Desalinating water with ultrasound, ultrasonics, the coanda effect and ocean geotextiles; with fresh water at one 1 cent per cubic meter as the output a 11 high identical element stack of water vapor maker, concentrator, and condenser made from corn cob
cellulose and some polymers is like a floating sandwich on the ocean, likely near shore; the inner bottom layer of the sandwich is a tesselation of wicking upright dendrites or tree shapes where the wick draw side contacts ocean water, the upper part of
the sandwich is a saltwater immune top corn cob cellulose based covering; corn cob powder is $100 per 1000 kilograms on alibaba or 10 cents per kilogram; treatment of cellulose with sulfuric acid or possibly electrode water acid causes the cellulose to
turn into a gel, likely compressible, shapeable, particle incorporating gel, a film of the corncob gel plus unreacted powdered corncob is both the upper layer and base lwicking layer of a geotextile air sandwich of a thinckness optimized for coanda
airflow, imaginably the geotextile ocean textile is 3 cm thick

Noting a 10 meter long, possibly, standard shipping container the sandwich is on 10 meter wide rolls and shipped uninflated, and the full square kilometer of sandwich is made of swathes 11 meters physically apart, which supports ocean well being by
avoiding the anoxia that would come from an uninterrupted square kilometer of ocean geotixtile; at the interior on the sandwich two complementary things combine to make it so air flowing through the middle of the sandwich has 80 times greater humidity,
up to 99.9% humidity just a minute amount less than auto condensation of water from air, 1) ultrasonic transducers motionize air in the sandwich sufficient to bring 20 times the volume of air in through apertures or slots on the upper outer surface of
the sandwich, and that air is used to provide coanda effect 20 times moving air, 2) the base tessellation of seawater wicking elements provides for 4-11 times greater air humidity for a 99.9 % humid airmass up to 88 times greater throughput of humid air
that eventually reaches a nonpowered seawater cooled condenser (liquid water maker); the ultrasonic transducers at the sandwich core are pendant on flaps from above and are shaped to push air axially forward, with the right incidence angle and likely
laminar flow to get the 20 times coanda effect air volume motion effect; notably, plastic acoustic lenses exist just like light lenses and along with good design of the ultrasonic elements the acoustic lenses can collimate the acoustic beam for more
effective air pushing at much farther distances to push and shape the coanda effect air entrainment, possibly two collimated ultrasound beams would pressurize and push 99.9% moist air which has gone from 10% humidity to 99.9% humidity from traveling past
the wicks to the a tube is a water making condenser part; if the humidifier is a sandwich, then a straw angled downward for gravity flow of liquid in-condenser is another part, with interior and exterior of the straw made to have very high surface area
internal to the straw and external at the straw with things like nub on a stick cold bringers and heat echangers, including laser velveting of the surface; the straw is a metal powder infused polymer rather than gelatinized pressed corncob powder;
although it risks corrosion a 80% magnesium or iron powder fill at the 35 cents per kilogram low density polyethylene could last 11 yearst, and with fe near 96$/ton possibly cheaper than less coolness conductive gelatinized corncob powder; from a simple
strawlike tube to an undulating rounded 3d shape the condenser is filled with freshwater from various simultaneous things like the coolness of the ocean, the presence of compression and decompression (slinky) waves from the ultrasound transducer, noting
a section of increased pressure causes water to condense and drip or flow to the gravity base of the condenser, and anything that can be done with the entrained coanda flow like passing it through a cooling venturi or what looks like a 3d nuclear plant
cooler hyperbolic paraboloid, as well as seeding a genetic algorithm with different aerodynamic shapes, flaps, water-hammer like pressure and thus condensation makers; the freshwater accumulated by each 10 meter wide and optimized length floating
component assembly is gathered together from the square kilometer and 11 lvertical ayers and pumped onto land or picked up by watermoving vessels; previously not mentioned is that each 10 meter wide swath of sandwich has 10-40 separate ultrasound flow
channels duplicated at it, a meter wide air channel only 3cm thick (sandwich thick) sounds less effective than a 11 cm wide channel; if the floaty sandwich weighs 3grams per square meter (compare various film masses), each square kilometer of 1 million
square meters is about 3 million grams or 333 kg, just $34 for gelatinized corncob construction, similarly 11 grams of low density polyethylene could be used at approximately 9 times more, or a little over $300 for a larger amount of a well comprehended
material; producing revenue at 1 cent per Cubic meter of water, if a cm^2 will evaporate 1/2 gram of water at 60 F then that is multiplied by 20 from the coanda effect breeze 9n the wicks then each cm^2 gathers 10g of water each 24 hour, or at a
kilometer square water production facility 100k sq meters of freshwater, or $1000 of freshwater at a cent a cubic meter per 24 hours, 365,000$ per year, a stack of 11 square kilometers earns 4 million $ annually; if the repairable life of the sandwich
and straw is 11 years then the entire thing earns $44 million on $3300 of polymer sandwich plus, at one ultrasound transducer per 20 cm wide times 49 cm sandwich channel, 3 cents for a mass produced but custom acoustic collimating lens, and 1.2-20 cents
per ultrasonic transducer (alibaba.com), 7 cents for a localized coanda making waveform generator/power supply, and 3 cents of wire and ultrasonically welded flap hosting the piezoelectric with a front pouch for the acoustic lens, the $ is .4+20+7+3 or
11 to 31 cents per square meter, at 11 cents per square meter a square kilometer is near $111k per square kilometer layer, and 11 layers is 1.2 million $ but earns 44 million $ each 11 years at 1 cent per cubic liter; 1 cent per cubic liter along with
benefitting urban persons is cheap enough to irrigate some kinds of crops in sunny locations like California, better versions of this could have the layers anchored far underwater, strongly reducing storm harm risk and placing the pipe that connects all
the freshwater containing straws to an ocean or bay bottom freshwater delivery to land pipe and macropump or advanced macro piezopump, possibly earning millions more is to have an upright pipe gathering Santa Barbara temperature ocean surface air and
bringing it to the 40-49 degree greater depth sandwich and condensing straw, a 20-29 degree difference, there may also be some millions of $ of fiscal value from pumping the air that will go through the sandwich to the straw through a within 6 inches of
warm ocean surface bubbleator/warm air humidifier before it is brought to the sandwich, or even skipping that and just drawing humid air from 16 cm above the ocean surface; electricity to power the ultrasonics comes from the shore; at alibaba
piezoelectric transducers come in 1.2 cent forms of about equal mass to the other multiwatt purpose engineered forms, suggesting that the very defined ultrasound transducer linear beam and collimating 3 cent polymer acoustic lens could be manufactured
together as 1 polymer pocket sized unit, additionally the corn cob molded gel polymer or low density polyethylene could have smooth flat construction benefitting coanda effect, it is even possible that at an 8 cm diameter channel there could be a short
stack of coanda passages for wall effect like(||||||) to entrain air on a rigid polymer gappy linear polywall; polywall or sandwich wall could be made with extra rigid ultrasonic reflectors or cones or other geometries to amplify/concentrate ultrasonic
force right where the coanda 20 times air entrainment happens; piezoelectric transducers that are ultrasound range from kHz to MHz, it is highly beneficial to utilize a frequency outside the hearing range of all mammals including marine mammals like
dolphins and whales, so MHz has both narrower beam and greater unhearability; on establishing private utilities can actually make money from sandwich and straw technologies they have the opportunity to invest in more durable forms lasting over a century
like PTFE membrane, digitally aware ultrasound transducers with a depthy form casting grating in front of them, harmless antimicrobial biocide peptides in the polymer to reduce fouling, condenser straws made from tin coated magnesium filled polymer,



