Difference between revisions of "Acoustic Cleaners"

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Acoustic Cleaners (view source)

Revision as of 02:59, 28 May 2012

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An acoustic cleaner consists of two parts.  
An acoustic cleaner consists of two parts.  
*The wave generator which takes the compressed air and applies it to a diaphragm. The wave generator is usually made from solid machined stainless steel. The diaphragm within the generator is the only moving part within an acoustic cleaner and there is no danger of sparking. The diaphragm is usually manufactured from special aerospace grade titanium to ensure  performance and longevity.  
*The wave generator which takes the compressed air and applies it to a diaphragm. The wave generator is usually made from solid machined stainless steel. The diaphragm within the generator is the only moving part within an acoustic cleaner and there is no danger of sparking. The diaphragm is usually manufactured from special aerospace grade titanium to ensure  performance and longevity.  
*The bell, which is usually made from spun 316 grade stainless steel. The bell is a resonance section or amplifier and it will tune and direct the sound waves.  An acoustic cleaner is powered by compressed air with an operating range of between 4.8 to 6.2 bars or 70 to 90 psi. The resultant sound pressure level will  be around 200dB.  The overall length of the acoustic cleaner will  range from between 430 mm to over 3 metres long.  There are generally 4 ways to control the operation of an acoustic cleaner.  *The most common is by a simple timer. *[[SCADA]] (Supervisory Control and Data Acquisition).  
*The bell, which is usually made from spun 316 grade stainless steel. The bell is a resonance section or amplifier and it will tune and direct the sound waves.  An acoustic cleaner is powered by compressed air with an operating range of between 4.8 to 6.2 bars or 70 to 90 psi. The resultant sound pressure level will  be around 200dB.  The overall length of the acoustic cleaner will  range from between 430 mm to over 3 metres long.  There are generally 4 ways to control the operation of an acoustic cleaner.   
*The most common is by a simple timer.  
*SCADA (Supervisory Control and Data Acquisition).  
*[[PLC Controllers]]
*[[PLC Controllers]]
*Manually by [[Ball Valves]].  An acoustic cleaner will typically sound for 10 seconds and then wait for a further 500 seconds before sounding again. This ratio for on/off is approximately proportional to the working life of the diaphragm. Provided the operating environment is between – 40  and 100 °C a diaphragm should last between 3 and 5 years. The wave generator and the bell have a much longer life span and will often outlast the environment in which they operate.  The older bells which were made from  cast iron were susceptible to rusting in certain environments. The new bells made from 316 spun steel have no problem with rust and are ideal for sterile environments such as found in the food industry or in pharmaceutical plants.  Acoustic cleaning began in the early 1970s with experiments using  ship horns or air raid sirens.  The first acoustic cleaners  were made from cast iron. From 1990 onwards the technology became commercially viable and began to be used in dry processing, storage, transport, power generation and manufacturing industries. The latest technology uses 316 spun stainless steel to ensure optimum performance.   
*Manually by [[Ball Valves]].  An acoustic cleaner will typically sound for 10 seconds and then wait for a further 500 seconds before sounding again. This ratio for on/off is approximately proportional to the working life of the diaphragm. Provided the operating environment is between – 40  and 100 °C a diaphragm should last between 3 and 5 years. The wave generator and the bell have a much longer life span and will often outlast the environment in which they operate.  The older bells which were made from  cast iron were susceptible to rusting in certain environments. The new bells made from 316 spun steel have no problem with rust and are ideal for sterile environments such as found in the food industry or in pharmaceutical plants.  Acoustic cleaning began in the early 1970s with experiments using  ship horns or air raid sirens.  The first acoustic cleaners  were made from cast iron. From 1990 onwards the technology became commercially viable and began to be used in dry processing, storage, transport, power generation and manufacturing industries. The latest technology uses 316 spun stainless steel to ensure optimum performance.   
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*Sound propagation. This relates to an understanding of the nature of the sound waves, how they vary and how they will interact with the environment.  
*Sound propagation. This relates to an understanding of the nature of the sound waves, how they vary and how they will interact with the environment.  
*Mathematics of the environment. Materials science, surface friction, distance and areas familiar to a mechanical engineer.  
*Mathematics of the environment. Materials science, surface friction, distance and areas familiar to a mechanical engineer.  
*Chemical engineering. The chemical properties of the powder or substance to be debonded. Especially the auto adhesive properties of the powder. An acoustic cleaner will  create a series of very rapid and powerful sound induced pressure fluctuations which are then transmitted into the solid particles of ash, dust, granules or powder. This causes them to move at differing speeds and debond from adjoining particles and the surface that they are adhering to. Once they have been separated then the material will fall off due to gravity or it will be carried away by the process gas or air stream.  The key features which determine whether or not an acoustic cleaner will be effective for any given problem are the particle size range, the moisture content and the density of the particles as well as how these characteristics will change with temperature and time. Typically particles between 20 micrometres and 5 mm with moisture content below 8.5% are ideal. Upper temperature limits are dependent upon the melting point of the particles and acoustic cleaners have been employed at temperatures above 1000 C to remove ash build-up in boiler plants.  It is important to match the operating frequencies to the requirements. Higher frequencies can be directed more accurately whilst lower frequencies will carry further, and are generally used for more demanding requirements.  
*Chemical engineering. The chemical properties of the powder or substance to be debonded. Especially the auto adhesive properties of the powder. An acoustic cleaner will  create a series of very rapid and powerful sound induced pressure fluctuations which are then transmitted into the solid particles of ash, dust, granules or powder. This causes them to move at differing speeds and debond from adjoining particles and the surface that they are adhering to. Once they have been separated then the material will fall off due to gravity or it will be carried away by the process gas or air stream.  The key features which determine whether or not an acoustic cleaner will be effective for any given problem are the particle size range, the moisture content and the density of the particles as well as how these characteristics will change with temperature and time. Typically particles between 20 micrometres and 5 mm with moisture content below 8.5% are ideal. Upper temperature limits are dependent upon the melting point of the particles and acoustic cleaners have been employed at temperatures above 1000 °C  to remove ash build-up in boiler plants.  It is important to match the operating frequencies to the requirements. Higher frequencies can be directed more accurately whilst lower frequencies will carry further, and are generally used for more demanding requirements.  


