ELMARCO's alternatives and competitors
Amphenol Fiber Systems International (AFSI) is a full service fiber optic company engaged in the fabrication and manufacture of fiber optic connectivity products and sy…
Top 8 ELMARCO competitors
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Verdex Technology operates as a technology company. It specializes in the mass production of nanofibers for extensive applications including air and microfiltration media, fuel filtration, advanced filtration, microporous breathable films, and more. It creates products for the filtration, pharmaceutical, food, and nutraceutical markets. It was founded in 2011 and is based in North Chesterfield, Virginia.
Seniton Technologyorporation is a company that received a SBIR Phase I grant for a project entitled: Developing an Ultra Energy Efficient Sensor Node Using RFID Technology. Their research project proposes to develop an ultra-energy efficient wireless sensor node using RFID technology. By providing ultra energy efficiency and hence extended network life time, the proposed solution can significantly reduce recurring maintenance cost due to replacing/recharging batteries and interruption of normal operation for networks with long deployment lifetime. The outcome of the proposed tasks is a prototype of a wireless sensor platform that will provide ultra-energy efficiency, at least 5-10 times improvement as compared to existing solutions. The approach is to uniquely combine wireless sensor platform with radio frequency identification (RFID) technology. In contrast to conventional designs where synchronized, periodic sleep/wakeup of sensor nodes are used as the dominant strategy for energy conservation, we employ an innovative asynchronous communication architecture, where sensor nodes are allowed to independently transmit without requiring any synchronization. The approach is fundamentally different from existing design paradigms; the innovative asynchronous communication architecture allows a sensor node to directly write data into a special, reactive module residing on the receiving node while its main platform is asleep. In this way, each individual sensor can schedule its own transmission without demanding any network-wide or local synchronization, thus resulting in a store-and-forward, asynchronous communication pattern in the network. Owing to the low duty cycle of a sensor node, the proposed asynchronous architecture will liberate the network from collisions and idle listening by fully exploiting time as one dimension of resource. The result is a design achieving order of magnitude improvement in energy efficiency. The extension of a wireless sensor network's life time will have significant commercial potential in saving recurring maintenance cost due to replacing/recharging batteries and disruption of normal operation for a technology with exploding market. Moreover, the technology can enable a plethora of applications, infeasible under existing designs, which demand extremely large scale sensor networks and ultra energy efficiency for long term operation. These include habitat, oceanic and planetary monitoring and surveillance of infrastructures. Furthermore, this integrative, and cutting edge project demands a systematic and synergistic approach that combines wireless networking, embedded system design, and lower power radio, and should also promote the fusion of knowledge in various domains by focusing on a mutual and challenging objective.
3F aims to provide research and engineering services for makers and users of technical textiles, advanced composite materials and structures, and their applications. With experience in development of textile and composite materials, their processes and their applications, 3F supports new-product development, aims to reduce costs and shorstens the time to market. Design, analysis, prototyping, and testing are all part of what 3F does. They bring value to their clients at pre-negotiated, fixed-prices that are value-based and stage-gate controlled. The end result is faster commercialization and earlier returns on the R&D investment. 3f is a company that received a STTR Phase I grant for a project entitled: Light-Weight Bio-Based Nano-Enhanced SMC Formulations. Their project shall utilize a multi-organizational team with uniquely experienced and multi-disciplinary personnel to demonstrate the feasibility of a new family of innovative sheet molding compounds (SMCs) that are partially bio-based and have lower density while having similar performance and cost. Kenaf natural fiber will be blended with glass fiber and combined with commercially available soy-oil based resin and select nano-materials to produce new SMC formulations that will be manufactured and validated experimentally. Innovations include 1) chemistry approaches to address the known problems of moisture absorption and strength retention in natural fiber composites and 2) fiber processing methods that will enable the use of standard fiber processing machines and existing SMC manufacturing equipment. The new lighter weight SMCs will find initial application in off-road