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The Science Behind Wind Chimes
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History
A
number of cultures throughout history have enjoyed the pleasing sounds
of wind bells and wind chimes. Widespread use of wind chimes can be
traced to ancient China.
The
Chinese became excellent metal workers, particularly in refining iron,
around the year 1000 B.C. They began producing wind bells at this time
for ritual ceremonies.
The
use of wind chimes spread to Japan around 400 B.C. The Japanese used
these chimes in Buddhist temples as well as in home gardens.
The Japanese produced a bronze wind bell called dotaku. They later developed a smaller and lighter wind chime called the furin, made from glass, metal or ceramics. The furin chimes were often hand painted.
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The wind chimes enjoyed by
western cultures today are typically made from rods of varying lengths
suspended from a rack. This design became popular in the 19th
century. This design is partly due to a musician who sought to improve
the tone of the bells he played in an orchestra. Entrepreneurial
Victorians, remembering the Japanese furin, popularized this design.
Author’s Wind Chime
The
wind chime model is “Cavernous Echoes” by Majesty Bells, as shown in
the image at the top of the page. The vendor’s brochure states that
this is a five note wind chime hand-tuned to the scale of E. The
material is anodized aluminum. The outer diameter is 1.25 inch. The
chimes are hollow, with a wall thickness of 3/32 inch. The
boundary condition is essentially free-free for vibration calculations.
The condition is open-open for acoustic frequency.
The chimes have three wooden parts, which are from top to bottom: the head, the striker, and the wind catcher.
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Experiment
Assume
that the wind chimes have three types of possible responses as shown
in Table 1. Furthermore, each type has higher modes. One of the
objectives is to determine which mode type or types produce the
chimes pleasing sound. The natural frequencies are calculated using
textbook formulas.
In
addition, the chimes also have a ring frequency corresponding to a
breathing mode. This frequency is 50,540 Hz for each chime, since the
chimes have a common diameter. This frequency is well above the upper
frequency limit of human hearing, however.
The
wind chimes were excited separately using the striker. The resulting
responses were due to the bending modes in each case. Note that the
bending mode is the only type in Table 1 that has non-integer
harmonics, however. In this sense, wind chimes are atonal.
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Frequency Response Data
The response data is summarized in Table 2. The musical note is the nearest note to the measured frequency.
The
sequence: E, F#, G#, A, B, represents the first five tones of the E
major scale. The complete E major scale contains this sequence plus C#
and D#.
The second natural frequency of each chime represents a note in the E scale, as shown in Table 2.
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Table 1. Wind Chime Fundamental Frequencies
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Chime
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Length
(inch)
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Vibration
Bending
(Hz)
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Vibration
Longitudinal
(Hz)
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Acoustical
Longitudinal
(Hz)
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1
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34.69
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238
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2832
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194
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2
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32.56
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271
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3017
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207
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3
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30.69
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305
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3201
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219
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4
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29.94
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320
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3281
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225
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5
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28.19
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361
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3485
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238
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Table 2. Measured Frequencies and Nearest Musical Notes
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Chime 1
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Chime 2
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Chime 3
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Chime 4
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Chime 5
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Freq (Hz)
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Note
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Freq (Hz)
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Note
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Freq (Hz)
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Note
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Freq (Hz)
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Note
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Freq (Hz)
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Note
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244
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B
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278
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C
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312
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D
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330
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E
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371
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F#
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663
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E
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753
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F#
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850
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G#
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890
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A
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1000
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B
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1272
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D#
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1441
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F#
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1625
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G#
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1700
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G#
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3031
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F#
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2050
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C
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2314
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D
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2600
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E
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2712
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D#
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4351
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C#
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Sound Files
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Waterfall Plots
Waterfall plots for each of the five chimes are given in Figures 1 through 5, respectively. The vertical axis is the Fourier transform magnitude, which has an arbitrary scale factor. Each axis scale is linear.
The
corresponding frequencies for each chime are given in the accompanying
tables. The calculated frequency is the bending frequency. The
measured frequencies have reasonably good agreement for the calculated
frequency for each chime.
The waterfall plots show the relative difference in amplitude between the various natural frequencies within each chime.
The extent to which each mode is excited depends in part on the impact location of the striker against the chime.
Whether
the manufacturer considered the complexity of nodal lines when
designing the striker position is unclear.
The waterfall plots also show the how the reverberation time varies
between the natural frequencies. The fundamental frequency is the
frequency with the longest reverberation time for each chime.
The peak amplitude response, however, may occur at the second or third natural frequency for a given chime.
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Bending Mode Shapes
A geometry model of chime 1 is shown in Figure 6.
The
first through third bending mode shapes are shown in Figures 7 through
9, respectively. The mode shapes are greatly exaggerated, with an
arbitrary scale factor.
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Figure 6. Chime 1, Undeformed Model
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Figure 7. Chime 1, First Bending Mode
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Figure 8. Chime 1, Second Bending Mode
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Figure 9. Chime 1, Third Bending Mode
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TUTORIALS
Please Visit the Vibrationdata Tutorial Page to access over 200 acoustics, shock, vibration, and signal processing papers.
CONTACT INFORMATION
For questions, please contact Tom Irvine: tomirvine@aol.com
Wind chimes have come a long way since their banging, clanging days of old. Today's precision-tuned wind chimes produce a melody as inviting, sweet, and clear as the song sung by pristine waters cascading down a mountain side on a hot summer's day. That didn't happen by accident. More than an enhancement to home décor and garden yard décor, a quality wind chime is crafted using a scientific approach to achieve the best sound possible.
The lengths and placements of tubular pipes might look as though they were put together haphazardly. In reality, their placement is dependant upon where each pipe will vibrate most when struck by the clapper.
Areas of the pipe called "anti-nodes" resonate with a clearer, truer sound. These special points are found at each end of the pipe, as well as in the center. String placement is also important. Holes for the string are drilled where the pipe vibrates least. This is known as the "node of vibration."
That eye-catching wind chime hung from a tree limb to complete garden yard décor and landscape design is more than just lovely. It is a high precision instrument that joyously plays nature's song. It is conduit to feng shui philosophy, based on the invisible yet tangible presence of universal energy flowing throughout our environment.
Wind chimes sound best when tuned to the pentatonic scale, the same used as the black keys on a piano. This type scale is best for generating pleasing but random notes – like those generated by the wind. Type of material used is also important. Some materials provide a clearer sound than others. For decorative purposes, the pipes on some wind chimes are made to look like copper. Some clappers are made from metal, some from wood, or another material to produce variations of sound, different from one another.
Besides making harmonious sounds generated by the force of air current, the wood and metal used in the production of wind chimes further enhances their connection to the feng shui philosophy and the importance of elements.
A wind chime is among the most perfect gifts for Mother's Day. They also make meaningful anniversary gifts, and great personalized housewarming gifts. That is because they not only enhance home decorating and add interest to garden yard décor. They also are symbolic of harmony and peace…important elements of any relationship.
A quality set of tuned wind chimes can be found in lawn and garden stores, department stores, and some specialty shops. For your best selection and competitive pricing, however, purchase wind chimes on line.
Wind chimes…a unique and lovely way to set the tone for peace and harmony, while adding beauty and charm to your home or yard.
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