A way of desalinating water so that when it precedes reverse or forward osmosis manufacture of fresh water from seawater only 3% as much osmosis membrane is used, making the two together cheaper than reverse osmosis or forward osmosis alone, first a
technology that is similar to a better version; at an STP tube have an ultrasound transducer surround a hollow narrow diameter tube such that when oceanwater is sprayed out of the tube moving compression waves or other ultrasonic and coanda shapes cause
the narrow stream of atomized droplets, nanoliters or microliters per droplet to travel forward until they are 94% evaporated; at 94% the droplets strike a wall I will call the brine drainage wall; continuous or even pulsed use raises the humidity of the
air in the tube to 99.9% humidity, minutely short of condensation, air is pumped through the tube and the 99.9% humidity air is condensed from acoustic ultrasound pressure waves that cause enough areas of free space air pressurized enough to condense on
an unchilled sponge ;Now for the actual different technology; consider a foaming agent mixed with seawater (protein based foaming agent 51¢/kg at alibaba) and the foam it makes, ultrasonically and coanda effect fan it until it mostly evaporates and
becomes briny foam with smaller bubble size, then although the actual technology does not use a centrifuge imagine centrifuging the entire chambers bubbles and then setting aside the; a different foam seawater desalination technology has several parts 1)
polymer tubes with dendritic wicks sticking out of a tube that carries oceanwater 2) an ultrasonically pumped airflow shape around the wicking tube, at 20 times multiple greater airflow a multiple flat plane geometry is used like [∆] or [ [ ] ], 8
planes at a diamond in a square is 160 times as much airflow in the tube, 3) beneath the 160 times breezy coanda elements is a layer of foamy bubbles that are made with a cheap foaming agent, when the coanda guide ceases all 160 airflow volumes of moist
wicked air are directed at the foam layer; the foam layer then surface absobs the water vapor rich coanda breeze air; when the bubbles moisture, determined by spectroscopy or just predicted with timing, has been re

placed with 97% freshwater a phonic or ultrasonic all bubble popping event occurs and the 97% freshwater is pumped to an osmosis filter to purify the remaining nacl mgcl2 cacl2 out; ultrasonics drive the coanda breeze



