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Refrigeration systems schematic

Figure 4.23 The metal hydride refrigeration system schematic (Qin et al.,2007). Figure 4.23 The metal hydride refrigeration system schematic (Qin et al.,2007).
A schematic of the two-level refrigeration system is shown in Fig. 6.406. It should be noted that the single exchangers represented in Fig. 6.406 might in practice be several exchangers. [Pg.208]

Figure 17. Schematic diagram of refrigeration system. Courtesy of Crown Chemtech U.S.A., a division of Crown iron Works Co., Minneapoiis, Minnesota. [Pg.2891]

Fig. 1. Schematic representation of vacuum furnace closed-cycle helium refrigeration system used for metal vapor microsolution optical spectroscopy, as well as conventional metal vapor-matrix isolation experiments. (A) NaCl or Suprasil optical window, horizontal configuration (B) stainless steel vacuum shroud (C) NaCl or Suprasil optical viewing ports (D) cajon-rubber septum, liquid or solution injection port (E) gas deposition ports (F) vacuum furnace quartz crystal microbalance assembly. With the optical window in a fixed horizontal configuration, liquid or solution sample injection onto the window at any desired temperature in the range 12-300 K is performed in position 1A, metal deposition is conducted in position IB, and optical spectra are recorded in position 1C see Procedure). Fig. 1. Schematic representation of vacuum furnace closed-cycle helium refrigeration system used for metal vapor microsolution optical spectroscopy, as well as conventional metal vapor-matrix isolation experiments. (A) NaCl or Suprasil optical window, horizontal configuration (B) stainless steel vacuum shroud (C) NaCl or Suprasil optical viewing ports (D) cajon-rubber septum, liquid or solution injection port (E) gas deposition ports (F) vacuum furnace quartz crystal microbalance assembly. With the optical window in a fixed horizontal configuration, liquid or solution sample injection onto the window at any desired temperature in the range 12-300 K is performed in position 1A, metal deposition is conducted in position IB, and optical spectra are recorded in position 1C see Procedure).
Fig. 1.17. Schematic diagram of a continuous cold stabilization system 1, intake of wine to be treated 2, heat exchanger 3, refrigeration system (with compressor, condenser, etc.) 4, insulation 5, mechanical agitator 6, recycling circuit (optional) 7, outlet of treated wine 8, filter (earth) 9, drain 10, overflow... Fig. 1.17. Schematic diagram of a continuous cold stabilization system 1, intake of wine to be treated 2, heat exchanger 3, refrigeration system (with compressor, condenser, etc.) 4, insulation 5, mechanical agitator 6, recycling circuit (optional) 7, outlet of treated wine 8, filter (earth) 9, drain 10, overflow...
Fig. 12.1. Schematic diagram of a cold-stabilization installation A, untreated wine (- -14°C) B, treated wine (- -5°C) C, wine during stabilization (—5°C) 1, untreated wine pump 2, treating wine at —5°C (refrigeration system and plate heat exchanger) 3, filter at the end of cold treatment 4, pump for cold-stabilized wine, ready to be filtered 5, heat exchanger for precooling wine to be treated by using it to warm treated wine... Fig. 12.1. Schematic diagram of a cold-stabilization installation A, untreated wine (- -14°C) B, treated wine (- -5°C) C, wine during stabilization (—5°C) 1, untreated wine pump 2, treating wine at —5°C (refrigeration system and plate heat exchanger) 3, filter at the end of cold treatment 4, pump for cold-stabilized wine, ready to be filtered 5, heat exchanger for precooling wine to be treated by using it to warm treated wine...
Fig. 2.8 Schematic of refrigeration system a vapor compression and b vapor absorption... Fig. 2.8 Schematic of refrigeration system a vapor compression and b vapor absorption...
Figure 8.5 Schematic Diagram of a Simple Cascaded Refrigeration System... Figure 8.5 Schematic Diagram of a Simple Cascaded Refrigeration System...
Solution. Figure 4.9 provides a schematic for the refrigeration system described. From the temperature-entropy property tabulations of Dean for n-H2 we have... [Pg.127]

Fig. 16.3. Left Schematic picture of the damping system of MimiGRAIL. The suspension consists of seven stages, the upper four made of CuAl followed by three copper masses. The upper CuAl mass is suspended from the top flange of the cryostat by stainless steel cables hanging from helical springs. Mass number 5, the first copper mass, will be cooled by the dilution refrigerator. Right Picture of the four CuAl masses hanging from the top flange (courtesy of Leiden Cryogenics). Fig. 16.3. Left Schematic picture of the damping system of MimiGRAIL. The suspension consists of seven stages, the upper four made of CuAl followed by three copper masses. The upper CuAl mass is suspended from the top flange of the cryostat by stainless steel cables hanging from helical springs. Mass number 5, the first copper mass, will be cooled by the dilution refrigerator. Right Picture of the four CuAl masses hanging from the top flange (courtesy of Leiden Cryogenics).
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Refrigeration systems

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