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	<title>Infrarood en Toepassingen Archives - INFRAROOD THERAPIE | Warmte &amp; Licht | THERMO MEDICA ®</title>
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		<title>Far Infrared Heat Therapy for Seniors</title>
		<link>https://thermomedica.nl/far-infrared-heat-therapy-for-seniors/</link>
		
		<dc:creator><![CDATA[Madhava Overgoor]]></dc:creator>
		<pubDate>Mon, 03 Jul 2017 17:41:45 +0000</pubDate>
				<category><![CDATA[Infrarood en Toepassingen]]></category>
		<category><![CDATA[Uncategorized]]></category>
		<category><![CDATA[Ziekten en Infrarood]]></category>
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					<description><![CDATA[<p>Far Infrared Heat Therapy For Seniors Far Infrared Heat Therapy For Seniors &#124; Seniors are more likely to suffer from diseases such as chronic fatigue, arthritis, falls and injuries, chronic pains in the back and joints, elevated blood pressure, sleep disorders and many other conditions due to build-up acidity and toxins in their system. Lifestyle [&#8230;]</p>
<p>The post <a href="https://thermomedica.nl/far-infrared-heat-therapy-for-seniors/">Far Infrared Heat Therapy for Seniors</a> appeared first on <a href="https://thermomedica.nl">INFRAROOD THERAPIE | Warmte &amp; Licht | THERMO MEDICA ®</a>.</p>
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										<content:encoded><![CDATA[<h2>Far Infrared Heat Therapy For Seniors</h2>
<p><em>Far Infrared Heat Therapy For Seniors</em> | Seniors are more likely to suffer from diseases such as chronic fatigue, arthritis, falls and injuries, chronic pains in the back and joints, elevated blood pressure, sleep disorders and many other conditions due to build-up acidity and toxins in their system. Lifestyle habit and diet changes are often part of the overall treatment of these conditions. But there is also much to be said for time-tested techniques such as heat therapy and its latest version, Far Infrared Therapy, to FIR Therapy, which can provide natural pain relief and helps to get rid of toxins and cellular waste.</p>
<p>Fir/Far infrared light is the frequency of invisible light that is generated naturally by the sun. FIR Therapy is a type of low energy therapy that takes advantage of the heat generated by waves of energy from the far end of the infrared spectrum. This safe and natural alternative therapy can be used in the treatment of a variety of health problems such as stress, arthritis, muscle pain, spasms and shoulder or joint stiffness.</p>
<p><em>Far infrared therapy also benefits the body by:</em></p>
<ul>
<li>Increasing poor blood circulation deep in the tissues</li>
<li>Remove heavy metals and toxins from the body through perspiration</li>
<li>Reducing tension and stress</li>
<li>Improving lymphatic flow and function</li>
<li>Stimulating/boosting the immune system</li>
</ul>
<p>Far infrared therapy also causes blood vessels to expand. This expansion leads to improved circulation and allows the immune system cells and chemicals to converge on the injured areas to facilitate the healing process. Despite the heat induced, FIR therapy does not cause any significant rise in core body temperature or in blood pressure, which makes it safer for seniors with cardiovascular problems.</p>
<h3>Different types of far infrared devices</h3>
<p>There are several types of far infrared therapy devices on the market today that provide both direct and indirect heat therapy. FIR saunas can be used to deliver whole body or indirect therapy while <a href="https:/shop/"><strong>far infrared heating pads</strong></a>, clothing and bedding supplies may be used for localized applications.</p>
<p>Each of these types of FIR therapy uses different means to produce far infrared heat. Far infrared saunas use carbon/ceramic heaters to generate indirect heat in the form of low energy far infrared waves. Heating pads utilize individual natural jade stones, and far infrared clothing and far infrared bedding such as undergarments, therapy gloves, joint braces, socks, sheets and pillows use specially designed infrared emitting fabrics to produce the infrared heat. All of these different types of therapy generate radiant heat that penetrates deep into the body to provide natural pain relief and other health benefits.</p>
<h3>Far Infrared Heat Therapy For Seniors</h3>
