• Environments in which a high ozone concentration is expected should be marked with an additional safety label that summarises the emergency overview, the safeguards, first aid procedures, fire procedures and spill procedures. An example of such a warning label is given in Appendix B. If the size or design of the UV-C device makes marking impractical, the marking should be included in the packaging and with appropriate web-based links. Other regional required or accepted colour schemes may be utilized. 5.4 Instructional training Containment Safeguards 6 should be provided with instructional training (e.g. instructional manual or video) which includes all relevant...
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  • 3.1.4 spatial wireless power transfer system group implementing spatial wireless power transfer in which the power source can deliver power and data to the power-receiving device Note 1 to entry: In special cases, a spatial wireless power transfer system can consist of only a single power source and only a single power-receiving device. Note 2 to entry: Spatial wireless power transfer system includes the case in which a power source has the ability to access a power-receiving device through a relay from other power sources when the power source attempts to deliver data to the receiving device. In this document,...
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  • This part of IEC 63171 covers 2-way, shielded or unshielded, free and fixed connectors for data transmission up to 600 MHz, with current-carrying capacity, known as Type 2. It specifies the common dimensions, mechanical, electrical and transmission characteristics and environmental requirements as well as test specifications respectively. The form factor of these connectors allows their use for cable sharing with already installed TO’s for structured cabling. NOTE The overall performance of the transmission channel in such case has to be evaluated. Intermateable and interoperable versions for circular connector for sealed applications including this connector are described in IEC 63171-5. The...
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  • 5 General safety considerations General 5.1 The safety of sealed nickel-metal hydride cells or batteries requires the consideration of two sets of applied conditions: a) intended use; b) reasonably foreseeable misuse. The manufacturer can use “cell block(s) or monobloc(s)” instead of “cell(s)” for any test that specifies “cell(s)”. The manufacturer can use “battery pack” instead of “battery” as the test unit in this document. The cell manufacturer shall clearly declare the test unit for each test. Cells or batteries shall be so designed and constructed that they are safe under conditions of both intended use and reasonably foreseeable misuse. It...
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  • 4 EPS interoperability based on USB technologies Overview 4.1 Clause 4 describes the USB common charging interoperability model and provides a summary of the USB Type-C and USB Power Delivery technologies specified in IEC 62680 ‑1‑3 and IEC 62680-1-2, respectively. 4.2 General Since its introduction over 20 years ago, USB charging technology has consistently provided 5 V DC power and relied on a common USB Standard-A connector on the power source. When used with defined legacy cables and adapters, USB Type-C-based power sources, including those that source higher voltages, remain electrically and mechanically interoperable with previous generation USB devices, while...
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  • 3.1 local regulations regulations pertinent to the particular process in the country concerned Note 1 to entry: These regulations may be defined by local, regional or national legislation or even by the owner or operator of the equipment itself. They are always to be considered as the most stringent of any combination thereof. It is the responsibility of each user of this document to familiarize themselves with the regulations applicable to their situation. These regulations shall refer to operational, environmental or health and safety issues. A detailed risk assessment will usually be required. 3.2 routine tests (Group 1 ) minimum...
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  • 4.2 Definition of battery type General 4.2.1 A battery consists of a number of cells or battery modules and/or assembled in trays, crates, and then assembled in a battery box. A cell consists of positive and negative plates, electrolyte, metal container and sealing cap. Positive and negative terminals, which are apart by a separator, are housed and sealed in the metal container with a sealing cap. The sealing cap consists of a positive terminal, a pressure release valve and an insulator which are insulated to a negative part that forms a container. The container wears an insulating envelope. The positive...
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  • 4 Testing method 4.1 General experimental apparatus The general principle for the test set-up to measure the amount of power generation from thermoelectric devices, especially focusing on flexible thermoelectric devices, is described. In general, the thermoelectric device generates electric energy due to the temperature difference between one surface of the device and the other surface. Hence, in order to characterize the performance of the device, the temperature of both the cooling and heating sides in an experimental set-up should be maintained consistently. The general schematic diagram of the thermoelectric device, including the experimental set-up to measure the generated power, is...
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  • 7 Characterization methods for measuring the performance of bare cells and CoCs subjected to qualification tests 7.1 General The optoelectronic performance characterization based on illumination I-V curves tries to identify optoelectronic performance degradation of test samples caused by the required qualification tests. Therefore, illumination I-V curve has to be performed before and after qualification tests. The goal of the illumination I-V curve is on the relative power degradation, not on the absolute power output. Scanning Acoustic Microscopy (SAM) is also required but only for CoCs. In addition, electroluminescence mapping and dark I-V curve can provide diagnostic information about defects and...
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  • 4.1.3 FDI Type Library The Device Access Services and the UIP Services can be modelled as .NET interfaces passing .NET data type arguments. These interfaces and data types are used for the data exchange and interaction between the UIP and the FDI Client. For runtime error handling purposes during interface method calls, .NET exceptions classes are defined. The FDI .NET interfaces, data types, and exception classes are defined in a single FDI Type Library. The FDI Type Library is a strong-named Assembly. The file name of this Assembly shall be ‘fdi.dll’. The fdi.dll shall be versioned as per IEC 62769-1:2020,...
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