With ease of laser cutting it could be that lightweight metal or ceramic replacements for wood are possible, cheaper than 2021AD wood lumber, and much longer lasting a few forms are made on site ceramic pieces from laser sintering of cheap ceramic powder
or ceramic lumber factories at areas with lots of cheap electricity or natural gas; genetic algorithms would find optimal internal structure like geodesics, vaulting internals and screwdrivable, nailable drillable forms; that form could be a lumber core
that is then cooled and slid into a ceramic or metal sheath/outerlayer/girdle for greatest durability; glass beverage containers are cheaper than ALU!inum so an ultrasonically foamed liquid glass or ceramic could be especially affordable, perhaps foamed
around a cheap green ceramic molded geodesic Where the ceramic lumber is then heat treated to ceramicize (cost similar to concrete thermal calcination), other ways to make cheaper than wood ceramic or metal lumber is to make two mateable sides, like
stacked bookends or stacked ice cube trays making the linear lumber replacement fit together like two ]] brackets and using ultrasonic or laser spot welding that cofocalizes through the exterior to weld multiplenums inside a lineal lumber boxbeam
together giving more strength than just a hollow boxbeam, at a welded brackets form genetic algorithms are used to find optimal strength with least mass and greatest ease of munufacture; it could be that rather than vertical wall plenums, angled plenums
in a polyribbed shape surface or asterisk are better, the genetic algorithm improves the box beam filling; at ceramics foam is possible and could greatly reduce weight, large cell double thick walled larger diameter foam bubbles may be possible to
produce from ultrasonic and simultaneous treatment that produces cavitation at a spreader nozzle that either fills a mold or draws a lumber shaped bolus on a continuous process conveyor belt; low (sodium silicate) or high temperature glasses and ceramics
can be used for cheapest manufacture; other kinds of wood replacing lumber are producible this way like ceramic or metal plywood, metal version might be butcher block ice cube tray, ultrasonically welded or laser welded plenum construction or anything
the genetic algorithm likes better, notably at laser welding, and possibly at ultrasonic welding entire square meters of material can be welded in parallel with a light distribution grating like a hologram that simply spot welds all ]] plenum walls with
minimal alignment, industrial lasers are published as join welding 60 meters/minute, which could be multiplied several times over as the massively multiparallel plenum spot welds are much faster

The metal to make a linear lumber or plywood replacement seems to be ferrous alloy, zinc or new conductive polymer anodic protections would be used, at a construction site a drone could beam radio at a wall or building and compare it to a the image or
the cad plans to find any ungrounded metal at the buildings metal lumber to connect to anodic protection



Comparing an explosive nailgun and an explosive rifled barrel screwgun that shoots with a twist, rotational rates that are multiples higher than the directional force could shoot screw-capable screws, useful at metal lumber



My perception at plywood and oriented strand board is that the urea glue is cheaper than the wood, only if that is so then genetic algorithms could come up with a new form for all urea glue paneling, ultrasonic and laser foaming might be very cheap, and
embossing surface ribs is also cheap, although plywood is a laminate minimizing the amount of laminations makes all glue plywood cheaper, noting the polymer expansion pellet like styrofoam, peraps urea wood glue expansion pellets could be made to make a
new kind of strong light styroboard where different space filling geometries or pellets are combined, like long foam straw lzser oriented nonwoven fabric layers, at alibaba aluminized mylar is 1\2 cent per sqfoot, suggesting an aluminum, or bismuth or
tin moisture blocking metallization can be less than that

Could soliton like high energy dissipative solitons be better at drilling through earth for wells and petrochemicals, farm soiltreatents and sewage leachate fields and colorization layer of reverse osmosis membranes



Using ultrasound to make roofs last longer, at a roof like a polymer coat flat roof there are areas of water concentration some might be puddle like, the effect of putting an ultrasound transducer and vibrating form in these puddles is the cool
ultramicrospray of water out of the puddle at a velocity comparable to an ultrasound humifier, this takes much less energy than it would to evaporate the puddle, so as a roof technology a 1-2 watt piezoelectric transducer, a polymer or aluminum vibrating
plane an either a 1 or 2 watt photovoltaic or a rooftop electrical plug powers the puddle remover; for new construction of bulbiform, angled and flat roofs the ultrasonic elements can be made a part of the roofs layers or top, each 1000 sq meters of roof
might have 1kw of spread out transducers, run for an hour or less each day, and contain $200 of transducers at 20 cents per transducer; it may also be possible to use 1\10 the energy and number of transducers from putting them only at low wet spots at
the edges of eaves and height reduced areas of flat roofs