<p>Far infrared waves can penetrate up to vier inches deep to generate warmth that can provide immense relief to muscles and internal organs. The gentle heat produced in far infrared heat therapy exerts an analgesic effect and can help reduce or eliminate chronic pains that seniors often experience in various parts of the body. Stiffness in the joints from arthritis can be significantly relieved. Studies show that far infrared heat makes connective tissue more flexible, permits greater joint movement and brings about increased levels of endorphins, which increases pain relieve.</p>
<p>The post <a href="https://thermomedica.nl/far-infrared-heat-therapy-for-seniors/">Far Infrared Heat Therapy for Seniors</a> appeared first on <a href="https://thermomedica.nl">INFRAROOD THERAPIE | Warmte &amp; Licht | THERMO MEDICA ®</a>.</p>
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		<title>Infrared energy: A new renewable source?</title>
		<link>https://thermomedica.nl/infrared-energy/</link>
		
		<dc:creator><![CDATA[Madhava Overgoor]]></dc:creator>
		<pubDate>Sat, 20 Dec 2014 21:50:50 +0000</pubDate>
				<category><![CDATA[Infrarood en Toepassingen]]></category>
		<category><![CDATA[energy]]></category>
		<category><![CDATA[infrared]]></category>
		<category><![CDATA[infrared energy]]></category>
		<category><![CDATA[physics]]></category>
		<category><![CDATA[source]]></category>
		<guid isPermaLink="false">https:/?p=1429</guid>

					<description><![CDATA[<p>Infrared energy: A new renewable source? HARVARD PHYSICISTS PROPOSE A DEVICE TO CAPTURE ENERGY FROM EARTH’S INFRARED EMISSIONS TO OUTER SPACE March 3, 2014  &#124;  By Caroline Perry Cambridge, Mass. – March 3, 2014 – When the sun sets on a remote desert outpost and solar panels shut down, what energy source will provide power through [&#8230;]</p>
<p>The post <a href="https://thermomedica.nl/infrared-energy/">Infrared energy: A new renewable source?</a> appeared first on <a href="https://thermomedica.nl">INFRAROOD THERAPIE | Warmte &amp; Licht | THERMO MEDICA ®</a>.</p>
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<p>HARVARD PHYSICISTS PROPOSE A DEVICE TO CAPTURE ENERGY FROM EARTH’S INFRARED EMISSIONS TO OUTER SPACE</p>
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<div class="field-item even"><span class="date-display-single">March 3, 2014  |  </span>By Caroline Perry</div>
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<p><strong>Cambridge, Mass. – March 3, 2014 – </strong>When the sun sets on a remote desert outpost and solar panels shut down, what energy source will provide power through the night? A battery, perhaps, or an old diesel generator? Perhaps something strange and new.</p>
<p>Physicists at the <a href="https://www.seas.harvard.edu/">Harvard School of Engineering and Applied Sciences</a> (SEAS) envision a device that would harvest energy from Earth’s infrared emissions into outer space.</p>
<p>Heated by the sun, our planet is warm compared to the frigid vacuum beyond. Thanks to recent technological advances, the researchers say, that heat imbalance could soon be transformed into direct-current (DC) power, taking advantage of a vast and untapped energy source.</p>
<p>Their analysis of the thermodynamics, practical concerns, and technological requirements will be published this week in the <a href="https://www.pnas.org/content/early/2014/02/26/1402036111.abstract"><em>Proceedings of the National Academy of Sciences</em></a>.</p>
<p>“It’s not at all obvious, at first, how you would generate DC power by emitting infrared light in free space toward the cold,” says principal investigator <a href="https://www.seas.harvard.edu/directory/capasso">Federico Capasso</a>, the Robert L. Wallace Professor of Applied Physics and Vinton Hayes Senior Research Fellow in Electrical Engineering at Harvard SEAS. “To generate power by emitting, not by absorbing light, that’s weird. It makes sense physically once you think about it, but it’s highly counterintuitive. We’re talking about the use of physics at the nanoscale for a completely new application.”</p>
<p class="inline_caption"><img decoding="async" src="https://www.seas.harvard.edu/sites/default/files/images/news/Capasso-Byrnes_650px.jpg" alt="" width="650" height="433" /></p>
