The nature of their deployment requires them to work in harsh service conditions. These service conditions include extreme temperatures (hot or cold), increased radiation, etc. Many materials from which satellites are made when exposed to these conditions for a prolonged period may begin to show signs of failure.��

This will affect the efficiency of the satellite and the cost of maintenance as parts would have to be replaced or repaired more often. This is where thermal control coatings come in.

Thermal control coatings are an essential component of satellite technology. They help to protect and regulate the temperature of satellites in order to ensure optimal performance and longevity.

In this article, we will explore the importance of thermal control coatings in satellite technology, how they work, the different types of coatings available, and the challenges faced in designing them. We will also look at how thermal control coatings help to prolong the life of satellites, how they are tested and validated, and the future of thermal control coatings in satellite technology.

���׶���Ƶ Surface Technologies provides many different finishes for parts that are used in the space and satellite . The processes can range from to and plate and more. Many of these processes are crucial to the function of the components, so precise application is critical.

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What Are Thermal Control Coatings?

Thermal control coatings are specially designed materials that are applied to the exterior of satellites and spacecraft to regulate their temperature. Depending on the mission requirements of the satellite, these coatings are made to reflect, absorb, or dissipate heat.��

For the satellite to be protected from severe temperatures and to perform at its best, thermal control coatings are crucial.

The primary purpose of thermal control coatings is to protect the satellite from the extreme temperatures of space. The temperature in space can range from -170°C to +120°C depending on the altitude, making it essential to protect the satellite from these temperatures.

Thermal control coatings are designed to reflect or absorb external heat and dissipate internal heat, allowing the satellite to remain at a stable temperature. This helps ensure the satellite can operate at its optimal temperature and extend its lifespan.

��

How Does It Work?��

Thermal control coatings are designed to regulate the temperature of a satellite in space.�� The satellite’s exterior is coated with these materials to protect it from the incredibly hot conditions in space. This is achieved by deflecting, absorbing, or radiating heat away from the satellite, the function of the coating.

Paint is the most typical thermal control coating in satellite technology. Black paint is used to absorb heat and dissipate it, whereas white paint is used to reflect heat away from the satellite. These paints, which are used to cover the exterior of satellites in a thin coating, are made to be resilient enough to endure the harsh conditions of space.

In addition to paint, other materials such as multilayer insulation, thermal blankets, and metallic coatings are also used for thermal control. Multilayer insulation is a type of insulation that consists of multiple layers of reflective material.��

It is designed to reflect heat away from the satellite while also providing some insulation. Thermal blankets are thin layers of insulation that are designed to protect the satellite from extreme temperatures. Metallic coatings are also used to reflect heat away from the satellite.��

Benefits Of Thermal Control Coatings For Satellites��

The benefits of thermal control coatings for satellite performance are numerous. The most important of these are protection, consistency, prevention, reflection, prolongation, efficiency, cost-saving, and improvement.��

Protection��

Thermal control coatings are important for protecting satellites against severe temperatures and ensuring their maximum performance. These coatings offer a layer of protection from the harsh space environment by absorbing, reflecting, and dissipating heat.

To help control temperature, thermal control coatings can be used on the satellite’s exterior and on internal parts like the electronics and wiring.

Consistency��

The success of any satellite’s mission depends heavily on maintaining consistent temperatures. Meanwhile, the temperature of a satellite’s surface is controlled by thermal control coatings, which are crucial to this operation.��

Depending on the type of coating being used, the coatings are intended to either reflect or absorb solar light. Despite the environment the satellite is in, this helps to maintain its surface temperature at a constant level.

Thermal control coatings also help reduce the amount of heat that is conducted from the satellite’s surface to its internal components, thus helping to keep the internal temperature of the satellite consistent.��

This helps to ensure that the satellite’s components are not damaged by excessive heat. Additionally, the coatings can also help to reduce the amount of heat that is radiated from the satellite, thus helping to ensure that the satellite does not overheat and become damaged.��

Prevention��

One of the most significant advantages of thermal control coatings in satellite technology is prevention. Thermal control coatings help prevent heat buildup in delicate components, which could result in overheating and harm to the satellite. This is crucial for satellites operating in high-temperature environments, including those in low-Earth orbit.

