Tag Archives: heat exchangers

In the ATS Labs – Where Thermal Solutions Advance to Meet Industry Demands

Thermal management innovations need to match the rapid pace at which the electronics industry is advancing. As consumers demand new and more powerful devices or greater amounts of information at faster speeds, cooling solutions of the past will not be enough. Today’s cooling solutions must be smaller, lighter, and offer higher performance, but also need to be cost-effective, meet demanding project specifications, and be reliable for many years.

Advanced Thermal Solutions, Inc. (ATS) understands the importance of creating cutting-edge thermal solutions for its customers and has geared its thermal design capability and its research and development to match the innovations taking place in electronics design.

ATS Labs

An ATS engineer assembles a rig for testing cold plates in one of ATS’ six state-of-the-art labs. (Advanced Thermal Solutions, Inc.)

To meet the need for innovative solutions, ATS engineers are hard at work in the company’s six state-of-the-art laboratories at the ATS headquarters, located in Norwood, Mass. (south of Boston). Thermal issues of all kinds are recognized, broken down, and resolved and cooling solutions are designed, simulated, prototyped, and rigorously tested in these research-grade facilities.

When someone thinks of a research lab, the initial picture is scientists in white coats working for major corporations, such as IBM, Microsoft, or Google, but the development of new ideas is an essential tool for any company in the technology field. Working with empirical tests in a lab environment pushes concepts from the white board or the computer screen to reality. There comes a time when engineers need to produce tangible data to ensure that a design works as planned.

ATS thermal engineers are no different. They use state-of-the-art instruments and software in each of the six labs to conduct a long list of characterization, quality-assurance, and validation tests. In addition to finding custom cooling solutions for customers, ATS engineers produce thermal management products for commercial uses, including a variety of next generation heat sink, heat pipe, vapor chamber, and liquid cooling designs.

Engineers test ATS instruments using a wind tunnel and sensors in the Characterization Lab. (Advanced Thermal Solutions, Inc.)

Among the most common tests performed in the ATS labs are:

• Measurements of air velocity, direction, pressure and temperature;
• Characterization of heat sink designs, fans and cold plates
• Flow visualization of liquid and air flow
• Image visualization characterization using infrared and liquid crystal thermography.

Many of the instruments that these tests are performed on were designed and fabricated by ATS. That includes open-loop, closed-loop, and bench-top wind tunnels; the award-winning iQ-200™, which measures air temperature, velocity, and pressure with one instrument; and the thermVIEW™ liquid crystal thermography system. Engineers also use specially-designed sensors, such as the ATS Candlestick Sensor, to get the most accurate analysis possible.

Smoke flow visualization tests run in ATS wind tunnels demonstrate how air flows through a system. (Advanced Thermal Solutions, Inc.)

Heat pipes and vapor chambers are increasingly common cooling solutions, particularly for mobile devices and other consumer electronics, and ATS engineers are working to expand the company’s offerings for these solutions and to develop next generation technology that optimizes the thermal performance of these products. This research involves advanced materials, new fabrication methods, performance testing, and innovative designs that are ready for mass production.

ATS engineer Vineet Barot sets up a thermal imaging camera for temperature mapping studies in the lab. (Advanced Thermal Solutions. Inc.)

ATS has also developed products to meet the growing demand across the electronics industry for liquid cooling systems. From new designs for recirculating and immersion chillers to multi-channel cold plates to tube-to-fin heat exchangers, ATS is continuing to expand its line of liquid cooling solutions to maximize the transfer of heat from liquid to air and researching new manufacturing methods, advanced materials, and other methods of enhancing the technology.

As liquid cooling technology has grown, ATS has met this demand with new instruments and lab capabilities, such as the iFLOW-200™, which measures a cold plate’s thermal and hydraulic characteristics, and full liquid loops to test ATS products under real-world conditions.

ATS Labs

ATS engineer Reza Azizian (right) works with intern Vladislav Blyakhman on a liquid cooling loop in the lab. (Advanced Thermal Solutions, Inc.)