<p class="inline_caption">Harvard physicists Federico Capasso (<em>left</em>), Steven J. Byrnes (<em>right</em>), and Romain Blanchard propose a new way to harvest renewable energy. (Photo by Eliza Grinnell, SEAS Communications.)</p>
<hr />
<p><strong>Challenging convention</strong></p>
<p>Capasso is a world-renowned expert in semiconductor physics, photonics, and solid-state electronics. He co-invented the infrared quantum-cascade laser in 1994, pioneered the field of bandgap engineering, and demonstrated an elusive quantum electrodynamical phenomenon called the repulsive Casimir force—work for which he has received the <a href="https://www.seas.harvard.edu/news/2013/04/federico-capasso-receive-gold-medal-highest-honor-spie">SPIE Gold Medal</a>, the <a href="https://www.seas.harvard.edu/news/2013/05/federico-capasso-receives-prestigious-european-physical-society-prize">European Physical Society Prize for Quantum Electronics and Optics</a>, and the <a href="https://www.seas.harvard.edu/news/2011/09/federico-capasso-receives-2011-jan-czochralski-award">Jan Czochralski Award</a> for lifetime achievement. His research team seems to specialize in rigorously questioning dated assumptions about optics and electronics.</p>
<p>“The mid-IR has been, by and large, a neglected part of the spectrum,” says Capasso. “Even for spectroscopy, until the quantum cascade laser came about, the mid-IR was considered a very difficult area to work with. People simply had blinders on.”</p>
<p>Now, Capasso and his research team are proposing something akin to a photovoltaic solar panel, but instead of capturing incoming visible light, the device would generate electric power by releasing infrared light.</p>
<p>“Sunlight has energy, so photovoltaics make sense; you’re just collecting the energy. But it’s not really that simple, and capturing energy from emitting infrared light is even less intuitive,” says lead author Steven J. Byrnes (AB ’07), a postdoctoral fellow at SEAS. “It’s not obvious how much power you could generate this way, or whether it’s worthwhile to pursue, until you sit down and do the calculation.”</p>
<p>As it turns out, the power is modest but real.</p>
<p>As Byrnes points out, “The device could be coupled with a solar cell, for example, to get extra power at night, without extra installation cost.”</p>
<p><strong>Two proposed devices—one macro, one nano</strong></p>
<p>To show the range of possibilities, Capasso’s group suggests two different kinds of emissive energy harvesters: one that is analogous to a solar thermal power generator, and one that is analogous to a photovoltaic cell. Both would run in reverse.</p>
<p>The first type of device would consist of a “hot” plate at the temperature of the Earth and air, with a “cold” plate on top of it. The cold plate, facing upward, would be made of a highly emissive material that cools by very efficiently radiating heat to the sky. Based on measurements of infrared emissions in Lamont, Oklahoma (as a case study), the researchers calculate that the heat difference between the plates could generate a few watts per square meter, day and night. Keeping the “cold” plate cooler than the ambient temperature would be difficult, but this device illustrates the general principle: differences in temperature generate work.</p>
<p>“This approach is fairly intuitive because we are combining the familiar principles of heat engines and radiative cooling,” says Byrnes.</p>
<p>The second proposed device relies on temperature differences between nanoscale electronic components—diodes and antennas—rather than a temperature that you could feel with your hand.</p>
<p>“If you have two components at the same temperature, obviously you can’t extract any work, but if you have two different temperatures you can,” says Capasso. “But it’s tricky; at the level of the electron behaviors, the explanation is much less intuitive.”</p>
<p class="fright"><img decoding="async" src="https://www.seas.harvard.edu/sites/default/files/images/news/Circuits_400px_0.jpg" alt="" width="400" height="366" />Three diode-resistor generator circuits with different temperature inputs. A circuit at thermal equilibrium (A) generates no current; (B) is a conventional rectifier circuit. The Harvard team proposes a twist—shown in (C). (Image courtesy of Federico Capasso and PNAS.)</p>
