Metrology. Each Party shall ensure, to the extent practicable, the documented traceability of its standards and the calibration of its measuring instruments, according to the recommendations of the Bureau International des Poids et Measures (BIPM) and the International Organization of Legal Metrology (OIML), and comply with the requirements set out in this Chapter.
Metrology. The Member States shall:
Metrology. To promote cross-strait cooperation in respect of legal metrology and exchange of information on measurement techniques and legal metrological control; to conduct joint research on the highest measurement standards with precision and reliability, and intercomparison of standards; and to pursue technical cooperation in respect of measuring instruments, tracibility and calibration.
Metrology. Memorandum of understanding for cooperation relating to standardization, conformity assess- ment and legal metrology. Signed at Wash- ington May 9, 2000; entered into force May 9, 2000. TIAS MISSIONS, MILITARY Agreement for the establishment of the United States military advisory group to the Republic of Korea. Signed at Seoul January 26, 1950; entered into force January 26, 1950; operative July 1, 1949. 3 UST 2696; TIAS 2436; 178 UNTS 97. Amendment: October 21, 1960 (11 UST 2348; TIAS 4613; 400 UNTS 386). MUTUAL SECURITY Agreement relating to the assurances required by the Mutual Security Act of 1951. Exchange of notes at Pusan January 4 and 7, 1952; en- tered into force January 7, 1952. 3 UST 4619; TIAS 2612; 179 UNTS 105.
Metrology. Increased process reliability & productivity of processes to reduce costs •Additional process understanding and control via the digital thread, cloud and big data •Exploration of coordinated control of multiple energy sources and new materials •Integrating technologies •Developing next generation additive and hybrid systems that enable new materials, applications and solutions for energy relevant fields. Systems •Localized microstructure control •Materials designed for harsh conditions such as superalloys, ceramics, refractories, and composites •Developing polymer materials with anisotropic properties •Spatially graded & hybrid materials •Developing materials designed for additive manufacturing, creating composite and hybrid materials and understanding the role of feedstocks. Materials 2019 AMO Peer Review Technical Innovation (continued) Rapid advanced manufacturing of solutions for energy generation and efficiency Rapid prototyping Direct fabrication Tools, dies, molds <.. image(Rapid prototyping ) removed ..> <.. image(Direct fabrication ) removed ..> <.. image(Tools, dies, molds ) removed ..> Using advanced manufacturing for energy generation, national and economic security, and revitalizing America’s manufacturing competitiveness. Hydro Wind Buildings Fossil Transportation Nuclear <.. image(Hydro ) removed ..> <.. image(Wind ) removed ..><.. image(Buildings ) removed ..> <.. image(Fossil ) removed ..> <.. image(Transportation ) removed ..> 2019 AMO Peer Review Technical Approach: Core Research & Development The Manufacturing Demonstration Facility The MDF is an ORNL user facility focused on cost- shared early-stage applied R&D in the areas of additive manufacturing and carbon fiber materials research related to energy. Based on ORNL strengths in materials, computation, engineered systems and characterization MDF by the Numbers # of People Staff 82 Interns 33 Students 51 Summer Interns 37 Total 166 to 203 ~5,000 annual visitors representing ~700 companies per year providing insight 5 year strategic plan, 4 technical areas
Metrology. 12.8.1 The material loss from the cobalt chromium taper junction surfaces (including head/neck and stem/neck) may be characterized using a CMM or roundness machine as per ASTM F3129-16. The profilometer will touch the surface of the component using a 2 mm (or larger) diameter stylus.
Metrology. The metrology system is used to record interferogram samples in equal intervals of optical path difference of the wishbone interferometer. A 1.55 micron fiber launched laser based infrared metrology system was developed for use at cryogenic temperatures. Figure 50 shows the IR laser launched using an optical fiber into the interferometer module. A plane mirror was mounted on the piezo-electric translation mechanism oscillating at a frequency of 10 Hz. The following figures shows the oscilloscope grabs of the metrology fringes at different time scales while the translation stage is motion.
Metrology. The overall instrument (including telescope) needs several highly accurate metrology sub-systems. Knowledge of the origin and propagation of phase and positional errors along the optical path is critical to fringe visibility and interferogram reconstruction. Ultimately, an overall error budget will need to be constructed that assesses all possible causes or error. Further work on this is also presented in report 1.3. For example, further work is needed to assess the maximum allowable optical path difference (OPD) of the two beams. Sporadic, modest “jumps” of order λ/4 can most likely be contained, but bearing in mind the wideband of operation, the RMS of the OPD will need to be constrained to much tighter tolerance (of order tens of nm). Other metrology information:
Metrology. 1. According to the Metrology Law of the People’s Republic of China, National Planning Commission Jiran (1987) No. 2001 Provisional Measures on the Management of Natural Gas Commodity Volume, Ministry of Energy and National Metrology Nengyuanyou (1990) No. 943 Regulations on Metering of Crude Oil, Natural Gas and Natural Gasoline, the metrology value of gas shall be determined by the value of Connection Point of the Supplier, the metering method shall be determined by the Supplier’s need.
Metrology. HHNEC shall be responsible for developing an effective method of measuring the depth of the narrow and deep trenches in the Wafers;