ETS-Lindgren is an international manufacturer of components and systems that measure, shield, and control electromagnetic and acoustic energy. The company's products are used for electromagnetic compatibility (EMC), microwave, wireless, and Magnetic Resonance Imaging (MRI) testing, electromagnetic field (EMF) measurement, radio frequency (RF) personal safety monitoring, and control of acoustic environments.
Headquartered in Cedar Park, Texas, ETS-Lindgren has manufacturing facilities in North America, Europe, and Asia. The company is a wholly owned subsidiary of ESCO Technologies, a leading supplier of engineered products for growing industrial and commercial markets. ESCO is a New York Stock Exchange listed company (symbol ESE) with headquarters in St. Louis, Missouri. Additional information about ETS-Lindgren is available at www.ets-lindgren.com. Additional information about ESCO and its subsidiaries is available at www.escotechnologies.com.
Ets Lindgren Tile Download
Download File 🔥 https://byltly.com/2yGaJx 🔥
Software customers with maintenance contracts enjoy an extra level of support for their software needs, whether it involves driver development, new software release downloads, or even just a helping hand in getting the most out of your software investment.Click here to access the Software Support Portal or contact sales@ets-lindgren.com to set-up your access today!
Keep your testing up-to-date with these important updates to our industry-leading test software. ETS-Lindgren software products are developed by professionals with the knowledge gained from designing, installing, and supporting EMC, EMF, and wireless test software applications. Customers with active software maintenance contracts will be able to utilize these updates automatically by accessing downloads through our Software Support Portal. If you are not sure that you are active, or wish to activate your maintenance contract, please contact ETS-Lindgren sales at sales@ets-lindgren.com or via Contact Us.
The ETS-Lindgren GTEM correlation program is a simple routine that allows the user to calculate the equivalent OATS, SAC or far field strength from the three orthogonal power measurements made in a GTEM cell based on some assumptions about the propagation characteristic of the device under test (DUT).
Cathy and Eric formed the Huntsville Tile Co. in 1990 due to their interest in handmade tiles. Eric has been producing handmade stoneware basins since 1981. Cathy's background in textile design suits the design process for tiles.After 11 years serving hundreds of satisfied customers and making many thousands of tiles, we sold the tile company in 2001 so that we could live life and make pots and tile in a more creative and comfortable way - back at the pottery.
The new owners do not make handmade tile so we are free to carry on with that interest.
Contact us to discuss your project. Digital images are available if we have done prior work that would be appropriate to show you.
ETS Lindgren Enclosure General Equipment
Follow us for the latest equipment specials.
Refurbished ETS Lindgren EnclosureCall 1-800-615-8378 or 407-804-1299 for more information
Sell EquipmentRepairsAdd to cartE-mail this pageAlert me when this goes on sale
ETS Lindgren Enclosure Details
ETS Lindgren Enclosure
DEI Copper screen enclosures are used where absence of a sense of confinement or where casual observation from the outside is desirable. The superior shielding characteristics obtained from ETS-Lindgren screen enclosures are primarily the result of DEI construction, which permits screen to be used where solid double shield construction would ordinarily be used.
In some applications, screen enclosures eliminate the need for additional ventilation. Where required, exhaust fans or connections to existing air handling systems are easily added. Screen rooms are very easy to assemble because of the inherent flexibility of the shielding material which requires lower clamping pressures than are generally required with steel and other rigid materials.
Kick-plates or protective paneling are used to protect the lower 32" on the inside and outside of each wall panel. Kick-plates are made of an attractive wood grain paneling. A color coordinated vinyl tile is installed over 3/4" plywood panels which are connected with 1/8" thick, 4" wide aluminum strips to provide an entirely flush modular floor system.
A heavier 22 x 22 x .015" copper wire mesh is offered for applications which require the advantages of screen, with the best possible high frequency microwave and improved low frequency magnetic attenuation characteristics.
The ETS-Lindgren DEI door employs a number of unique proprietary and patented features which contribute to its superior performance characteristics and durability. All hardware and door seals are designed to maintain electrical isolation between the inner and outer shields. Doors are side hinged and supported by three heavy duty hinges to provide sag-free mounting and have been cycle tested up to 25,000 operations.