<p>“The key is in these beautiful circuit diagrams,” he adds (see image at right). “We found they had been considered before for another application—in 1968 by J.B. Gunn, the inventor of the Gunn diode used in police radars—and been completely buried in the literature and forgotten. But to try to explain them qualitatively took a lot of effort.”</p>
<p>Simply put, components in an electrical circuit can spontaneously push current in either direction; this is called electrical noise. Gunn’s diagrams show that if a valve-like electrical component called a diode is at a higher temperature than a resistor, it will push current in a single direction, producing a positive voltage. Capasso’s group suggests that the role of the resistor could be played by a microscopic antenna that very efficiently emits the Earth’s infrared radiation toward the sky, cooling the electrons in only that part of the circuit.</p>
<p>The result, says Byrnes, is that “you get an electric current directly from the radiation process, without the intermediate step of cooling a macroscopic object.”</p>
<p>According to the paper, a single flat device could be coated in many of these tiny circuits, pointed at the sky, and used to generate power.</p>
<p><strong>Technological challenges—and promise</strong></p>
<p>The optoelectronic approach, while novel, could be feasible in light of recent technological developments—advances in plasmonics, small-scale electronics, new materials like graphene, and nanofabrication. The Harvard team says a strength of their research is that it clarifies the remaining challenges.</p>
<p>“People have been working on infrared diodes for at least 50 years without much progress, but recent advances such as nanofabrication are essential to making them better, more scalable, and more reproducible,” says Byrnes.</p>
<p class="pullquote">We’re talking about the use of physics at the nanoscale for a completely new application.</p>
<p>However, even with the best modern infrared diodes, there is a problem. “The more power that’s flowing through a single circuit, the easier it is to get the components to do what you want. If you’re harvesting energy from infrared emissions, the voltage will be relatively low,” explains Byrnes. “That means it’s very difficult to create an infrared diode that will work well.”</p>
<p>Engineers and physicists, including Byrnes, are already considering new types of diodes that can handle lower voltages, such as tunnel diodes and ballistic diodes. Another approach would be to increase the impedance of the circuit components, thereby raising the voltage to a more practical level. The solution might require a little of both, Byrnes predicts.</p>
<p>Speed presents another challenge.  “Only a select class of diodes can switch on and off 30 trillion times a second, which is what we need for infrared signals,” says Byrnes. “We need to deal with the speed requirements at the same time we deal with the voltage and impedance requirements.”</p>
<p>“Now that we understand the constraints and specifications,” Byrnes adds, “we are in a good position to work on engineering a solution.”</p>
<p>Romain Blanchard, who completed his Ph.D. at Harvard SEAS, was also a coauthor of the paper in <em>PNAS</em>. This research was supported in part by King Abdullah University of Science and Technology.</p>
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<div class="block-inner clearfix">Source: <a href="https://www.seas.harvard.edu/news/2014/03/infrared-new-renewable-energy-source">https://www.seas.harvard.edu/news/2014/03/infrared-new-renewable-energy-source</a></div>
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<p>The post <a href="https://thermomedica.nl/infrared-energy/">Infrared energy: A new renewable source?</a> appeared first on <a href="https://thermomedica.nl">INFRAROOD THERAPIE | Warmte &amp; Licht | THERMO MEDICA ®</a>.</p>
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		<title>Infrarood en zonnepanelen</title>
		<link>https://thermomedica.nl/infrarood-en-zonnepanelen/</link>
		
		<dc:creator><![CDATA[Madhava Overgoor]]></dc:creator>
		<pubDate>Sat, 20 Dec 2014 07:34:05 +0000</pubDate>
				<category><![CDATA[Infrarood en Toepassingen]]></category>
		<category><![CDATA[Infrarood]]></category>
		<category><![CDATA[nanotechnologie]]></category>
		<category><![CDATA[Photons]]></category>
		<category><![CDATA[Science]]></category>
		<category><![CDATA[zonnecellen]]></category>
		<category><![CDATA[Zonnepanelen]]></category>
