From what we can tell, the solar cells would bring in just enough power to run some sort of
heating device in the hat and gloves - perhaps thin wiring like an electric blanket, but on a smaller scale.
Fire anxiety — Quality vaporizers are generally pretty safe, but having an electrical
heating device in your home can be a source of anxiety for parents, ie, worrying about fires.
Not exact matches
«We do have a provisional patent on the actual
heat dissipation methods involved
in the
device, because we're pumping
heat away from the body with this technology and we've actually found a way to very consistently dissipate that underneath clothing to allow people to wear it throughout their days,» said Paulin.
The technology would allow the
device to analyse the display's structure, spot anomalies, and slowly use
heat to modify the scraped area by remolding it
in a way as close as possible to the original.
The company, launched
in 2009, started by selling medical refrigerators used
in labs and hospitals but recently expanded into fiber - optic
devices, which
heat up as light and data travel through them.
In the winter, dPoint's device helps to bring in fresh air but prevents heat and moisture from escapin
In the winter, dPoint's
device helps to bring
in fresh air but prevents heat and moisture from escapin
in fresh air but prevents
heat and moisture from escaping.
«Samsung expects to see its sales of mobile
devices increase with the rollout of flagship products and new models, but profitability may suffer due to a
heated race over price and product specifications,» the company said
in July.
Hot food, a
heat source and charged - up smartphones, all
in an easy - to - carry
device?
Long, lazy turns
in front of high -
heat - emitting
devices are for winter soups and stews, peeples!
In a medium size saucepan over medium
heat, combine the milk, sugars, brown rice syrup, and cream of tartar; stir with a silicone spatula (or any silicone
device capable of such a task) then let the mixture cook for 25 minutes, without stirring.
The advanced food processing
device can
heat 1,000 kg of product from 15 °C to 90 °C
in 5 minutes with no burn or particulate damage.
The patented Vaction ™ technology used
in Steam Infusion is a highly effective
heating and mixing
device.
If you're concerned, don't put plastic bottles of any type
in boiling water, the dishwasher, microwave, or any other
device that uses
heat because high temperatures can release chemicals from the plastic.
The mechanism is based on
heating water filled
in the vessel of the
device after it is switched on.
This product type uses water
in certain form
in order to warm the bottle and there comes an issue with mineral deposits that form somewhere on the
device, mainly
in the warming chamber or on the
heating element.
The
device applies
in particular
in winter months, when the indoor air gets too dry, as your
heating system steals the natural moisture present
in it.
Electronic
devices — such as
heating or cooking
devices, electric fans, portable air conditioners, and coffee pots — are prohibited
in the hospital so we can maintain a safe environment for everyone.
Combined with the included carbon filter belts, you can hook up all of your relevant
devices to control the humidity, light, air, and
heat in your tent ecosystem!
An electric current will not only
heat a hybrid metamaterial, but will also trigger it to change state and fade into the background like a chameleon
in what may be the proof - of - concept of the first controllable metamaterial
device, or metadevice, according to a team of engineers.
British Antarctic Survey scientists placed panels equipped with
heating elements on the seabed
in Antarctica and warmed the
devices by either 1 or 2 degrees Celsius.
After ten 15 - second exposures over five minutes to the vapor from iQOS, a
heat - not - burn
device that has been test - marketed
in several countries, blood vessel function decreased by 58 percent.
«
In most systems, heat flow is equal in both directions, so there are no thermal devices like electrical diode
In most systems,
heat flow is equal
in both directions, so there are no thermal devices like electrical diode
in both directions, so there are no thermal
devices like electrical diodes.
Heat - not - burn
devices may eliminate users» exposure to tobacco smoke, but the vapor they produce has the same negative impact on blood vessel function as smoking, according to a preliminary animal study presented at the American Heart Association's Scientific Sessions 2017, a premier global exchange of the latest advances
in cardiovascular science for researchers and clinicians.
Researchers are proposing a new technology that might control the flow of
heat the way electronic
devices control electrical current, an advance that could have applications
in a diverse range of fields from electronics to textiles.
The
device consists of a doughnut - shaped reactor called a tokamak, wrapped
in superconducting magnets that squeeze and
heat a plasma of hydrogen isotopes to the point of fusion.