The labs at ATS are up to even the toughest electronics cooling challenges that the company’s global customers present. Thanks to its extensive lab facilities, ATS has provided thousands of satisfied customers with the state-of-the-art thermal solutions that they demand.

For more information about Advanced Thermal Solutions, Inc. (ATS) thermal management consulting and design services, visit www.qats.com/consulting or contact ATS at 781.769.2800 or ats-hq@qats.com.

What is Geothermal Cooling and Heating Technology and How Does it Work

By Norman Quesnel
Senior Member of Marketing Staff
Advanced Thermal Solutions, Inc. (ATS)

If you cross-sectioned the Earth, it would show a multi-layered structure with a solid iron core spinning in a sea of liquid iron and sulfur. You would also find great quantities of flowing heat starting at the very center and moving outward.

The flow of heat from Earth’s interior to the surface is estimated at 47 terawatts, i.e. 47 trillion watts, and comes from two main sources in roughly equal amounts: the radiogenic heat produced by the radioactive decay of isotopes in the mantle and crust and the primordial heat left over from the formation of the Earth 4-1/2 billion years ago.

In a recent study, scientists estimated the temperature of the center of the Earth at 6,000°C (10,800°F) – about as hot as the surface of the sun. [2]

Geothermal Cooling

Fig. 1. Earth’s Outermost Layer, the Crust, and Comprises Just 1% of Our Planet’s Mass. [2]

In fact, more than 99% of the inner Earth is hotter than 1,000°C (1,800°F). Unlike the sun, the Earth is much cooler at its outer crust and on its outside surface. But even at cooler temperatures, the shallow depths of the Earth’s crust provide a geothermal resource for both heating and cooling structures built above the ground.

By drilling deeper down, but still within the crust, much higher temperatures can be harnessed to help generate power that can in turn provide industrial and even community-wide levels of heating and cooling. High-temperature geothermal heat has tremendous potential because it represents an inexhaustible, and virtually emissions-free, energy source. [3]

Geothermal Cooling

Fig. 2. Simple Diagram of Near Surface Heating and Cooling Geothermal System. [4]

Near Surface Heating and Cooling Systems

The ground absorbs nearly half of the solar energy the planet receives. As a result, the Earth remains at a constant, moderate temperature just below its surface year-round. However, air temperature varies greatly from summer to winter, making air source (traditional) heating and cooling least efficient when you need it the most. [5]

Geothermal heat pumps take advantage of the moderate temperatures typically found at shallow depths to boost efficiency and reduce the operational costs of architectural heating and cooling systems. Unlike conventional heating and air conditioning systems, which use the outside air to absorb and release heat, geothermal systems use heat pumps to transfer heat from below the surface.

Geothermal Cooling

Fig. 3. Four Basic Types of Geothermal Heat Pump System Shown in a US Department of Energy Illustration. Open Loop Systems Can Use Either a Man-made or Natural Water Reservoir. [6]

The pumps connect to closed loops of plastic pipes buried either horizontally or vertically in the ground below the frost line (about 100-200 meters), where the temperature is consistently between 40-80°F depending on location. Called ground loops, the underground pipes are filled with water and sealed tight except where they are connected to the geothermal heating and cooling system inside the building.

In winter, water running through the loops will absorb heat from the ground and pipe it into the home, while the system will run in the opposite direction to keep things cool during the scorching summer months. The pipes are connected to a heat pump and water heater inside the house and users can control the indoor climate through a smart thermostat.

There are four basic configurations for geothermal heat pump ground loops. Three of them are closed-loop systems that use a self-contained water and an anti-freeze solution. The open-loop system uses ground water or water from a well. [6]

Geothermal Cooling

Fig 4. Geothermal Pumps Can Efficiently Heat and Cool Homes and Commercial Buildings. [7]

Newer geothermal systems can be installed at shallower depths, less than 50 feet. Even at these levels, the ground can provide a heat source in colder weather and serve as a cooling heat sink when surface temperatures are hot. [8]

There are several providers of geothermal heating and cooling systems. Google’s parent company, Alphabet, is among them with its newly created startup, Dandelion. Originally conceived at X, Alphabet’s innovation lab, Dandelion is now an independent company offering geothermal heating and cooling systems to homeowners, starting in the northeastern U.S. [9]

To put in the ground loops, Dandelion uses its “clean drilling technology” to dig a few small holes in the yard, each only a few inches wide. Then a technician will install the other components inside the house, and the system should be up and running in two or three days. After that, the only regular maintenance is an air filter change every six to 12 months.