		<guid isPermaLink="false">https:/?p=1419</guid>

					<description><![CDATA[<p>Infrarood en zonnepanelen De Rijksuniversiteit Groningen en Stichting FOM hebben aangetoond dat infrarood licht middels upconversie omgezet kan worden tot bruikbare energie voor zonnepanelen. Er bestaat nog wel ruimte voor verbetering, maar kan zonnecellen in de toekomst wel eens een stuk efficiënter maken.  Vandaag de dag zijn zonnepanelen redelijk in staat om zichtbaar licht om te zetten in energie. Maar [&#8230;]</p>
<p>The post <a href="https://thermomedica.nl/infrarood-en-zonnepanelen/">Infrarood en zonnepanelen</a> appeared first on <a href="https://thermomedica.nl">INFRAROOD THERAPIE | Warmte &amp; Licht | THERMO MEDICA ®</a>.</p>
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<h2 class="entry-title">Infrarood en zonnepanelen</h2>
<h4><strong>De Rijksuniversiteit Groningen en Stichting FOM hebben aangetoond dat infrarood licht middels upconversie omgezet kan worden tot bruikbare energie voor zonnepanelen. </strong><strong>Er bestaat nog wel ruimte voor verbetering, maar kan zonnecellen in de toekomst wel eens een stuk efficiënter maken. </strong></h4>
<p>Vandaag de dag zijn zonnepanelen redelijk in staat om zichtbaar licht om te zetten in energie. Maar er gaat tegelijkertijd ook heel veel licht verloren. Er is bekend dat ongeveer de helft van al het zonlicht dat het aardoppervlak bereikt bestaat uit infrarood licht. Tot voor kort kon een zonnepaneel daar weinig mee. Het infrarode licht was namelijk te zwak en had te weinig energie om elektronen vrij te maken.</p>
<p><strong>Moleculen, Infrarood en zonnepanelen</strong><br />
Op het probleem van energieomzetting hebben de Wetenschappers van de Rijksuniversiteit Groningen en Stichting FOM nu iets bedacht meldt het blad <em>Nature Photonics</em>. Er worden speciale moleculen die de energie van het infrarode licht opvangen gebruikt. Deze moleculen geven energie door aan nanodeeltjes, deze nanodeeltjes maken op hun beurt weer energie van twee zwakke fotonen en zetten deze om in één sterk signaal. Deze aanpak is niet nieuw en bestaat al een tijdje bekend onder de naam ‘upconversie’, maar de onderzoekers hebben deze techniek nu flink verbeterd. “Er bestaan anorganische materialen, gemaakt van zeldzame aardmetalen, die dit upconversie-proces kunnen bewerkstellingen,” vertelt onderzoeker Kees Hummelen. “Maar deze materialen absorberen zelf erg weinig infrarode fotonen. Daarom hebben we er organische moleculen aan gekoppeld die deze fotonen opvangen en de energie doorgeven aan het upconversiemateriaal. Daarmee is het hele proces van infraroodabsorptie, upconversie en zichtbaar licht uitzenden met een factor 3300 toegenomen.”</p>
<div class="wistudat"><b>WIST U DAT…</b></p>
<div class="wistudat2">…wetenschappers ook op andere manieren infrarood licht proberen te oogsten?</div>
</div>
<p><strong>Werk aan de winkel</strong><br />
Een prachtig resultaat. Toch zit het werk van de onderzoekers er nog lang niet op. “Ook met onze antennes vangen we nog steeds maar een beperkt deel van het infrarode licht op. Daar valt nog winst te behalen.” Een ander nadeel is dat de twee fotonen kort na elkaar in het materiaal moeten komen, willen ze samen één sterk signaal voortbrengen. “In de praktijk is de efficiëntie van dit proces nog erg laag. Maar het oogsten is nu alvast veel beter gelukt, dat is stap 1!”</p>
<p>Het werk van de wetenschappers biedt zoals gezegd vooral veel mogelijkheden voor zonnecellen. “Een Duitse groep gaat onze nanokristallen met antennes in zonnecellen inbouwen, om ze in de praktijk te testen.” Maar het onderzoek van Hummelen en zijn collega’s heeft meer implicaties. Bijvoorbeeld voor de medische wereld. Zo kunnen we door hun onderzoek straks wel eens een beter beeld van het menselijk lichaam krijgen. “Infrarood licht dringt dieper in biologische weefsels door dan zichtbaar licht. Wanneer je verbindingen die upconversie uitvoeren, laat binden aan specifieke cellen in weefsels, kan je door infraroodbelichting afbeeldingen maken.”</p>
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<p>The post <a href="https://thermomedica.nl/infrarood-en-zonnepanelen/">Infrarood en zonnepanelen</a> appeared first on <a href="https://thermomedica.nl">INFRAROOD THERAPIE | Warmte &amp; Licht | THERMO MEDICA ®</a>.</p>
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