Copper disk pyrheliometer of high accuracy

C. K. Hsieh; X. A. Wang

doi:10.1364/AO.22.000107

Applied Optics
Vol. 22,
Issue 1,
pp. 107-114
(1983)
•https://doi.org/10.1364/AO.22.000107

Copper disk pyrheliometer of high accuracy

C. K. Hsieh and X. A. Wang

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C. K. Hsieh and X. A. Wang, "Copper disk pyrheliometer of high accuracy," Appl. Opt. 22, 107-114 (1983)

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Abstract

A copper disk pyrheliometer has been designed and constructed that utilizes a new methodology to measure solar radiation. By operating the shutter of the instrument and measuring the heating and cooling rates of the sensor at the very moment when the sensor is at the same temperature, the solar radiation can be accurately determined with these rates. The method is highly accurate and is shown to be totally independent of the loss coefficient in the measurement. The pyrheliometer has been tested using a standard irradiance lamp in the laboratory. The uncertainty of the instrument is identified to be ±0.61%. Field testing was also conducted by comparing data with that of a calibrated (Eppley) Normal Incidence Pyrheliometer. This paper spells out details of the construction and testing of the instrument; the analysis underlying the methodology was also covered in detail. Because of the high accuracy, the instrument is considered to be well suited for a bench standard for measurement of solar radiation.

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Materials	Specific heat equations (J g⁻¹ K⁻¹)	Temperature (K) ranges	References
Copper	c = 0.38304 + 0.0001884 × (T-283)	283–304	17–20
Graphite	c = 0.6583 + 0.002882 × (T-279.94)	270–305	19,21
Solder (50/50 tin/lead)	c = 0.17638 + 0.00008375 × (T-270)	270–310	22

	(g)
Copper Disk	0.4867
Thermocouple wires (bonded to disk)	0.0004
Solder	0.0023
Lacquer	0.0008
3M Nextel Velvet	0.0050
Equivalent mass of wooden supports (3)	7 × 10⁻⁵
Equivalent mass of thermocouple wires (2)	8.8 × 10⁻⁵

	(JK⁻¹)	(%)
Copper disk	0.187526	97.21
Thermocouple wires (bonded to disk)	0.000171	0.09
Solder	0.000411	0.21
Lacquer	0.001072	0.56
3M Nextel Velvet	0.003508	1.81
Equivalent capacitance of wooden supports (3)	0.000191	0.10
Equivalent capacitance of thermocouple wires (2)	0.000037	0.02
Total effective capacitance	0.192916	100.00

Sensor disk diameter (at 22°C)	9.5816 mm
Mass of heat sink	151.5 g
Pyrheliometer body mass (exclusive of sensor and its base 12)	710 g
Aperture diameter (at 22°C)	15.68 mm
Aperture angle	5.7 deg
Shape factors
F_r_–_a	0.0025
F_r_–_b	0.9975
F_r_{–heat sink 9}	0.7567
F_r_–_b − F_r_{–heat sink 9}	0.2408

	Smithsonian silver disk (deg)	Eppley NIP (deg)	Present pyrheliometer (deg)
View angle	5.7	5.7	5.7
Tracking tolerance	0.8	2.1	1.1

Cycle	T(°C)	${(W m^{- 2})}^{H_{0}}$		Difference (%)
1	41.81	1343.07	1344	−0.07
2	41.81	1338.46		−0.41
3	41.78	1334.03		−0.74
4	41.78	1344.15		0.01
Mean		$\bar{H} = 1339.93$		−0.30%

Level	T(°C)	${(W m^{- 2})}^{H_{0}}$		Difference (%)
1	38.57	1341.80	1344	−0.16
2	40.18	1342.97		−0.08
3	41.78	1344.15		0.01
4	43.39	1345.33		0.10
5	45.00	1346.51		0.19
Mean		$\bar{H} = 1344.15$		0.01

Cycle	T(°C)	${(W m^{- 2})}^{H_{0}}$		Difference (%)
1	43.17	1339.19	1344	−0.36
2	42.99	1346.82		0.21
3	42.99	1333.73		−0.76
4	42.98	1338.13		−0.44
5	42.98	1339.21		−0.36
Mean		$\bar{H} = 1339.42$		−0.34

Cycle time (sec)	No. of cycles	Total time used (sec)	H		Difference (%)
Cycle time (sec)	No. of cycles	Total time used (sec)	Eppley NIP (W m⁻²)	Present pyrheliometer (W m⁻²)	Difference (%)
60	5	180	1006.4	1012.2	0.6
30	5	90	988.3	990.6	0.2

Parameters	Estimated uncertainty (%)
m	±0.1
c	±0.25
A	±0.2
α	±0.1
Σ(dT/dt)	±0.5
	Total ±0.61

Parameters	Estimated uncertainty (%)
m	±0.1
c	±0.25
A	±0.2
α	±0.1
Σ(dT/dt)	±0.5
	Total ±0.61

Abstract

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Applied Optics