The coatings provide insulation, deflecting heat from the delicate parts and keeping them from overheating. This guarantees that the satellite’s parts can operate as efficiently as possible and guard against potential harm.��

These coatings also aid in maintaining the satellite’s temperature, enabling it to function normally in a wide range of temperatures. Due to its ability to endure severe temperatures, this extends the satellite’s life.

Reflection��

Reflection is an important aspect of thermal control coatings used in satellite technology.�� It is the ability of the coating to reflect infrared and visible light radiation from the sun. By reducing the absorption of solar light, it helps in lowering the temperature of the satellite and its parts.��

Depending on the satellite’s environment, the coating must be designed to deflect light of a particular wavelength.��

Since white paints reflect a wide spectrum of light wavelengths, they are frequently employed for this purpose. However, depending on the purpose, other colors like black or silver can also be employed.��

The coating must also be built to last and resist harsh weather conditions and other environmental elements. To guarantee the best possible light reflection, the coating must also be designed with the proper thickness.

Prolongation��

Prolongation is one of the key benefits of thermal control coatings for satellite technology. Thermal control coatings ensure that the satellite performs at its best while safeguarding it from excessive temperatures.��

Thermal coating greatly influences a satellite’s lifespan since it helps keep the satellite from being damaged or destroyed too soon and increases its longevity.

The primary method in which thermal control coatings help to prolong the life of a satellite is by providing insulation.�� This insulation helps stabilize the temperature of the satellite, preventing the sensitive systems and components from being harmed by sudden temperature changes.��

The coatings also contribute to the satellite’s energy conservation and increased lifespan by lowering its heat loss.

Efficiency��

Efficiency is a key factor when it comes to thermal control coatings for satellite technology. To maximize efficiency, the thermal control coating must be designed to minimize the amount of energy lost in the form of heat. This is done by reflecting heat away from the satellite’s surface, which helps to keep the satellite cooler.��

Additionally, the coating must be designed to be as lightweight as possible to reduce the amount of energy used to move the satellite through space. Using a thermal control coating designed for maximum efficiency, satellites can maximize their performance while minimizing their energy consumption.

Cost-Saving��

Cost-saving is one of the most important benefits of using thermal control coatings in satellite technology. Thermal control coatings can help to reduce the cost of powering a satellite, as they help to regulate the temperature of the satellite and ensure that its components are not over or under-heated.��

This helps to ensure that the satellite remains within its optimal temperature range, which in turn helps to reduce the amount of energy needed to power it.��

Improvement��

Thermal control coatings are invaluable tools for improving the performance of satellites. By carefully controlling the amount of heat absorbed and reflected by a satellite, these coatings can help maintain optimal temperatures for all components.��

This is especially important for satellites exposed to extreme temperatures, such as those in space, as it can help prevent overheating or freezing of sensitive components.��

In addition to protecting against temperature extremes, thermal control coatings can also help improve a satellite’s efficiency by reducing the amount of energy required to maintain a certain temperature. This can lead to significantly improved performance.��

Different Types Of Thermal Control Coatings Used In Satellite Technology��

There are various types of thermal control coatings available, each with its own advantages and disadvantages. Some of these thermal coatings include;

White Paints��

One of the most popular thermal management coatings used in satellite technology is white paint. This kind of coating enables spacecraft to reflect solar energy and maintain a cool temperature.��

Titanium dioxide, a white pigment that has a high degree of reflection, is commonly used in white paints. To offer the best defense against solar radiation, this kind of coating is often used in combination with other temperature control coatings.��

Black Paints��

Black paints are one of the most commonly used thermal control coatings in satellite technology. These paints are specifically designed to absorb the sun’s heat and prevent it from damaging the satellite’s sensitive electronics and other components.��

Black paints are usually made from a combination of carbon black, graphite, and other materials that can absorb large amounts of heat.��

The paint is applied in a thin layer to the satellite’s exterior, which helps to reduce the amount of heat that is transferred from the sun to the satellite. Black paint is also used to reduce the amount of infrared radiation emitted by the satellite, which can reduce the amount of energy used to cool the satellite.��

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Multilayer Insulation��

Multilayer insulation, or MLI, is a type of thermal control coating used in satellite technology. It is made up of multiple layers of thin, reflective material, such as aluminum foil, that are separated by thin layers of insulation. The layers are arranged in a way that traps air between them, which acts as an insulator and reduces the amount of heat transfer.��

This helps to keep the temperature inside the satellite stable and prevents it from becoming too hot or too cold. MLI is particularly useful for satellites operating in extreme temperature environments, such as space.��

It is also lightweight and easy to install, making it a popular choice for many satellite applications. MLI is also highly effective at reflecting incoming solar radiation, which helps to protect the satellite from damaging radiation.