The three-point clamping system draws the door into a closed position when the 28" panic type handle is pulled up with a force of less than 30 pounds. A positive opening pressure is applied to the door when the handle is pushed down to open. The handle and lever arms, which apply clamping pressure, are adjustable as are the contact fingers. Single, double and vestibule door systems are available in most sizes and with a variety of options, including color-coordinated or wood-grained veneer finishes, view windows, access openings, ramps, locks, alarms, interlocks and microwave absorber seals. Flush floor systems are also optional. Optional auto latch door available.
The basis of ETS-Lindgren's DEI construction is its unique patented design, which permits double shield enclosures to be assembled from individual panels. Panels are designed to accommodate a variety of shielding materials which are attached to a strong, nonconductive wood frame. When the shielding is overlapped and the panels bolted together, a resilient, as opposed to rigid, clamping pressure is applied, making it easier to achieve and maintain an RF tight seal. This design requires 18 inches of space around the perimeter for assembly.
On midwall and ceiling panels, an angle bar clamping system is used that also provides additional structural support. Individual panels can be easily modified to accommodate accessories and special enclosure size requirements.
This optional construction style enables the enclosure to be completely assembled from the inside, to accommodate areas with tight restrictions. This design employs separate clamping strips to interconnect panels. In other aspects, it is similar to standard construction and maintains the DEI principle.
Special care is taken to protect the inside floor shield by covering it with a layer of 3/8" plywood. A separate walking surface consists of 1/8" vinyl tile on 3/4" A-C plywood panels, which are interconnected with 1/8" aluminum strips, to ensure a flush, durable floor capable of supporting 1,000 pounds per square foot. Floors can be strengthened to accommodate heavier loads when required.
Standard DEI enclosures are of modular construction and assembled from panels which are interchangeable to facilitate expansion or modification. Modular construction permits nonstandard enclosure requirements to be met with a minimum number of special panels. The customer's size requirements determine the number of panels in the room. Special size enclosures, mobile rooms and portable enclosures are also available.
I just watched the documentary/drama called "The Challenger Disaster". Physicist Richard Feynman made a few physics points that opened my eyes. Points and problem solving that we could use in various parts of our industry. I recommend this movie.
The Challenger disaster, as well as the Columbia disaster were the primary impetuses for my total loss of faith in NASA. Although I still firmly believe the human race needs to find ways to exploit space and settle on other worlds (assuring survival of the species in the event of a planet-wide catastrophe), I now follow private enterprise much more closely, like Elon Musk's SpaceX, Orbital Sciences, Armadillo Aerospace, Bigelow Aerospace and Virgin Galactic.
The original design did not call for SRB's. It called for a near-totally reuseable spaceflight system using SSME's (Space Shuttle Main Engines) in their place. The idea was that liquid-fueled engines were cheaper to operate and provided better performance. The OMB (Office of Management and Budget) pressed NASA to use SRB's due to their cheaper cost to develop despite their higher flight costs and environmental impact (SSME's burn liquid hydrogen with liquid oxygen whereas SRB's used aluminum powder (fuel), ammonium perchlorate (oxidizer), iron oxidized powder (catalyst) polybutadiene acrylic acid acrylonitrile (binder) and an epoxy curing agent.
Burning liquid hydrogen (LH2) and liquid oxygen (O2) produces H2O (water) while burning the fuels in an SRB creates hydrogen chloride - which reacts with the atmosphere to produce chlorine, nitric oxide - which may convert in the air to nitric acid and cause acid rain, carbon monoxide, water and aluminum oxide. In fact, the aluminum oxide burned by the SRB's was more hazardous than you might think:
The DoD also had a negative hand in the design process. Due to budget restrictions placed on NASA by the politicians (the same ones who cancelled continuing Apollo missions that would have had a space station long before the ISS and even settlements on The Moon and Mars long before now), the DoD's committment to use the Shuttle was enlisted to help pay for development and operating costs. The DoD and the NRO (National Reconnaissance Office) gained primary control over the design process. For example, NASA planned a 40 feet-long and 12 feet-wide cargo bay, but NRO specified a 60 feet by 15 feet bay because it expected future intelligence satellites to become larger. 152ee80cbc
animation movies with english subtitles free download