Wikipedia describes ultrasonic trills as using just 10w to drill a hole in granite compared with 760w with a rotary electric drill, that suggests that boat and ship propellors like those used for containerized shipping could be more energy efficient with
ultrasonically agitated or even driven (rotated) propellors perhaps causing 76 times less drag, similarly kW of ultrasonic energy at the leading point of a ship could ”drill" throughwater 76 times more efficiently; applied to pumps like air
conditionimg amd heat pump pumps as well as agricultural pumps à vertical translation rotating 8mpeller that rides a focal cone of ultrasound (see wikipedia ultrasonic drill) or is ultrasonically linked to a vibrating mass that twirls could use much
less energy to recompress refrigerant or, at agriculture, move water, and at industrial pumps move industrial fluids, i do not know of any water propellors or pumps based on the wikipedia ultrasonic drill developed by NASA; I perceive the thicker the
solid or liquid the nearer the technology is to the 76 times efficiency gain, that suggests an ultrasonic saw, simply a line of ultrasonic drills could replace diamond tip circular saws at construction and roadway concrete cutting, metal cutting and, at
industrial cutting the equivalent of blades that omit getting dull thus last longer and have less maintenance, what is called stir-welding could also benefit from ultrasonic drill technology, producing, like granite, 76 times greater stirring rotating
perhaps percussimg amount of stir welding for the energy used; the ultrasonic drill technology's effectiveness at drilling an inch in granite with 76 times less energy has direct functionality at transforming above ground or below ground ore chunks
around 2-3 cm into powders and microfine powders for smelting and leaching ore, at mining, similarly if an ultrasonic grinder is based on ultrasonic drill technology cement and concrete clinkers can be powderized for use much more energy efficiently;
wikipedia notes after 1 inch drill depth mineral fragments and powders effect drilling effectiness, blowing the fragmented material out with the coanda effect or a simple water jet slurry are likely to increase drilling depth; I read about an amorphous
compressed fullerene glass more than 1000 times harder than diamond, that could make an especially effective ultrasonic drill, saw, or grinder active element coating; the efficiency of the 76 times more effective ultrasonic drill could be increased from
customizing the kHz/MHz frequency to the ores being powderized or the thing drilled; also wikipedia mentions one part of the drill is a vibrating mass with the drill bit on one side, if an ultrasound acoustic reflector is used then both sides of the
vibrating masses wiggle can be used, visually a little like a ballpoint pen receiving energy from inktube and also angled-in ferrule around the ball of the ball point pen image, also depending on the material being drilled or the ore being powderized
various ratios of percussion:rotation or even eccentric motion produce different effects at the same energy, it seems to be possible to double the energy efficiency of the ultrasonic drill, saw and grinder; its easy to think of an ultrasound crystal as
an electrode sandwich, but what if the piezoelectric element were molded or laser cut to look like an undulating rollercoaster or a center connected group of chevrons>>>>, then the wave emitted would have additional 2D or 3D character and with different
electrical connections at each swell of the roller coaster or separate leaf of a polychevron the ultrasonic crystal could separately and compositely addressed; is the vibrating mass mentioned at wikipedia high density and highly affordable like bismuth



The way a rotary electric drill is often a motor, and a motor swaps for a generator, but is 76 times less efficient at drilling than an ultrasonic drill suggests the possibility of an electric generator or motor that produces energy or travels further an
order of magnitude better than an electrical winding machine if the generator is built to precisely and frequently strike/deshape piezoelectric elements that have conductors on them to produce piezoelectricity, a rotating turbine like a gas or nuclear
turbine could pressurize an air or even water whistle tuned to the optimal receiving frequency of the physically connected piezoelectric crystal, an alternative to a whistle is a super purposefully very loud slippage of metal on metal, like the idea of a
squeaky bearing amplified, another source of piezoelectric sound is a rotating bike wheel with thousands of radii wires as strikers to a plurality of tuning Y objects encruested with piezoelectric crystals, or each being a single wired for electrical
production crystal each



Motion coupled piezoelectric elements could function as very high efficiency transformers benefitting the many transformers at an electrical grid



Ultrasonic anti-ultrasonic drilling at bearings and piston rings, can an anti-drilling effect make a bearing or ball bearing that floats in the middle of its tolerance range, causing much greater life, does ultrasonic jiggling reduce raceway friction if
the jiggle moves the bearing or ball bearing towards central location of least contact, reduce friction and warmth generation



Noting that lasers can etch surface finishes it could be that an agricultural drone laser that purposefully thins the outer upper cuticle of agricultural plants leaves to make them thinner and have a grating would cause them to absorb more irrigation
water and spray on nutrients, fruit, nut, soybean, grain crops could all be tried with this, it also increases gas exchange, really unlikely possibility is that with laser cuticle thinning available CO2 goes way up; just as gratings increase the optical
transparency of metals the laser ruled gratings on plants could increase transparency and be like an antireflective coating from reshaping the cellulose on the leaf, broad massively multiparallel etching of 2x2 meters of surface at a time could be done
with a hologram grating and strong laser aimed at a swath of plants, using heatless pulsed spallation lasers is also possible



Lasers could be used to smooth out bumps on roads with laser planing of asphalt and cement, making drivers happier and possibly slightly increasing energy mileage; the road laser planer could have a new road stripe painter on the same platform, airjets
or rotary sweepers could sequester and remove the planed away micropowder



Do geodesic molecules like fullerenes exist but made of silicon?