Thermal Blankets��

Thermal blankets are another type of thermal control coating used in satellite technology. They are made from a combination of insulating materials such as aluminum, Mylar, and Kapton, and are designed to reflect infrared radiation away from the satellite’s surface.��

This helps to maintain the satellite’s temperature at the optimal level, even in the most extreme conditions. Thermal blankets are lightweight and flexible, making them ideal for use in space applications. They are also corrosion-resistant and can be easily applied to the satellite’s surface.��

The main advantage of using thermal blankets is their ability to provide insulation and thermal protection. By reflecting infrared radiation away from the satellite’s surface, the blankets reduce the amount of heat that is absorbed by the satellite.��

This helps to maintain the satellite’s temperature at the optimal level, even in extreme conditions. The blankets also protect the satellite from exposure to extreme temperatures, which can damage the electronics and other components of the satellite.��

Thermal blankets are also highly durable and can withstand the harsh conditions of space. They are designed to resist ultraviolet radiation, oxidation, and other environmental factors that can damage the satellite. This makes them ideal for long-term use in space applications.��

Metallic Coatings��

Metallic coatings are a type of thermal control coating used in satellite technology to provide protection from extreme temperatures. These coatings are made from a combination of metals, such as aluminum, copper, and stainless steel, that are applied to the surface of a satellite in a thin layer.��

They are designed to reflect heat away from the satellite and provide a barrier from the extreme temperatures of space. Typically, metallic coatings are applied to the exterior of the satellite, where they serve as a strong barrier against the extreme temperatures of space.��

They are also used in the interior of the satellite to help keep components, such as electronics, at a stable temperature. When a satellite is exposed to direct sunlight, metallic coatings can reflect up to 95% of the sun’s rays, keeping the spacecraft cool.

Aerogels��

Aerogels are a unique type of thermal control coating used in satellite technology. They are a kind of solid foam created from a gel with a silica foundation and are renowned for being extremely light and having excellent insulating qualities.��

Making aerogels involves draining the liquid from the gel and leaving a porous solid behind. Because of their low density and high surface area-to-volume ratio, aerogels are able to trap air and inhibit heat transfer thanks to their porous structure.

Since the Hubble Space Telescope’s construction in the early 1990s, aerogels have been used in space. Since then, aerogels have been employed on various space missions, including the Cassini-Huygens mission, the Phoenix Mars Lander, and the Mars Exploration Rovers.��

On the International Space Station (ISS), aerogels are also employed to insulate the station’s walls and windows from the incredibly hot conditions in orbit.

Hybrid Coatings��

A type of thermal control coating known as a hybrid coating uses two or more components to provide the desired result. These coatings are frequently employed in satellite technology because they function better than coatings made of a single substance.��

A reflective layer, like aluminum, plus a non-reflective layer, like a polymer or ceramic, make up hybrid coatings in most cases. The non-reflective layer aids in reducing heat radiation from the satellite while the reflective layer aids in reducing heat absorption by the satellite.

Hybrid coatings can be made to reflect some wavelengths of light while letting others pass through, allowing them to be customized to match specific needs.��

This makes it possible for the satellite to keep a constant temperature even during periods of severe heat. Moreover, hybrid coatings can be designed to be resistant to damage from ultraviolet radiation, which is important for satellites in low-Earth orbit.

What Are The Challenges Faced In Designing Thermal Control Coatings For Satellites?��

Designing thermal control coatings for satellites is a complex process that requires a deep understanding of the environment in which the satellite will be operating. This is because the temperature of a satellite’s environment can vary dramatically depending on its location and altitude.��

As a result, the thermal control coating must be able to withstand extreme temperatures and provide the necessary protection for the satellite. Furthermore, the coating must also be lightweight and durable, as well as be able to reflect, absorb, and dissipate heat efficiently.