Controlling the
heat and current of particles
in this way could open up the door to various strategies for designing quantum transport
devices with directionality control of the injection of currents for applications
in thermoelectrics, spintronics, phononics and detection, among others.
Among other adjustments that could help double fuel economy are turbocharging with smaller, more efficient engines that produce the same level of power; advanced
heat management and cooling systems, which reuse the
heat produced
in the engine for energy; weight reduction, including broader use of high - strength steel that is already
in some cars today; better aerodynamics; more efficient air conditioners, transmissions and lighting
devices (including headlights); and increased electrification leading to full hybridization with electric motor and regenerative breaking — all of which currently exist.
From your hot car to your warm laptop, every machine and
device in your life wastes a lot of energy through the loss of
heat.
Heat flow
in novel nanomaterials could help
in creating environmentally friendly and cost - effective nanometric - scale energy
devices.
Comparison of the new model proposed by UAB researchers and the classic model to explain the behavior of
heat in an electronic
device.
This will help physicists and
device engineers to design better quantum capacitors, an array of subatomic power storage components capable to keep high energy densities, for instance,
in batteries, and vertical transistors, leading to next - generation optoelectronics with lower power consumption and dissipation of
heat (cold
devices), and better performance.
A growing interest
in thermoelectric materials — which convert waste
heat to electricity — and pressure to improve
heat transfer from increasingly powerful microelectronic
devices have led to improved theoretical and experimental understanding of how
heat is transported through nanometer - scale materials.
In their paper, they studied how thermal noise flows through quantum
devices and they devised a method that can prevent the
heat flow to warm up the sensitive quantum
device.
«With this
in mind, we hope our work can support the development of energy - efficient
devices that can function
in conditions of extreme
heat or radiation.»
Understanding how
heat behaves
in ultra-small gaps is critical for advancing next - generation data storage and
devices that convert
heat directly into electricity.
By taking clever advantage of the interplay between light, electrons on the surface of metals, and
heat, researchers at the National Institute of Standards and Technology (NIST) have for the first time created a plasmomechanical oscillator (PMO), so named because it tightly couples plasmons — the collective oscillations of electrons at the surface of a metal nanoparticle — to the mechanical vibrations of the much larger
device it's embedded
in.
In the morning, the chamber is closed, and sunlight entering through a window on top of the
device then
heats up the MOF, which liberates the water droplets and drives them — as vapor — toward the cooler condenser.
Scale formation also lowers the efficiency of
heating and cooling
devices and can result
in machine damage.
Markovic, who was Mlack's advisor at Johns Hopkins at the time, suggested that,
in order to recreate it without having to continually blow up
devices, they could thermally anneal it, a process
in which they put it into a furnace and
heat it to a certain temperature.
Researchers have found an unexpected way to control the thermal conductivity of two - dimensional (2 - D) materials, which will allow electronics designers to dissipate
heat in electronic
devices that use these materials.
The PTMA is
in a class of electrically active polymers that could bring inexpensive transparent solar cells; antistatic and antiglare coatings for cellphone displays; antistatic coverings for aircraft to protect against lightning strikes; flexible flash drives; and thermoelectric
devices, which generate electricity from
heat.
Because of the unusual way the material interacts with infrared light, the finding, which appears October 21
in Physical Review X, could lead to camouflage against
heat - sensing cameras and to efficient
heating and cooling
devices.
In those thermoelectric
devices, a
heat current causes a separation of electrical charges.
High power achieves a target temperature on the surface of the metal
device quickly, before there is much time for
heat to accumulate
in surrounding tissues.
The
device's ability to absorb electromagnetic energy without
heating up has direct applications
in imaging, sensing and lighting.
The trend
in electronics toward miniaturization squeezes more chips into ever smaller
devices, leading to intense
heat buildup.
In an electronic
device, extra resistance can generate
heat or drain battery power faster.
In their
device, the core converts the absorbed light into
heat.
In their initial small - scale lab versions, they showed the stored
heat can remain stable for at least 10 hours, whereas a
device of similar size storing
heat directly would dissipate it within a few minutes.
In a thermo - photovoltaic
device, external
heat causes the material to glow, emitting light that is converted into an electric current by an absorbing photovoltaic element.