Deeper Down Geothermal Systems

The Kola borehole, on Russia’s Kola Peninsula is the deepest mankind has ever drilled into the Earth’s crust. After nearly 15 years of boring, the hole was 12,262 meters (40,230 feet) – over 12 kilometers or 7.6 miles deep. At that depth, the temperature was 185°C (356°F). [10]

Geothermal Cooling

Fig. 5. Very Hot, Deep Underground Thermal Energy Can Convert Water to Steam to Power Turbine Generators in Power Plants. [11]

Even at half that depth, there can be much more heat than a near-surface geothermal system can access. The Norwegian company Rock Energy wants to be an international leader in high power geothermal heat and energy. A pilot plant has been planned for Oslo that will collect heat from 5,500 meters deep. The high temperatures from this depth can heat water to 90-95°C (194-203°F) and can be used in district heating plants. [12]

Rock Energy is planning to drill two wells, an injection well where cold water is pumped down, and a production well where hot water flows back up. Between these will be so-called radiator leads that connect the wells. The water is then exchanged with water in a district heating plant managed by the Norwegian power company Hafslund. [13]

Geothermal Cooling

Figure 6. Water is Superheated by Deeply Located Hot Rocks and Pumped to the Surface Where It Converts a Separate Liquid to Turbine-Driving Steam. [14]

A hot dry rock system potentially allows geothermal energy to be captured from hot rocks, 3-5 km (1.8-3.1 miles) underground. In operation, cold water is pumped at high pressure down into the very high-temperature, fractured hot rock. The water becomes superheated as it passes through the rock on its way to the extraction boreholes.

In Figure 6, the diagram of a hot dry rock system shows hot water emerging from the borehole and directed through a heat exchanger. After giving up its heat, the cooled water is recycled back down the injection borehole in the hot rock bed. The working fluid, a low boiling point liquid, circulating through the secondary circuit of the heat exchanger is vaporized by the heat extracted from the well water and used to drive the power plant’s turbines. [14]

At both shallow depths and miles down, the Earth offers thermal energy that can harnessed for heating, cooling and power generation. Compared to most other processes, geothermal energy is cleaner, continuous and, as technology advances, a low cost alternative to fossil fuels or to solar and wind-powered systems.

References
1. https://en.wikipedia.org/wiki/Earth%27s_internal_heat_budget
2. https://www.geokraftwerke.de/en/geokraftwerke/geothermal-energy/geothermics.html
3. https://www.sciencedaily.com/releases/2015/10/151023094414.htm
4. http://www.coolingzone.com/index.php?read=1279
5. http://www.climatemaster.com/residential/how-geothermal-works/
6. https://www.pinterest.com/pin/524387950340721445/
7. https://www.geoexchange.org/geothermal-101/
8. https://en.wikipedia.org/wiki/Geothermal_heat_pump
9. https://dandelionenergy.com/
10. https://en.wikipedia.org/wiki/Kola_Superdeep_Borehole
11. http://photonicswiki.org/index.php?title=Survey_of_Renewables
12. https://www.qats.com/cms/2017/04/25/industry-developments-district-cooling-systems/
13. https://www.sintef.no/en/latest-news/energy-underfoot-/
14. http://www.mpoweruk.com/geothermal_energy.htm

For more information about Advanced Thermal Solutions, Inc. (ATS) thermal management consulting and design services, visit www.qats.com/consulting or contact ATS at 781.769.2800 or ats-hq@qats.com.