There are a number of challenges that must be taken into consideration when designing thermal control coatings for satellites.��

Range Of Temperature

Firstly, the coating must be able to withstand the extreme temperatures of space. This means that the coating must be able to withstand temperatures ranging from -270 degrees Celsius to +200 degrees Celsius.��

Additionally, the coating must also be able to resist radiation, as well as be able to withstand the vacuum of space.��

Weight Of Coating

Another challenge is the weight of the coating. As satellites are typically very lightweight, the coating must be lightweight as well. This is because the weight of the coating can affect the overall weight of the satellite, which can affect its performance.��

Additionally, the coating must also be able to withstand the high levels of vibration that the satellite will experience during launch and re-entry.��

How Are Thermal Control Coatings Tested And Validated For Use In Satellite Technology?��

Testing and validating thermal control coatings for use in satellite technology is an essential part of the process of designing and launching a satellite. Thermal control coatings must be certified able to withstand extreme temperatures and provide the necessary protection and insulation to ensure that the satellite is able to function optimally.��

The process of testing and validating thermal control coatings for use in satellite technology involves a variety of tests and simulations. These tests and simulations are designed to ensure that the thermal control coatings are able to withstand the extreme temperatures that the satellite will be exposed to in space.��

The first step in the testing process is to simulate the environment that the satellite will be exposed to in space. This includes tests that simulate extreme temperatures, solar radiation, and other environmental factors. These tests help to ensure that the thermal control coatings are able to withstand the extreme temperatures that the satellite will be exposed to in space.

The next step in the testing process is to perform tests that measure the thermal performance of the thermal control coatings. These tests measure the thermal conductivity, emissivity, reflectivity, and other properties of the coatings. The results of these tests help to determine whether the coatings are able to provide the necessary insulation and protection for the satellite.

The final step in the testing process is to validate the results of the tests. This includes conducting further tests to ensure that the thermal control coatings are able to meet the requirements of the satellite. These tests help to ensure that the coatings are able to provide the necessary insulation and protection for the satellite.

The Future Of Thermal Control Coatings In Satellite Technology��

Thermal control coatings have a promising future in satellite technology. The need for sophisticated thermal management solutions that can offer dependable protection and optimal performance in severe temperatures is increasing along with the need for satellite technology.��

In order to ensure that satellites can resist the harsh conditions of space and operate consistently for years to come, thermal control coatings are being used more and more during the design and construction of satellites.

Thermal control coatings are becoming more advanced and efficient, with new materials and technologies being developed to provide better protection and performance. For example, the use of nanomaterials and nanostructures in thermal control coatings is allowing for greater thermal conductivity, better protection from radiation, and improved durability.��

In addition, the development of hybrid coatings combining multiple materials to create a single coating is providing a more efficient solution for thermal control.��

As technology continues to evolve, thermal control coatings are becoming more cost-effective and efficient. This is allowing more satellites to be launched and operated at a lower cost, while still providing reliable protection and performance.��

Final Thoughts��

Thermal control coatings are an indispensable component of satellite technology. These coatings help to protect satellites from extreme temperatures and ensure their optimal performance.��

They also help to prolong the life of satellites and can be cost-saving in the long run. Thermal control coatings come in various forms, such as white paints, black paints, multilayer insulation, thermal blankets, metallic coatings, aerogels, phase change materials, and hybrid coatings. The design and testing of these coatings is a complex process, and their development is an ongoing effort.��

As satellite technology advances, the use of thermal control coatings will become increasingly important. With the help of these coatings, satellites will be able to operate more efficiently and reliably in space.

is a full-service surface finishing company specializing in the , , and. With ten strategically located sites across the United States, ���׶���Ƶ provides a start to finish solution from and , to paint and sub-assembly.

We are the world’s largest independent aerospace surface finishing company. We are unique in that we are the only complete integrated solution in the supply chain, saving time and money for our customers. from an industry leader today!

For additional topics of interest, please read:��

• Top Surface Finishing Applications In Aerospace
• What Is Aerospace Plating? Significance And Advantages
• What Is Surface Plating? Intro To Surface Finish

FAQs��

Why is thermal control necessary in a satellite?

Thermal control is necessary in a satellite to ensure the optimal performance of its components and systems. Extreme temperatures can cause components to malfunction, leading to a decrease in performance and even failure.

