𝔖 Bobbio Scriptorium
✦   LIBER   ✦

A low temperature thermocouple with a copper—iron arm

✍ Scribed by V.M. Beilin; I.Ya. Levin; L.A. Medvedeva; M.P. Orlova; I.L. Rogel'berg

Publisher
Elsevier Science
Year
1973
Tongue
English
Weight
88 KB
Volume
13
Category
Article
ISSN
0011-2275

No coin nor oath required. For personal study only.

📜 SIMILAR VOLUMES

Low temperature thermoelectric power of
Low temperature thermoelectric power of gold-iron vs Copper thermocouples
✍ R.L. Rosenbaum; R.R. Oder; R.B. Goldner 📂 Article 📅 1964 🏛 Elsevier Science 🌐 English ⚖ 96 KB

have reported on the high thermopower of dilute goldiron alloys as compared with gold-cobalt alloys below 15 ° K. They have found that the gold-iron thermopower at 1 ° K is ten times higher than the thermopower of gold-cobalt and that the calibration of any given gold-iron thermocouple is reproducib

The effect of a magnetic field on a copp
The effect of a magnetic field on a copper-constantan thermocouple at low temperatures
✍ W.F. Schlosser; R.H. Munnings 📂 Article 📅 1972 🏛 Elsevier Science 🌐 English ⚖ 148 KB

The influence of a magnetic field on the Seebeck effect for a copper-constantan thermocouple was studied. Measurements of the change in Seebeck voltage were carried out with only one thermocouple junction in the magnetic field at varying magnetic field and constant sample temperature. The magnetic f

Measuring temperature in a flowing gas-s
Measuring temperature in a flowing gas-solids suspension with a thermocouple
✍ B. S. Brewster; J. D. Seader 📂 Article 📅 1984 🏛 American Institute of Chemical Engineers 🌐 English ⚖ 414 KB 👁 2 views

= velocity integrals defined by Eqs. 17 and 18 = velocity function, defined by Eq. 6 = constants, defined by Eqs. 1 to 3 and 12 to 14 = jet exit radius (m) = radius of potential core (m) = radius of jet edge (m) = velocity at jet exit (m/s) = length of potential core (m) = radial distance, Figure 1