--- SoupGate-Win32 v1.05
* Origin: fsxNet Usenet Gateway (21:1/5)

Desalinating water with ultrasound, ultrasonics, the coanda effect and ocean geotextiles; with fresh water at one 1 cent per cubic meter as the output a 11 high identical element stack of water vapor maker, concentrator, and condenser made from corn cob
cellulose and some polymers is like a floating sandwich on the ocean, likely near shore; the inner bottom layer of the sandwich is a tesselation of wicking upright dendrites or tree shapes where the wick draw side contacts ocean water, the upper part of
the sandwich is a saltwater immune top corn cob cellulose based covering; corn cob powder is $100 per 1000 kilograms on alibaba or 10 cents per kilogram; treatment of cellulose with sulfuric acid or possibly electrode water acid causes the cellulose to
turn into a gel, likely compressible, shapeable, particle incorporating gel, a film of the corncob gel plus unreacted powdered corncob is both the upper layer and base lwicking layer of a geotextile air sandwich of a thinckness optimized for coanda
airflow, imaginably the geotextile ocean textile is 3 cm thick

Noting a 10 meter long, possibly, standard shipping container the sandwich is on 10 meter wide rolls and shipped uninflated, and the full square kilometer of sandwich is made of swathes 11 meters physically apart, which supports ocean well being by
avoiding the anoxia that would come from an uninterrupted square kilometer of ocean geotixtile; at the interior on the sandwich two complementary things combine to make it so air flowing through the middle of the sandwich has 80 times greater humidity,
up to 99.9% humidity just a minute amount less than auto condensation of water from air, 1) ultrasonic transducers motionize air in the sandwich sufficient to bring 20 times the volume of air in through apertures or slots on the upper outer surface of
the sandwich, and that air is used to provide coanda effect 20 times moving air, 2) the base tessellation of seawater wicking elements provides for 4-11 times greater air humidity for a 99.9 % humid airmass up to 88 times greater throughput of humid air
that eventually reaches a nonpowered seawater cooled condenser (liquid water maker); the ultrasonic transducers at the sandwich core are pendant on flaps from above and are shaped to push air axially forward, with the right incidence angle and likely
laminar flow to get the 20 times coanda effect air volume motion effect; notably, plastic acoustic lenses exist just like light lenses and along with good design of the ultrasonic elements the acoustic lenses can collimate the acoustic beam for more
effective air pushing at much farther distances to push and shape the coanda effect air entrainment, possibly two collimated ultrasound beams would pressurize and push 99.9% moist air which has gone from 10% humidity to 99.9% humidity from traveling past
the wicks to the a tube is a water making condenser part; if the humidifier is a sandwich, then a straw angled downward for gravity flow of liquid in-condenser is another part, with interior and exterior of the straw made to have very high surface area
internal to the straw and external at the straw with things like nub on a stick cold bringers and heat echangers, including laser velveting of the surface; the straw is a metal powder infused polymer rather than gelatinized pressed corncob powder;
although it risks corrosion a 80% magnesium or iron powder fill at the 35 cents per kilogram low density polyethylene could last 11 yearst, and with fe near 96$/ton possibly cheaper than less coolness conductive gelatinized corncob powder; from a simple
strawlike tube to an undulating rounded 3d shape the condenser is filled with freshwater from various simultaneous things like the coolness of the ocean, the presence of compression and decompression (slinky) waves from the ultrasound transducer, noting
a section of increased pressure causes water to condense and drip or flow to the gravity base of the condenser, and anything that can be done with the entrained coanda flow like passing it through a cooling venturi or what looks like a 3d nuclear plant
cooler hyperbolic paraboloid, as well as seeding a genetic algorithm with different aerodynamic shapes, flaps, water-hammer like pressure and thus condensation makers; the freshwater accumulated by each 10 meter wide and optimized length floating
component assembly is gathered together from the square kilometer and 11 lvertical ayers and pumped onto land or picked up by watermoving vessels; previously not mentioned is that each 10 meter wide swath of sandwich has 10-40 separate ultrasound flow
channels duplicated at it, a meter wide air channel only 3cm thick (sandwich thick) sounds less effective than a 11 cm wide channel; if the floaty sandwich weighs 3grams per square meter (compare various film masses), each square kilometer of 1 million
square meters is about 3 million grams or 333 kg, just $34 for gelatinized corncob construction, similarly 11 grams of low density polyethylene could be used at approximately 9 times more, or a little over $300 for a larger amount of a well comprehended
material; producing revenue at 1 cent per Cubic meter of water, if a cm^2 will evaporate 1/2 gram of water at 60 F then that is multiplied by 20 from the coanda effect breeze 9n the wicks then each cm^2 gathers 10g of water each 24 hour, or at a
kilometer square water production facility 100k sq meters of freshwater, or $1000 of freshwater at a cent a cubic meter per 24 hours, 365,000$ per year, a stack of 11 square kilometers earns 4 million $ annually; if the repairable life of the sandwich
and straw is 11 years then the entire thing earns $44 million on $3300 of polymer sandwich plus, at one ultrasound transducer per 20 cm wide times 49 cm sandwich channel, 3 cents for a mass produced but custom acoustic collimating lens, and 1.2-20 cents
per ultrasonic transducer (alibaba.com), 7 cents for a localized coanda making waveform generator/power supply, and 3 cents of wire and ultrasonically welded flap hosting the piezoelectric with a front pouch for the acoustic lens, the $ is .4+20+7+3 or
11 to 31 cents per square meter, at 11 cents per square meter a square kilometer is near $111k per square kilometer layer, and 11 layers is 1.2 million $ but earns 44 million $ each 11 years at 1 cent per cubic liter; 1 cent per cubic liter along with
benefitting urban persons is cheap enough to irrigate some kinds of crops in sunny locations like California, better versions of this could have the layers anchored far underwater, strongly reducing storm harm risk and placing the pipe that connects all
the freshwater containing straws to an ocean or bay bottom freshwater delivery to land pipe and macropump or advanced macro piezopump, possibly earning millions more is to have an upright pipe gathering Santa Barbara temperature ocean surface air and
bringing it to the 40-49 degree greater depth sandwich and condensing straw, a 20-29 degree difference, there may also be some millions of $ of fiscal value from pumping the air that will go through the sandwich to the straw through a within 6 inches of
warm ocean surface bubbleator/warm air humidifier before it is brought to the sandwich, or even skipping that and just drawing humid air from 16 cm above the ocean surface; electricity to power the ultrasonics comes from the shore; at alibaba
piezoelectric transducers come in 1.2 cent forms of about equal mass to the other multiwatt purpose engineered forms, suggesting that the very defined ultrasound transducer linear beam and collimating 3 cent polymer acoustic lens could be manufactured
together as 1 polymer pocket sized unit, additionally the corn cob molded gel polymer or low density polyethylene could have smooth flat construction benefitting coanda effect, it is even possible that at an 8 cm diameter channel there could be a short
stack of coanda passages for wall effect like(||||||) to entrain air on a rigid polymer gappy linear polywall; polywall or sandwich wall could be made with extra rigid ultrasonic reflectors or cones or other geometries to amplify/concentrate ultrasonic
force right where the coanda 20 times air entrainment happens; piezoelectric transducers that are ultrasound range from kHz to MHz, it is highly beneficial to utilize a frequency outside the hearing range of all mammals including marine mammals like
dolphins and whales, so MHz has both narrower beam and greater unhearability; on establishing private utilities can actually make money from sandwich and straw technologies they have the opportunity to invest in more durable forms lasting over a century
like PTFE membrane, digitally aware ultrasound transducers with a depthy form casting grating in front of them, harmless antimicrobial biocide peptides in the polymer to reduce fouling, condenser straws made from tin coated magnesium filled polymer,