Thermal control coatings are designed to help regulate temperatures in the satellite, protecting against extreme temperatures and maintaining optimal performance.��

What are the components of thermal control?

Thermal control involves several components, including thermal control coatings, thermal control systems, and thermal control layers. Thermal control coatings are applied to the exterior of the satellite and work to regulate temperatures.��

Thermal control systems are active systems that use a combination of heaters and radiators to maintain optimal temperatures. Thermal control layers are insulation materials that are used to help reduce heat transfer.��

What are the active thermal control systems used in satellites?

The most common active thermal control systems used in satellites are thermal radiators and heaters. Thermal radiators use a combination of radiative and convective heat transfer to dissipate heat away from the satellite. Heaters are used to generate heat when necessary, such as during certain phases of a mission.��

What is a thermal control layer?

A thermal control layer is an insulation material that is used to reduce heat transfer. These layers are usually composed of multiple layers of materials, such as foam, films, or fabrics, that are designed to reflect, absorb, or dissipate heat.��

What paint does NASA use?

NASA uses a variety of paints for its satellites, depending on the mission requirements. White paints are commonly used for thermal control, as they are highly reflective and help to reduce the absorption of heat. Black paints are also used, as they help to absorb heat and dissipate it away from the satellite.

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���׶���Ƶ Seattle is now offering Type II and Type III Anodizing with Class 2 black dye. This new additional anodizing capability allows ���׶���Ƶ to further provide a single-supplier solution to aerospace outside processing in the Pacific Northwest.

“Hard Anodize (Type III) in Seattle is a game-changer for the region and adding black dye as well further expands our capabilities to support our growing customer’s needs for this and other processes”.
– Jim Duncan, Q.A. Manager

���׶���Ƶ Seattle, founded as MAPSCO in 1981, is the leader in the Pacific Northwest in processing small to medium-sized precision parts for the aerospace industry. ���׶���Ƶ Seattle sets the standard for on-time delivery, customer service, and quality due to its relentless focus on quick and transparent communication, competitive and consistent turnaround times, and technical quality and processing expertise built over 35 years. ���׶���Ƶ Seattle’s 32,000 square foot facility is located in the heart of Washington’s aerospace hub and offers full-service NDT (penetrant and magnetic particle inspection), shot peen, aluminum, and hard metal chemical processing, and paint services. ���׶���Ƶ Seattle has earned the trust of leading aerospace manufacturers and we support primes such as Boeing, Goodrich (UTAS), Spirit AeroSystems, Northrop Grumman, Raytheon, and more. ���׶���Ƶ Seattle has 2 highly efficient process lines for titanium and steel and aluminum processing including chemfilm, type I, type II, and type III anodize. We proudly process over 4 million parts per year, a testament to our 24/7 operation, lean manufacturing philosophy, and state of the art MRP system with RFID tracking.

About ���׶���Ƶ Surface Technologies
���׶���Ƶ Surface Technologies is the world’s largest independent provider of Aerospace product finishing services. With 12 locations and over 2,500 unique industry approvals, ���׶���Ƶ processes more than 1 million parts per month. In addition to being Nadcap accredited, all ���׶���Ƶ sites provide specialized metal processing and finishing services to a diversified set of fast-growing commercial aerospace, defense, and space/satellite markets. ���׶���Ƶ partners with its customers to deliver best-in-class quality, turn times, and full-service supply chain solutions.

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���׶���Ƶ Seattle has already achieved approval for Boeing’s BAC 5821 hard anodize along with military specification MIL-A-8625 Type III for Collins Aerospace. Additional OEM approvals are also actively being pursued. This added capability and new approvals expands and allows ���׶���Ƶ to provide complete end-to-end surface finishing services to its customer base.