ATS Releases New Line of Tube-to-Fin, Liquid-to-Air Heat Exchangers

Advanced Thermal Solutions, Inc. (ATS) has introduced a new line of tube-to-fin, liquid-to-air heat exchangers that “push the boundaries of the technology with the industry’s highest density fins.” These new heat exchangers, available with or without fans, come in seven different sizes and 49 different options and are part of the array of liquid cooling products that ATS offers.

Heat Exchangers

ATS has released a new line of tube-to-fin, liquid-to-air heat exchangers that boast the industry’s highest density fins. (Advanced Thermal Solutions, Inc.)

ATS heat exchangers maximize heat transfer from fluid to air, which allows liquid to be cooled to lower temperatures than other heat exchangers on the market. The fins and tubes are made of copper and stainless steel and are suitable for a variety of different liquids, including water, dielectric fluids and custom designed heat transfer fluids.

Read the full product release announcement at https://www.qats.com/News-Room/Press-Releases-Content/1183.aspx.

ATS heat exchangers can be used in a variety of applications including laser cooling, cooling medical equipment and imaging devices, compressor cooling, semiconductor processing, HVAC, food and beverage processing, and other liquid cooling applications.

The following table shows the different heat transfer capacities and dimensions of the different heat exchangers that ATS has released:

Heat Exchangers

The heat exchangers have silver-solder brazed joints and have been internally cleaned and externally coated for corrosion protection. They are available with or without fans.

Watch the short video below to learn more:

For more information about Advanced Thermal Solutions, Inc. thermal management consulting and design services, visit www.qats.com or contact ATS at 781.769.2800 or ats-hq@qats.com.

How is a Heat Exchanger Used in Liquid Cooling

A heat exchanger is a device that transfers heat from a fluid (liquid or gas) to pass to a second fluid without the two fluids mixing or coming into direct contact. Heat exchangers are commonly used in liquid cooling systems to dissipate heat from a fluid that has passed over a cold plate attached to the heat-producing component. The cool fluid is pumped through the system and back across the cold plate.

Heat Exchanger

An example of a standard liquid cooling loop using a heat exchanger to transfer heat from the liquid to the ambient. (Advanced Thermal Solutions, Inc.)

Heat exchangers are designed to maximize the surface area of the wall between the two fluids, while minimizing the resistance to fluid flow through the exchanger. The addition of fins or corrugations in one or both directions increases the surface area and increases the heat transfer capacity of the heat exchanger.

There are several types of liquid-to-air heat exchangers.

In a shell and tube heat exchanger, one fluid flows through a series of metal tubes and the second fluid is pumped through a shell that surrounds them. The fluid flow can be either parallel (flowing in the same direction), counterflow (flowing in opposite directions) or crossflow (flows are perpendicular to each other).

Tube-to-fin heat exchangers (as shown in the GIF above) use fins surrounding two tubes that carry the fluids. The fins increase the surface area and maximize heat transfer to the ambient. Some finned tube heat exchangers use natural convection and other can include fans to increase the airflow and heat transfer capacity.

Plate and frame heat exchangers have two rectangular end members holding together a series of metal plates with holes in each corner to allow the liquids to pass through. Each of the plates has a gasket to seal the plates and arrange the flow of the fluids between the plates. Brazed plate heat exchangers avoid the potential for leakage by brazing the plates together. Plate and frame heat exchangers are commonly used in food processing.

Common applications for heat exchangers include telecommunications, process cooling, power electronics, medical device and medical imaging, automotive, industrial, and HVAC.

Watch the video below to learn more:

For more information about Advanced Thermal Solutions, Inc. thermal management consulting and design services, visit www.qats.com or contact ATS at 781.769.2800 or ats-hq@qats.com.

Industry Developments: Heat Exchangers for Electronics Cooling

By Norman Quesnel, Senior Member of Marketing Staff
Advanced Thermal Solutions, Inc.

(This article will be featured in an upcoming issue of Qpedia Thermal e-Magazine, an online publication dedicated to the thermal management of electronics. To get the current issue or to look through the archives, visit http://www.qats.com/Qpedia-Thermal-eMagazine. To read other stories from Norman Quesnel, visit https://www.qats.com/cms/?s=norman+quesnel.)