A way of desalinating water so that when it precedes reverse or forward osmosis manufacture of fresh water from seawater only 3% as much osmosis membrane is used, making the two together cheaper than reverse osmosis or forward osmosis alone, first a
technology that is similar to a better version; at an STP tube have an ultrasound transducer surround a hollow narrow diameter tube such that when oceanwater is sprayed out of the tube moving compression waves or other ultrasonic and coanda shapes cause
the narrow stream of atomized droplets, nanoliters or microliters per droplet to travel forward until they are 94% evaporated; at 94% the droplets strike a wall I will call the brine drainage wall; continuous or even pulsed use raises the humidity of the
air in the tube to 99.9% humidity, minutely short of condensation, air is pumped through the tube and the 99.9% humidity air is condensed from acoustic ultrasound pressure waves that cause enough areas of free space air pressurized enough to condense on
an unchilled sponge ;Now for the actual different technology; consider a foaming agent mixed with seawater (protein based foaming agent 51¢/kg at alibaba) and the foam it makes, ultrasonically and coanda effect fan it until it mostly evaporates and
becomes briny foam with smaller bubble size, then although the actual technology does not use a centrifuge imagine centrifuging the entire chambers bubbles and then setting aside the; a different foam seawater desalination technology has several parts 1)
polymer tubes with dendritic wicks sticking out of a tube that carries oceanwater 2) an ultrasonically pumped airflow shape around the wicking tube, at 20 times multiple greater airflow a multiple flat plane geometry is used like [∆] or [ [ ] ], 8
planes at a diamond in a square is 160 times as much airflow in the tube, 3) beneath the 160 times breezy coanda elements is a layer of foamy bubbles that are made with a cheap foaming agent, when the coanda guide ceases all 160 airflow volumes of moist
wicked air are directed at the foam layer; the foam layer then surface absobs the water vapor rich coanda breeze air; when the bubbles moisture, determined by spectroscopy or just predicted with timing, has been re

placed with 97% freshwater a phonic or ultrasonic all bubble popping event occurs and the 97% freshwater is pumped to an osmosis filter to purify the remaining nacl mgcl2 cacl2 out; ultrasonics drive the coanda breeze



