Thermodynamic Testing of Turbines and Pumps

Abstract

Hydraulic losses experienced by fluids in passing through machines effectively raise the temperature. The thermodynamic method of testing is basically a way of determining these losses by measuring temperature rise. When pressure change through a machine is measured along with temperature, the enthalpy change is known and the hydraulic efficiency can be evaluated. Knowledge is necessary of certain thermodynamic properties of the liquid which change with pressure and temperature. Heat transfer between the machine and its surroundiings is assumed to be negligible.

Apparatus is described for use in several different applications of the method, but principally in the thermometric and null methods. Temperature change has usually been measured by resistance thermometers in various bridge networks. Three types of bridge are discussed, the direct current, the transformer ratio and the hydraulic bridge. Methods of sampling small quantities of the main flow are described for the null method; when the two thermometer pockets are in streams having different velocities, a differential recovery factor has to be applied. Calorimeter design details are given, with a brief review of tests in the U.K. and abroad.

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References

Fontaine

‘Quelques applications de la méthode thermometrique Poirson’, La Houille Blanche 1951 (January/February).

Umpfenbach

K. J.

‘Calorimetric measurements of the efficiency of water turbines’ (in German), Z. Ver. dtsch. Ing. 1937 81 (No. 41, 9th October), 1203.

Katzman

‘Determination of the efficiency of a hydraulic turbine by a calorimetric method’, Canad. J. Research 1948 26 (No. 12, Section F), 513.

Willm

Campmas

‘Efficiency measurements for hydraulic turbines by the Poirson thermometric method’ (in French: Translated by Mrs E. Babister), La Houille Blanche 1954 9 (Nos 4, 5), 449, 550.

Holt

J. V. H.

‘Measuring pump efficiencies by thermometry’, Engineering, Lond. 1958 (18th April).

Brand

F. L.

‘Measurement of the effieciency of hydraulic machines by the thermodynamic method’ (in German), Voith Forsch. Konstr., Heidenheim 1961 (No. 7).

Leslie

W. H. P.

Hunter

J. J.

Robb

‘Precision temperature measurement outside the laboratory’, Research (G.B.) 1960 13 (No. 7), 250.

Langlands

R. C.

‘A stable copper resistance thermometer for field use’, J. Sci. Instrum. 1964 41 (July).

Rögener

Arens-Fischer

‘Bestimmung des inneren Wirkungsgrades von Kesselspeisepumpen aus der Messung von Druck und Temperatur’, Brennstoff-wärme-Kraft (Sonderdruck) 1959 11 (No. 11), 516.

10.

Singh

D. N.

‘Thermodynamic method of measuring turbine efficiency’, M.E.R.L. Fluids Report No. 70, 1958.

11.

Foord

T. R.

Langlands

R. C.

Binnie

A. J.

‘Transformer ratio bridge network with precise lead compensation for the measurement of temperature and of temperature difference’, Proc. Instn elect. Engrs, Lond. 1963 110, 1693.

12.

Barber

C. R.

‘Platinum resistance thermometers of small dimensions’, J. Sci. Instrum. 1950 27 (No. 2), 47.

13.

El Agib

A. A. R.

‘Pair ratio method’, J. Sci. Instrum. 1964.

14.

Thom

A. S.

‘Flow measurement by the thermodynamic method at Finlarig power station’, M.E.R.L. Fluids Report No. 76, 1959.

15.

Thom

A. S.

Ahmad

S. Y.

‘Thermodynamic method of measuring turbine efficiency, including a special technique for low heads’, N.E.L. Report No. 17, 1962.

16.

El Agib

A. A. R.

‘Hydraulic bridge for measuring small temperature difference’, J. Sci. Instrum. 1964 41, 596.

17.

Foord

T. R.

Langlands

R. C.

El Agib

A. A. R.

‘New developments in the thermometric method of measuring hydraulic efficiency and flow’, N.E.L. Report No. 130, 1964.

18.

Ahmad

S. Y.

‘Thermodynamic method of measuring efficiency of hydraulic machines’, Ph.D. thesis, Glasgow University, 1963.

19.

Vaucher

‘Thermodynamic measurements of the efficiency of hydraulic machines’, Escher Wyss News 1960, 69.

20.

Thom

A. S.

Singh

D. N.

‘Thermodynamic method of measuring turbine efficiency: further measurements at low and high-head turbines’, N.E.L. Fluids Report No. 93, 1960.

21.

Spencer

E. A.

Winternitz

F. A. L.

‘Comparative flow-measurement tests at Finlarig power station’, N.E.L. Report No. 148, 1964.

22.

McPherson

M. J.

Hinsley

F. B.

‘Thermometric testing of fans’, Heating Ventilating Engng 1963 (October), 175.

23.

Gabaudan

(Secretary, Groupe des Praticiens de la Méthode Thermodynamique, 37 Rue Diderot, Grenoble, France).

24.

Serpaud

Coffin

‘Thermodynamic method of measuring efficiencies of hydraulic machines’ (in French), I.M.E.K.O. Budapest, Separata 21-Fr-134, 1961.

25.

Tsu

T. C.

Beecher

D. T.

‘Thermodynamic properties of compressed water’, Amer. Soc. mech. Engrs publication, 1957.

26.

Brand

F. L.

‘Bemerkungen zur Messung des Wirkungsgrades von Turbinen und Pumpen nach dem thermodynamischen Verfahren’, Voith Forsch. Konstr., Heidenheim 1962 (No. 9).

27.

British Standard No. 353: 1962, ‘Methods of testing water turbine efficiency’.

28.

International Electrotechnical Commission Publication No. 41, second edition, 1963, ‘International code for the field acceptance tests of hydraulic turbines’.

29.

El Agib

A. A. R.

‘Principles of the thermodynamic method of measuring hydraulic efficiency’, N.E.L. Report No. 163, 1964.

30.

Dorsey

N. E.

Properties of ordinary water substance 1940 (Reinhold, New York).

31.

Bain

W. R.

‘Steam tables (physical properties of water and steam 0-800°C, 0-1000 bars)’, N.E.L. 1964.

32.

‘Specific volume of water 0-300°C, 0-1200 kg/cm²’ (in Russian), Teploenergetika (Moscow Institute of Energy) 1960 (No. 7, July), 4.