Heat exchangers are thermal management tools that are widely used across a variety of industries. Their basic function is to remove heat from designated locations by transferring it into a fluid. Inside the heat exchanger, the heat from this fluid passes to a second fluid without the fluids mixing or coming into direct contact. The original fluid, now cooled, returns to the assigned area to begin the heat transfer process again.

The fluids referred to above can be gases (e.g. air), or liquids (e.g. water or dielectric fluids), and they don’t have to be symmetrical. Therefore, heat exchangers can be air-to-air, liquid-to-air, or liquid-to-liquid. Typically, fans and/or pumps are used to keep these heat transfer medium in motion and heat pipes may be added to increase heat transfer capabilities.

Figure 1 shows a basic heat exchanger schematic. A hot fluid (red) flows through a container filled with a cold fluid (blue) but the two fluids are not in direct contact.

Heat Exchanger

Figure 1. In a Simple Heat Exchanger Heat Transfers from the Hot (Red) Fluid to the Cold (Blue) Fluid, and the Cooler After Fluid Re-Circulates to Retrieve More Heat. [1]

One example of a common heat exchanger is the internal combustion engine under the hood of most cars. A fluid (in this case, liquid coolant) circulates through radiator coils while another fluid (air) flows past these coils. The air flow lowers the liquid coolant’s temperature and heats the incoming air.

Applied to electronics enclosures, heat exchangers draw heated air from a cabinet, cool it, and then return the cooled air to the cabinet. These heat exchangers should be designed to provide adequate cooling for expected worst case conditions. Typically, those conditions occur when the ambient is the highest and when electrical loads through the enclosure are very high. Under typical conditions, heat exchangers can cool cabinet interiors to within 5°F above the ambient air temperature outside the enclosure.

Air-to-Air

Air-to-air heat exchangers have no loops, liquids or pumps. Their heat dissipation capabilities are moderate. Common applications are in indoor or outdoor telecommunications cabinetry or in manufacturing facilities that don’t have a lot of dust or debris.

Air-to-air heat exchangers provide moderate to good cooling performance. They don’t allow outside air to enter or mix with the air inside the enclosure. This protects the enclosure’s contents from possible contamination by dirt or dust, which could damage sensitive electronics and electrical devices and cause malfunctions.

An example of higher performance, air-to-air heat exchangers is the Aavid Thermacore HX series. These heat exchangers feature rows of heat pipes that add effective, two-phase heat absorbing properties when moving hot air away from a cooling area. The liquid inside the heat pipes turns to vapor. This transition occurs inside a hot cabinet. (See Figure 2)

The vapor travels to the other end of the heat pipe, which is outside the cabinet. Here it is cooled by a fan, transitions back to liquid form, and cycles back inside the cabinet environment.

Heat Exchangers

Figure 2. An Air-to-Air Heat Exchanger with Heat Pipes Extending Inside (top) and Outside (bottom) a Cabinet. Internal Heat is Transferred Outside the Enclosure. (Aavid Themacore) [1]

Other air-to-air heat exchangers feature impingement cooling functionality that can provide better performance than using heat pipes. Aavid Thermacore’s HXi Impingement core technology uses a folded fin core that separates the enclosure inside and outside. A set of inside fans draws in the hotter, inside air and blows it toward the fin core. This inside impingement efficiently transfers the heat to the fin core. Similarly, a set of outside fans draws in the cooler, ambient air and blows it toward the outer side of the fin core removing the waste heat. See Figure 3 below.

Heat Exchangers

Figure 3. Air-to-Air Heat Exchangers with Double-Sided Impingement Cooling Technology Can Move Twice the Heat Load of Conventional Exchangers. (Aavid Themacore) [3]

Liquid-to-Air

In some electronic cabinets, high power components can’t be cooled by circulating air alone or the external ambient air temperature is not cool enough to allow an air-to-air heat exchanger to solve the problem unaided. In these applications, liquid-to-air heat exchangers provide additional cooling to maintain proper cabinet temperatures.