With ease of laser cutting it could be that lightweight metal or ceramic replacements for wood are possible, cheaper than 2021AD wood lumber, and much longer lasting a few forms are made on site ceramic pieces from laser sintering of cheap ceramic powder
or ceramic lumber factories at areas with lots of cheap electricity or natural gas; genetic algorithms would find optimal internal structure like geodesics, vaulting internals and screwdrivable, nailable drillable forms; that form could be a lumber core
that is then cooled and slid into a ceramic or metal sheath/outerlayer/girdle for greatest durability; glass beverage containers are cheaper than ALU!inum so an ultrasonically foamed liquid glass or ceramic could be especially affordable, perhaps foamed
around a cheap green ceramic molded geodesic Where the ceramic lumber is then heat treated to ceramicize (cost similar to concrete thermal calcination), other ways to make cheaper than wood ceramic or metal lumber is to make two mateable sides, like
stacked bookends or stacked ice cube trays making the linear lumber replacement fit together like two ]] brackets and using ultrasonic or laser spot welding that cofocalizes through the exterior to weld multiplenums inside a lineal lumber boxbeam
together giving more strength than just a hollow boxbeam, at a welded brackets form genetic algorithms are used to find optimal strength with least mass and greatest ease of munufacture; it could be that rather than vertical wall plenums, angled plenums
in a polyribbed shape surface or asterisk are better, the genetic algorithm improves the box beam filling; at ceramics foam is possible and could greatly reduce weight, large cell double thick walled larger diameter foam bubbles may be possible to
produce from ultrasonic and simultaneous treatment that produces cavitation at a spreader nozzle that either fills a mold or draws a lumber shaped bolus on a continuous process conveyor belt; low (sodium silicate) or high temperature glasses and ceramics
can be used for cheapest manufacture; other kinds of wood replacing lumber are producible this way like ceramic or metal plywood, metal version might be butcher block ice cube tray, ultrasonically welded or laser welded plenum construction or anything
the genetic algorithm likes better, notably at laser welding, and possibly at ultrasonic welding entire square meters of material can be welded in parallel with a light distribution grating like a hologram that simply spot welds all ]] plenum walls with
minimal alignment, industrial lasers are published as join welding 60 meters/minute, which could be multiplied several times over as the massively multiparallel plenum spot welds are much faster

The metal to make a linear lumber or plywood replacement seems to be ferrous alloy, zinc or new conductive polymer anodic protections would be used, at a construction site a drone could beam radio at a wall or building and compare it to a the image or
the cad plans to find any ungrounded metal at the buildings metal lumber to connect to anodic protection



Comparing an explosive nailgun and an explosive rifled barrel screwgun that shoots with a twist, rotational rates that are multiples higher than the directional force could shoot screw-capable screws, useful at metal lumber



My perception at plywood and oriented strand board is that the urea glue is cheaper than the wood, only if that is so then genetic algorithms could come up with a new form for all urea glue paneling, ultrasonic and laser foaming might be very cheap, and
embossing surface ribs is also cheap, although plywood is a laminate minimizing the amount of laminations makes all glue plywood cheaper, noting the polymer expansion pellet like styrofoam, peraps urea wood glue expansion pellets could be made to make a
new kind of strong light styroboard where different space filling geometries or pellets are combined, like long foam straw lzser oriented nonwoven fabric layers, at alibaba aluminized mylar is 1\2 cent per sqfoot, suggesting an aluminum, or bismuth or
tin moisture blocking metallization can be less than that

Could soliton like high energy dissipative solitons be better at drilling through earth for wells and petrochemicals, farm soiltreatents and sewage leachate fields and colorization layer of reverse osmosis membranes



Using ultrasound to make roofs last longer, at a roof like a polymer coat flat roof there are areas of water concentration some might be puddle like, the effect of putting an ultrasound transducer and vibrating form in these puddles is the cool
ultramicrospray of water out of the puddle at a velocity comparable to an ultrasound humifier, this takes much less energy than it would to evaporate the puddle, so as a roof technology a 1-2 watt piezoelectric transducer, a polymer or aluminum vibrating
plane an either a 1 or 2 watt photovoltaic or a rooftop electrical plug powers the puddle remover; for new construction of bulbiform, angled and flat roofs the ultrasonic elements can be made a part of the roofs layers or top, each 1000 sq meters of roof
might have 1kw of spread out transducers, run for an hour or less each day, and contain $200 of transducers at 20 cents per transducer; it may also be possible to use 1\10 the energy and number of transducers from putting them only at low wet spots at
the edges of eaves and height reduced areas of flat roofs



