be modelled as a freely vibrating Euler–Bernoulli beam [10] and the dominant frequency in cycles per second is given by:

where L is the length of the tube, E is the Young's modulus for the tube material, I is the second moment of area of the tube, and μ is the mass per unit length of the tube. Young's modulus E is a constant for a given material. If the inner radius of the tube is ri and the outer radius is ro, then the second moment of area for an axis perpendicular to the axis of the tube is:

The mass per unit length is:

where ρ is the density of the tube material. The frequency is then

where W=ro-ri is the wall thickness and D is the average diameter D=ro+ri. For sufficiently thin-walled tubes the W2 term may be neglected, and for a given material, the main frequency is inversely proportional to L2 and proportional to the diameter D.

For the main mode of vibration, there will be two nodes on the tube, where the tube is motionless during the vibration. These nodes will be located at a distance of 22.416% of the length of the tube from each end of the tube. If the tube is simply supported (not clamped) at one or both of these nodes, the tube will vibrate as if these supports did not exist. A wind chime will give the clearest and loudest tone when it is hung using one of these node points as the attachment point. These attachment points are also the same as used by other similar instrument such as the xylophone and glockenspiel.

Use in music

David Sitek with a wind chime suspended from his guitar. Sitek wind chimes.jpg
David Sitek with a wind chime suspended from his guitar.

Different types of wind chimes have also been used in modern music and are listed as a percussion instrument. The following is a brief list of artists and composers who have used them:

Influence

Wind chime images

See also

Related Research Articles

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References

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  2. "Bronze phallic wind chime (tintinabulum)". British Museum.
  3. Westcott, Wendell (1970). "Chapter 1: Bells of the Orient". Bells and Their Music. G.P. Putnam. LCCN   76077762.
  4. Amano, Kenichi; Kawakami, Takashi (May 28, 2007). "Foreign tourists find real Tokyo". The Nikkei Weekly.
  5. Sethares, William A. (2005). Tuning, Timbre, Spectrum, Scale, p.115. ISBN   9781846281136.
  6. "Physics of Music: Make your own wind chimes". Michigan Tech. Michigan Tech. 2009-01-08.
  7. 1 2 3 4 5 "Giant, Ominous Wind Chimes". Milwaukee Makerspace. 2011-09-29.
  8. "Wind chimes". Virginia Tech Multimedia Music Dictionary. Virginia Tech. 2009-01-08.
  9. MacKenzie, Peggy (August 25, 2007). "Crafted silver chimes hit right note; Retooled cutlery the meat and potatoes of woman's successful small business". The Toronto Star. pp. H05.
  10. Hite, Lee. "Say it with Chimes" . Retrieved 2016-08-01.
  11. Anderman, Joan (October 15, 2008). "Connecting with TV on the Radio". The Boston Globe. pp. B07.