A typical selection of frequencies available would be as follows:   
A typical selection of frequencies available would be as follows:   
*420 Hz for a small acoustic cleaner which might be used to clear bridging at the base of a silo.  
*420 Hz for a small acoustic cleaner which might be used to clear bridging at the base of a silo.  
*350 Hz will be more powerful and this frequency can be used to unblock material build-up in ID (induced draft) fans, filters, cyclones, mixers, dryers and coolers.  
*350 Hz will be more powerful and this frequency can be used to unblock material build-up in ID (induced draft) fans, [[filters]], [[cyclones]], [[mixers]], [[dryers]] and [[coolers]].  
*230 Hz. At this frequency, the power involved is sufficient to use in most electricity generation applications.  
*230 Hz. At this frequency, the power involved is sufficient to use in most electricity generation applications.  
*75 Hz and 60 Hz. These are generally the most powerful acoustic cleaners and are often used in large vessels and silos.   
*75 Hz and 60 Hz. These are generally the most powerful acoustic cleaners and are often used in large [[vessels]] and [[silos]].   




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===Bridging===  
===Bridging===  
This is when the silo blocks at the outlet. Previously the problem was addressed by manual cleaning from underneath the silo which in its turn introduced significant risk from falling material when the blockage was cleared. An acoustic cleaner is able to operate from the top of a silo through in situ material to clear the blockage at the base. 
This is when the silo blocks
 
 
===Rat holing===
Compaction on the side of a silo. This not only reduces the operating volume in a silo but it also compromises quality control by disrupting the first in first out cycle. Older material compacted on the side of a silo can also start to degrade and produce dangerous gases. An acoustic cleaner will produce sound waves which will make the compacted material resonate at a different rate to the surrounding environment resulting in debonding and clearance. 
 
 
==Advantages of acoustic cleaners==
*Repetitive use during operations means that there are fewer unscheduled shut downs.
*Improved material flow by the elimination of hang-ups, blocking and bridging.
*Minimisation of cross contamination by ensuring complete emptying of the environment.
*Improved cleaning and reduction of health and safety risks.
*Increased energy efficiency. Reducing the build up on heat exchange surfaces results in lower energy usage.
*Extended plant life. Aggressive cleaning regimes are avoided.
*Ease of operation. It is easy to automate the horns either at regular intervals or to tie the sounding in to changes in their environment such as pressure or flow rates.
*Importantly they prevent the material build up problem from occurring in the first place.  These advantages mean that the financial payback is often very quick.  It is also possible to compare acoustic cleaners directly to alternative solutions.  *Air cannons. These are well established but are expensive with limited coverage thus requiring multi unit purchase. They are also noise intrusive and have a high compressed air consumption.
*Vibrators. These are easy to fit to an empty silo but can cause structural damage as well as contributing to powder compaction. *Low friction linings. These are very quiet but are expensive to install. Also they are prone to erosion and can then contaminate the environment or product.
*Inflatable pads and liners. Again these are easy to install in an empty silo. They help side wall build up but have no impact on bridging. They are also hard to maintain and can cause compaction.
*Fluidisation through a 1 way membrane. This can help already compacted material. However they are expensive and difficult to install and maintain. They can also contribute to mechanical interlocking and bridging. 
 
 
==Specific applications for acoustic cleaners==
*Boilers. Cleaning of the heat transfer surfaces.
*Electrostatic precipitators. Acoustic cleaners are being used for cleaning [[hoppers]], turning vanes, distribution plates, collecting plates and electrode wires.
*Super heaters, economisers and air heaters.
*Duct work. 
*[[Filters]]. Acoustic cleaners are used on reverse air, pulse jet and shaker units. They are effective in reducing pressure drop across the collection surface which will increase bag life and prevent hopper pluggage. Generally they can totally replace the both reverse air fans and shaker units and significantly reduce the compressed air requirement on pulse jet filters.
*ID fans.  Acoustic cleaning helps to provide a uniform cleaning pattern even for inaccessible parts of the fan. This maintains the balance of the fan.
*[[Kilns]] inlet. Acoustic cleaners help to prevent particulate build up at the kiln inlet and this will minimise nose ring formation.
*Mechanical pre Collectors. Acoustic cleaners help prevent build up around the impellers and between the tubes. *Mills. Acoustic cleaners help maintain material flow and also prevent blockages in the pre grind silos. They also help prevent material build up in the downstream separators and fans.
*Planetary Coolers. Acoustic cleaners help prevent bridging and ensure complete evacuation.
*Precipitator. Acoustic cleaners help clean the turning vanes, distribution plates, collecting plates and electrode wires. They can either assist or replace the mechanical rapping systems. They also prevent particulate build up in the under hoppers which would otherwise result in opacity spiking.
*Pre heaters.  Used in towers, gas risers, cyclones and fans. *Ship cargo holds. Used both to clean and de aerate current loads.
*[[Silos]] and [[Hoppers]].  To prevent bridging and rat holing. *Static cyclones. Acoustic cleaners will work both within the cyclone and with the associated duct work.
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