Wikipedia describes ultrasonic trills as using just 10w to drill a hole in granite compared with 760w with a rotary electric drill, that suggests that boat and ship propellors like those used for containerized shipping could be more energy efficient with
ultrasonically agitated or even driven (rotated) propellors perhaps causing 76 times less drag, similarly kW of ultrasonic energy at the leading point of a ship could ”drill" throughwater 76 times more efficiently; applied to pumps like air
conditionimg amd heat pump pumps as well as agricultural pumps à vertical translation rotating 8mpeller that rides a focal cone of ultrasound (see wikipedia ultrasonic drill) or is ultrasonically linked to a vibrating mass that twirls could use much
less energy to recompress refrigerant or, at agriculture, move water, and at industrial pumps move industrial fluids, i do not know of any water propellors or pumps based on the wikipedia ultrasonic drill developed by NASA; I perceive the thicker the
solid or liquid the nearer the technology is to the 76 times efficiency gain, that suggests an ultrasonic saw, simply a line of ultrasonic drills could replace diamond tip circular saws at construction and roadway concrete cutting, metal cutting and, at
industrial cutting the equivalent of blades that omit getting dull thus last longer and have less maintenance, what is called stir-welding could also benefit from ultrasonic drill technology, producing, like granite, 76 times greater stirring rotating
perhaps percussimg amount of stir welding for the energy used; the ultrasonic drill technology's effectiveness at drilling an inch in granite with 76 times less energy has direct functionality at transforming above ground or below ground ore chunks
around 2-3 cm into powders and microfine powders for smelting and leaching ore, at mining, similarly if an ultrasonic grinder is based on ultrasonic drill technology cement and concrete clinkers can be powderized for use much more energy efficiently;
wikipedia notes after 1 inch drill depth mineral fragments and powders effect drilling effectiness, blowing the fragmented material out with the coanda effect or a simple water jet slurry are likely to increase drilling depth; I read about an amorphous
compressed fullerene glass more than 1000 times harder than diamond, that could make an especially effective ultrasonic drill, saw, or grinder active element coating; the efficiency of the 76 times more effective ultrasonic drill could be increased from
customizing the kHz/MHz frequency to the ores being powderized or the thing drilled; also wikipedia mentions one part of the drill is a vibrating mass with the drill bit on one side, if an ultrasound acoustic reflector is used then both sides of the
vibrating masses wiggle can be used, visually a little like a ballpoint pen receiving energy from inktube and also angled-in ferrule around the ball of the ball point pen image, also depending on the material being drilled or the ore being powderized
various ratios of percussion:rotation or even eccentric motion produce different effects at the same energy, it seems to be possible to double the energy efficiency of the ultrasonic drill, saw and grinder; its easy to think of an ultrasound crystal as
an electrode sandwich, but what if the piezoelectric element were molded or laser cut to look like an undulating rollercoaster or a center connected group of chevrons>>>>, then the wave emitted would have additional 2D or 3D character and with different
electrical connections at each swell of the roller coaster or separate leaf of a polychevron the ultrasonic crystal could separately and compositely addressed; is the vibrating mass mentioned at wikipedia high density and highly affordable like bismuth



The way a rotary electric drill is often a motor, and a motor swaps for a generator, but is 76 times less efficient at drilling than an ultrasonic drill suggests the possibility of an electric generator or motor that produces energy or travels further an
order of magnitude better than an electrical winding machine if the generator is built to precisely and frequently strike/deshape piezoelectric elements that have conductors on them to produce piezoelectricity, a rotating turbine like a gas or nuclear
turbine could pressurize an air or even water whistle tuned to the optimal receiving frequency of the physically connected piezoelectric crystal, an alternative to a whistle is a super purposefully very loud slippage of metal on metal, like the idea of a
squeaky bearing amplified, another source of piezoelectric sound is a rotating bike wheel with thousands of radii wires as strikers to a plurality of tuning Y objects encruested with piezoelectric crystals, or each being a single wired for electrical
production crystal each



Motion coupled piezoelectric elements could function as very high efficiency transformers benefitting the many transformers at an electrical grid



Ultrasonic anti-ultrasonic drilling at bearings and piston rings, can an anti-drilling effect make a bearing or ball bearing that floats in the middle of its tolerance range, causing much greater life, does ultrasonic jiggling reduce raceway friction if
the jiggle moves the bearing or ball bearing towards central location of least contact, reduce friction and warmth generation



Noting that lasers can etch surface finishes it could be that an agricultural drone laser that purposefully thins the outer upper cuticle of agricultural plants leaves to make them thinner and have a grating would cause them to absorb more irrigation
water and spray on nutrients, fruit, nut, soybean, grain crops could all be tried with this, it also increases gas exchange, really unlikely possibility is that with laser cuticle thinning available CO2 goes way up; just as gratings increase the optical
transparency of metals the laser ruled gratings on plants could increase transparency and be like an antireflective coating from reshaping the cellulose on the leaf, broad massively multiparallel etching of 2x2 meters of surface at a time could be done
with a hologram grating and strong laser aimed at a swath of plants, using heatless pulsed spallation lasers is also possible



Lasers could be used to smooth out bumps on roads with laser planing of asphalt and cement, making drivers happier and possibly slightly increasing energy mileage; the road laser planer could have a new road stripe painter on the same platform, airjets
or rotary sweepers could sequester and remove the planed away micropowder



Do geodesic molecules like fullerenes exist but made of silicon?

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