By Ina Hunt
The same structural characteristics that produce a lovely echo when music is performed can make ordinary speech nearly unintelligible. Music is an important part of most church services, but the congregation should also be able to clearly hear and understand spoken words without straining. Acoustic sound panels for churches clarify and focus tonal vibrations, making them easier for human ears to process.
Although there are European cathedrals famous for their fantastic echoes, a fine dividing line separates noise from distortion. Echoes occur when the vibrations that make waves bounce repeatedly back and forth from hard, reflective surfaces. Some buildings are fortunate to include acoustic considerations in the original plans, but many churches today are housed in structures originally designed for other uses.
Although there are European cathedrals famous for their fantastic echoes, a fine dividing line separates noise from distortion. Echoes occur when the vibrations that make waves bounce repeatedly back and forth from hard, reflective surfaces. Some buildings are fortunate to include acoustic considerations in the original plans, but many churches today are housed in structures originally designed for other uses.
Even without the advantages of computerized modeling, there have been many past attempts to correct this issue. In some churches, absorbent ash was added to pots made of clay, which were then placed near walls and in corners. This trial-and-error method took time, and ash was added or removed as needed. Other ideas included redirecting echoes by altering the interior pillars, or by incorporating grooved stone blocks.
Today, solutions range from installing carpeting in strategic areas to using high-tech electronic reverberation systems that create a variety of listening environments. Both are effective, but neither can completely solve echo or muffling problems that are actually a product of the original building design. For many structures, a mixture of methods that also emphasizes special flat baffles creates the best results.
Rather than actually eliminating or blocking certain frequencies, they absorb the excess that confuses the ear. Most construction is fairly simple. There is an inner layer of dampening material surrounded by a rigid frame, and the exterior is covered with a variety of decorative materials. Fillings are commonly made of fiberglass, insulating foam, or newer, less environmentally hazardous materials.
Their size depends the extent of the echo and distortion. Some are as small as four square feet, while others may be nearly wall-sized, and most solutions require combinations. No matter their dimensions, they allow vibrations to pass through the exterior material rather than bouncing off, and any waves that return are re-absorbed. This principle is the same one used by music studios to emphasize accuracy, and can be easily adapted to churches.
Rather than being an industrial-looking eyesore, these structures lend themselves to the type of decor perfect for houses of worship. They may mirror stain
Today, solutions range from installing carpeting in strategic areas to using high-tech electronic reverberation systems that create a variety of listening environments. Both are effective, but neither can completely solve echo or muffling problems that are actually a product of the original building design. For many structures, a mixture of methods that also emphasizes special flat baffles creates the best results.
Rather than actually eliminating or blocking certain frequencies, they absorb the excess that confuses the ear. Most construction is fairly simple. There is an inner layer of dampening material surrounded by a rigid frame, and the exterior is covered with a variety of decorative materials. Fillings are commonly made of fiberglass, insulating foam, or newer, less environmentally hazardous materials.
Their size depends the extent of the echo and distortion. Some are as small as four square feet, while others may be nearly wall-sized, and most solutions require combinations. No matter their dimensions, they allow vibrations to pass through the exterior material rather than bouncing off, and any waves that return are re-absorbed. This principle is the same one used by music studios to emphasize accuracy, and can be easily adapted to churches.
Rather than being an industrial-looking eyesore, these structures lend themselves to the type of decor perfect for houses of worship. They may mirror stain
Rather than actually eliminating or blocking certain frequencies, they absorb the excess that confuses the ear. Most construction is fairly simple. There is an inner layer of dampening material surrounded by a rigid frame, and the exterior is covered with a variety of decorative materials. Fillings are commonly made of fiberglass, insulating foam, or newer, less environmentally hazardous materials.
Their size depends the extent of the echo and distortion. Some are as small as four square feet, while others may be nearly wall-sized, and most solutions require combinations. No matter their dimensions, they allow vibrations to pass through the exterior material rather than bouncing off, and any waves that return are re-absorbed. This principle is the same one used by music studios to emphasize accuracy, and can be easily adapted to churches.
Rather than being an industrial-looking eyesore, these structures lend themselves to the type of decor perfect for houses of worship. They may mirror stained glass windows, or can be used to repeat various themes already existing on actual walls or ceilings. Unadorned, they may seem intrusive, but in most cases a properly installed group looks like part of the original surroundings.
It is possible to precisely arrange them in the best possible positions using digital analysis, but diffusion and absorption is often best measured by the most effective tool of all, human hearing. Once the best configuration has been discovered, units can be positioned permanently. Instead of preventing certain frequency ranges or cutting down the volume, they make both speech and music sound clean and clear.
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Their size depends the extent of the echo and distortion. Some are as small as four square feet, while others may be nearly wall-sized, and most solutions require combinations. No matter their dimensions, they allow vibrations to pass through the exterior material rather than bouncing off, and any waves that return are re-absorbed. This principle is the same one used by music studios to emphasize accuracy, and can be easily adapted to churches.
Rather than being an industrial-looking eyesore, these structures lend themselves to the type of decor perfect for houses of worship. They may mirror stained glass windows, or can be used to repeat various themes already existing on actual walls or ceilings. Unadorned, they may seem intrusive, but in most cases a properly installed group looks like part of the original surroundings.
It is possible to precisely arrange them in the best possible positions using digital analysis, but diffusion and absorption is often best measured by the most effective tool of all, human hearing. Once the best configuration has been discovered, units can be positioned permanently. Instead of preventing certain frequency ranges or cutting down the volume, they make both speech and music sound clean and clear.
About the Author:
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