farm equipment, automotive trunk floors, wheel wells and other non surface-critical components that currently use metal or heavier SMCs. Multiple companies who currently make SMCs and/or SMC components will license the new material technology through the National Composite Centers (NCC) newly forming SMC consortium. The development team, innovative materials combinations and processing approach have been carefully selected to enable rapid commercialization of the new technology once demonstrated. Innovative materials and combinations of materials have potential to provide cost-effective engineered materials systems that provide significant weight savings for automotive structures, thus leading to higher vehicle fuel economy. Additionally, the full or partial use of bio-based renewable materials will reduce the consumption of and dependence on petroleum based products. The exciting ""green"" aspect to this program will assist NCC's educational mission as students have great interest in environmental issues and the use of renewable resources to make a sustainable environment. NCC's cooperative education program may be utilized in support of the proposed work. Positive R&D results may serve as the basis of setting up conferences with high schools through NCC's multi-source video and videoconferencing center. As a lead agency for the effort, NSF's funding of this program will also support President Bush's American Competitiveness Initiative whose goal is to ""increase investments in research and development, strengthen education, and encourage entrepreneurship"" and enable America to ""remain a leader in science and technology."" A focus of this research proposal is to develop technology that will enable cost-effective US manufacture of materials and components; thus supporting other ""Made in America"" type Federal initiatives. 3f is a company that received a STTR PHASE I grant for a project entitled: HIGH-STRENGTH LOW-COST FIBER VIA MULTI-COMPONENT NANOFIBER (MCN) SPINNING. Their project will employ a multi-component nanofiber spinning approach to develop a high-strength and high-modulus polymeric ""composite fiber"", using the latest available ""islands-in-sea"" spinning technology and innovative spinning process parameters and polymer combinations. The goal of this project is to achieve a ""composite fiber"" wherein nano-scale fibers (~100nanometers in diameter) reside in a reinforcing matrix. Due to their small size and molecular orientation, the nano-fibers will exhibit strengths approaching the theoretical strength of the constituent polymer. The resulting new composite fiber will be comparable to other high performance fibers on the market today, but will cost significantly less. Additionally, the matrix of the composite fiber may be a thermoplastic of lower processing temperature, enabling subsequent processing to melt the matrix and form composite materials and structures. The broader impact/commercial potential from this technology will be new composite fiber that can be commercialized in stages: first as an easy-to-sell industrial grade fiber; then as strong structural ballistic/structural fiber; and then as a composite material system with fiber and matrix already intimately interfaced (i.e. island and sea polymers, respectively). Initially composite fiber will be marketed as a replacement for industrial nylon, polyester, etc., in markets that don't require extensive testing and application development; e.g. cordage, ropes, nets, webbing, tire-cord, etc.
Amphenol Fiber Systems International (AFSI) is a full service fiber optic company engaged in the fabrication and manufacture of fiber optic connectivity products and systems. The company's commitment to technical excellence aims to make us an industry leader in providing sophisticated products and professional technical assistance in the fiber optic industry. AFSI aims to provide solutions for communications systems based on fiber optic interconnect technology. TFOCA-II, M83522, M29504, and M28876 are the global standards in the military marketplace. With over 100 employees, AFSI is currently located in a 50,000 square foot facility, in the heart of the telecom corridor in Allen, just north of Dallas, Texas. Since its inception in 1993, AFSI has and will continue to base its corporate strategy on technical and application support, quality assurance, product performance, and value.
Via Separations is a company focused on energy efficiency in the industrial sector. The company offers innovative filtration solutions that aim to increase process efficiency and reduce costs, specifically by eliminating 90% of the energy currently used in thermal separations. Via Separations primarily serves the industrial sector. It was founded in 2016 and is based in Watertown, Massachusetts.
Altafiber is a company that operates in the telecommunications and energy sectors. The company provides a range of services including high-speed internet, television, home phone services, and energy solutions. Its primary customers are residential and business sectors. It was founded in 1873 and is based in Cincinnati, Ohio.