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Pneumatic energy

An original route is that proposed by Ter-Minassian and Million in 1983 [44] with their pneumatic compensation calorimeter, represented in Fig 10. The tubular sample cell 4 is in good thermal contact with four metallic bulbs. Two of them operate like bulb 1 in the figure, Le. as pneumatic thermal detectors. They are filled with gas, say around 1 bar, and their pressure is compared, by means of a differential manometer, with the constant pressure of a reference reservoir 3 immersed in the surrounding thermostat block 5. Therefore, they detect any temperature change of the sample. The two oflier bulbs operate like bulb 2, i.e. as pneumatic energy-compensating devices. They are also filled with gas, say around 1 bar, but they are connected to flie piston-cylinder 7 which enables the heat of compression (or decompression) necessary to cancel the temperature difference between the sample and thermostat (as detected with the first set of bulbs) to be produced in the bulb. More recently, Zimmermaim and Keller built a comparable pneumatic compensation calorimeter whose calorimetric performances were carefully examined [45]. [Pg.36]

The power supply , which provides the energy -usually electrical or pneumatic energy sources -for locomotion of the different manipulator parts. [Pg.4310]

Actuator—A power mechanism used to effect the motion of a robot or a device that converts electrical, hydraulic, or pneumatic energy into robot motion. [Pg.467]

Thermal Transducers Infrared radiation generally does not have sufficient energy to produce a measurable current when using a photon transducer. A thermal transducer, therefore, is used for infrared spectroscopy. The absorption of infrared photons by a thermal transducer increases its temperature, changing one or more of its characteristic properties. The pneumatic transducer, for example. [Pg.379]

Pneumatic systems use the wave motion to pressurize air in an oscillating water column (OWC). The pressurized air is then passed through an air turbine to generate electricity. In hydrauhc systems, wave motion is used to pressurize water or other fluids, which are subsequendy passed through a turbine or motor that drives a generator. Hydropower systems concentrate wave peaks and store the water dehvered in the waves in an elevated basin. The potential energy suppHed mns a low head hydro plant with seawater. [Pg.111]

SNR s fluidized-bed cogeneiation system is an early example of the commercial development of AFBC technology. Foster Wheeler designed, fabricated, and erected the coal-fired AFBC/boHer, which generates 6.6 MWe and 37 MW thermal (also denoted as MWt) of heat energy. The thermal energy is transferred via medium-pressure hot water to satisfy the heat demand of the tank farm. The unit bums 6.4 t/h of coal and uses a calcium to sulfur mole ratio of 3 to set the limestone feed rate. The spent bed material may be reiajected iato the bed as needed to maintain or build bed iaventory. The fly ash, collected ia two multicyclone mechanical collectors, may also be transferred pneumatically back to the combustor to iacrease the carbon bumup efficiency from 93%, without fly ash reiajection, to 98%. [Pg.260]

The variable-pitch arrangement at constant motor speed changes the pitch of the olades through a pneumatic signal from the leaving-water temperature. As the thermal load and/or the ambient wet-bulb temperature decreases, the blade pitch reduces air flow and less fan energy is required. [Pg.1166]

The capacity of a pneumatic-conveying system depends on (1) produc t bulk density (and particle size and shape to some extent), (2) energy content of the conveying air over the entire system, (3) diameter of conveying hne, and (4) eqmvalent length of conveying hue. [Pg.1928]

Figure 19.16(a) An SFg circuit breaker 123-145 kV, 31.5 kA. It can also be pneumatic or spring operated, depending upon the arc quenching technique adopted and energy required to extinguish 2 the arc (Courtesy BHEL) 3... [Pg.639]

As another example of calculation and dimensioning of pneumatic conveying systems we consider an ejector shown in Fig. 14.20. In fluidized bed combus tion systems a part of the ash is circulated with the hot flue gas. The task of the ejector, is to increase the pressure of the circulating gas to compensate the pressure losses of the circulation flow. The motivation for using an ejector, rather than a compressor, is the high temperature of the flue gas. The energy... [Pg.1353]

Pneumatic or electric Deriving the energy for maintaining the constant flow rate function from an external source. It can be either of the constant or variable type. [Pg.1442]

Lyons, W. C., et al., Field testing of a downhole pneumatic turbine motor , Geothermal Energy Symposium, ASME/GRC, January 10-13, 1988. Magner, N. J., Air motor drill, The Petroleum Engineer, October 1960. Downs, H. F., Application and evaluation of air-hammer drilling in the Permian Basin, API Drilling and Production Practices, 1960. [Pg.1377]

See other pages where Pneumatic energy is mentioned: [Pg.303]    [Pg.232]    [Pg.196]    [Pg.506]    [Pg.407]    [Pg.371]    [Pg.371]    [Pg.333]    [Pg.21]    [Pg.303]    [Pg.232]    [Pg.196]    [Pg.506]    [Pg.407]    [Pg.371]    [Pg.371]    [Pg.333]    [Pg.21]    [Pg.112]    [Pg.319]    [Pg.111]    [Pg.327]    [Pg.328]    [Pg.328]    [Pg.237]    [Pg.251]    [Pg.514]    [Pg.1010]    [Pg.1225]    [Pg.643]    [Pg.17]    [Pg.182]    [Pg.193]    [Pg.79]    [Pg.435]    [Pg.358]    [Pg.1319]    [Pg.302]    [Pg.303]    [Pg.746]    [Pg.96]   
See also in sourсe #XX -- [ Pg.217 ]



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