“We are excited to now provide hard anodizing services for our customers in the Pacific Northwest”.
Daniel Hawkins, Regional General Manager

���׶���Ƶ Seattle, founded as MAPSCO in 1981, is the leader in the Pacific Northwest in processing small to medium-sized precision parts for the aerospace industry. ���׶���Ƶ Seattle sets the standard for on-time delivery, customer service, and quality due to its relentless focus on quick and transparent communication, competitive and consistent turnaround times, and technical quality and processing expertise built over 35 years. ���׶���Ƶ Seattle’s 32,000 square foot facility is located in the heart of Washington’s aerospace hub and offers full-service NDT (penetrant and magnetic particle inspection, shot peen, aluminum, and hard metal chemical processing, and paint services. ���׶���Ƶ Seattle has earned the trust of leading aerospace manufacturers and we support primes such as Boeing, Goodrich (UTAS), Spirit AeroSystems, Northrop Grumman, Raytheon, and more. ���׶���Ƶ Seattle has 2 highly efficient process lines for titanium and steel and aluminum processing including chem film, type I, type II, and now type III anodize. We proudly process over 4 million parts per year, a testament to our 24/7 operation, lean manufacturing philosophy, and state of the art MRP system with RFID tracking.

About ���׶���Ƶ Surface Technologies
���׶���Ƶ Surface Technologies is the world’s largest independent provider of Aerospace product finishing services. With 12 locations and over 2,500 unique industry approvals, ���׶���Ƶ processes more than 1 million parts per month. In addition to being Nadcap accredited, all ���׶���Ƶ sites provide specialized metal processing and finishing services to a diversified set of fast-growing commercial aerospace, defense, and space/satellite markets. ���׶���Ƶ partners with its customers to deliver best-in-class quality, turn times, and full-service supply chain solutions.

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Matthew Alty, VP Operations, explained, “We’ve seen a pressing need in the market for titanium processing, especially for growth programs like Boeing’s 777X and 737MAX. ���׶���Ƶ already offers extensive titanium processing capabilities at our plant in Seattle (formerly known as Mapsco Inc.) including titanium etch and sol gel for parts under 5’. Based on feedback from our customers we have leveraged this expertise to offer much-needed capacity for parts up to 12’ in length.”

Following the installation of the new capability, ���׶���Ƶ implemented an operator training program to transfer process knowledge and operating procedures from its Seattle facility, which culminated in the Everett site receiving Nadcap Merit accreditation and Boeing D1-4426 approval to process titanium per BAC 5753.�� Following the successful achievement of Boeing approvals, ���׶���Ƶ is now preparing to add titanium processing approvals for Gulfstream, Lockheed, and other aerospace OEMs.

About ���׶���Ƶ Surface Technologies

���׶���Ƶ Everett specializes in processing large aerostructure components. The site is a leader in large part processing with 30-foot capability for NDT, shot peen, chemical processing, and painting. ���׶���Ƶ now operates three processing facilities strategically located��in the Pacific Northwest and provides a complete range of product finishing services for aluminum, titanium and steel parts.

is the world’s largest independent provider of Aerospace product finishing services. With 10 locations, 530,000+ sq. ft. of manufacturing space, and over 2,500 unique industry approvals, ���׶���Ƶ processes more than 16 million parts per year. In addition to being Nadcap accredited, all ���׶���Ƶ sites provide specialized metal processing and product finishing services to a diversified set of fast-growing commercial aerospace, defense, and space/satellite markets.

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“���׶���Ƶ has worked closely with its customer base in the Pacific Northwest to understand the process requirements for new and existing programs. We’ve invested in adding much-needed capacity for large part shot peening,” explained Matthew Alty, vice president of operations. The plant combines an automated shot peen capability and an integrated digital masking cell specifically designed to streamline the processing of geometrically complex components.�� By matching large part shot peen capability to its existing 30-foot NDT, chemical processing, and paint lines, ���׶���Ƶ now delivers a fully integrated solution to its customers. Alty added, “Instead of sending a part to multiple suppliers, customers can now issue a single purchase order to ���׶���Ƶ, reducing lead times, transportation and logistics costs.”

About ���׶���Ƶ

, with 10 locations, over 530,000sq.-ft. of manufacturing space, over 2,500 unique industry approvals and over 15 million parts processed per year, is the world’s largest independent provider of special processing services to the aerospace and defense industry. The Company provides specialized metal processing and finishing services to a diversified set of fast growing commercial aerospace, defense, and space/satellite markets.�� All Valance sites are Nadcap accredited and offer services including NDT, all types of anodizing, chemfilm, passivate, plating, dry film lube, and painting.�� ���׶���Ƶ brings superior value to its customers through its industry-leading capabilities, approvals and systems and its continuous drive to provide best in class quality, turn times and supply chain partnership.

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