For example, in a situation where heat is collected through a liquid-cooled cold plate attached directly to high power components. Even with the cold plate, the ambient air external to the cabinet is not cool enough to maintain the internal cabinet temperature at an acceptable or required level. Here, a liquid coolant in an active liquid-to-air heat exchanger can be used to cool the enclosure.

Heat Exchangers

Figure 4. Tube-to-Fin, Liquid-to-Air Heat Exchangers Provide High-Performance Thermal Transfer. [4] (Advanced Thermal Solutions, Inc.)

Advanced Thermal Solutions, Inc. (ATS) tube-to-fin, liquid-to-air heat exchangers have the industry’s highest density of fins. This maximizes heat transfer from liquid to air, allowing the liquid to be cooled to lower temperatures than other exchangers can achieve. All tubes and fins are made of copper and stainless steel to accommodate a wide choice of fluids.

Available with or without fans, ATS heat exchangers are available in a range of sizes and heat transfer capacities up to 250W per 1°C difference between inlet liquid and inlet air temperatures. They can be used in a wide variety of automotive, industrial, HVAC, electronics and medical applications. [4]

Heat Exchanger

Figure 5. Small, Light-Weight Liquid-to-Liquid Heat Exchanger Provides Efficient Cooling Performance. [5]

Lytron’s liquid-to-liquid heat exchangers are only 10-20% the size and weight of conventional shell-and-tube designs. Their internal counter-flow design features stainless steel sheets stamped with a herringbone pattern of grooves, stacked in alternating directions to form separate flow channels for the two liquid streams. This efficient design allows 90% of the material to be used for heat transfer. Copper-brazed and nickel-brazed versions provide compatibility with a wide range of fluids. [5]

Nanofluids

The development of nanomaterials has made it possible to structure a new type of heat transfer fluid formed by suspending nanoparticles (particles with a diameter lower than 100nm). A mixture of nanoparticles suspended in a base liquid is called a nanofluid. The choice of base fluid depends on the heat transfer properties required of the nanofluid. Water is widely used as the base fluid. Experimental data indicates that particle size, volume fraction and properties of the nanoparticles influence the heat transfer characteristics of nanofluids. [5]

When compared to conventional liquids, nanofluids have many advantages such as higher thermal conductivity, better flow, and the pressure drop induced is very small. They can also prevent sedimentation and provide higher surface area. From various research, it has been found that adding even very small amounts of nanoparticles to the base fluid can significantly enhance thermal conductivity.

Heat Exchangers

Figure 6. 3D Design of Curved Tube Heat Exchanger. Increased Turbulence and Velocity Increases Heat Transfer Rate. [6]

A recent paper by Fredric et al. proposes a theoretical heat exchanger with curved tubes and with nanofluids as the coolant. Nanofluids in place of regular water provide improved thermal conductivity due to the increased surface area. The heat transfer rate is further improved using curved tubes in place of straight tubes because the used of curved tubes increases the turbulence and fluid velocity, which helps increase the heat transfer rate. [6]

References
1. Advanced Thermal Solutions, Inc., https://www.qats.com/Products/Liquid-Cooling/Heat-Exchangers.
2. Aavid Thermacore, http://www.thermacore.com/documents/system-level-cooling-products.pdf.
3. Aavid Thermacore, http://www.thermacore.com/products/air-to-air-heat-exchangers.aspx.
4. Advanced Thermal Solutions, https://www.qats.com/Products/Liquid-Cooling/Heat-Exchangers.
5. Kannan, S., Vekatamuni, T. and Vijayasarathi, P., “Enhancement of Heat Transfer Rate in Heat Exchanger Using Nanofluids,” Intl Journal of Research, September 2014.
6. Fredric, F., Afzal, M. and Sikkandar, M., “A Review on Shell & Tube Heat Exchanger Using Nanofluids for Enhancement of Thermal Conductivity,” Intl. Journal of Innovative Research in Science, Engineering and Technology, March 2017.

For more information about Advanced Thermal Solutions, Inc. thermal management consulting and design services, visit www.qats.com or contact ATS at 781.769.2800 or ats-hq@qats.com.