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Sains Malaysiana 45(5)(2016): 689–697
Horizontal Heat Flux between Urban Buildings and Soil and Its Influencing Factors (Fluks
Haba Mendatar antara Bangunan Bandar dan Tanah serta Faktor yang Mempengaruhinya)
HONGXUAN ZHOU, XIAOLIN WANG, YUANZHENG LI, FENGSEN HAN
& DAN HU*
State Key Laboratory of Urban and Regional Ecology, Research
Center for Eco-Environmental Sciences, Chinese Academy of Sciences, Beijing
100085, PR China
Diserahkan: 12 Jun 2015/Diterima: 3 Disember 2015
ABSTRACT
The soil temperature near four external walls with different
orientations was investigated in spring and summer. In both seasons, the soil
temperature was higher in the positions closest to the buildings, suggesting
that the buildings were a heat source for the soil surrounding them. Therefore,
it could be confirmed that there was lateral heat transfer between the soil and
the buildings. Based on this, a soil heat flux plate was set between the soil
and the buildings to investigate the horizontal heat flux. The data showed
diurnal variations of the horizontal heat flux in both spring and summer. In
order to determine the factors that influenced the horizontal heat flux and to
provide a basis to understand its mechanism, the correlations between the data
of several meteorological factors and the horizontal heat flux were analysed.
The results showed that solar radiation was significantly correlated with the
horizontal heat flux (p<0.0001)
in any single season and in the two seasons that were studied. Additionally,
other meteorological factors (net radiation, air temperature, relative humidity
and soil temperature and moisture) showed strong correlations with the
horizontal heat flux on a diurnal scale only. On a seasonal time scale, the
correlation might be significant (p<0.0001) as well, but the
correlation coefficients decreased too significantly, such as those for soil
temperature, air temperature and relative humidity. Alternatively, the
correlation might not be significant (p>0.05), such as that for soil
moisture. The stepwise regression results indicated that the relative
importance of these meteorological factors was 48.63, 21.94, 14.44, 8.12 and
6.87% for solar radiation, soil temperature, air temperature, relative humidity
and soil moisture, respectively, on a diurnal scale.
Keywords: Building; construction; horizontal heat flux; soil
temperature; urban area
ABSTRAK
Suhu tanah berhampiran empat dinding luar dengan
orientasi yang berbeza telah dikaji pada musim bunga dan musim panas. Dalam kedua-dua musim, suhu
tanah adalah lebih tinggi dalam kedudukan paling hampir dengan bangunan,
menunjukkan bahawa bangunan adalah sumber haba untuk tanah di sekeliling
mereka. Oleh itu, ia boleh mengesahkan
terdapat pemindahan haba sisi antara tanah dan bangunan. Berdasarkan
ini, plat fluks haba tanah telah ditubuhkan antara tanah dan bangunan
untuk mengkaji fluks haba mendatar. Data
menunjukkan variasi diurnal fluks haba mendatar dalam kedua-dua
musim bunga dan musim panas. Untuk menentukan
faktor yang mempengaruhi fluks haba mendatar dan untuk menyediakan
asas untuk memahami mekanismenya, korelasi antara data daripada
beberapa faktor meteorologi dan fluks haba mendatar telah dianalisis.
Hasil kajian menunjukkan bahawa sinaran suria
telah mempunyai hubungan yang signifikan dengan fluks haba mendatar
(p<0.0001) dalam mana-mana musim tunggal dan dalam dua musim
yang dikaji. Selain itu, faktor meteorologi lain (sinaran
bersih, suhu udara, kelembapan dan suhu tanah dan kelembapan) menunjukkan
korelasi yang kuat dengan fluks haba mendatar pada skala yang diurnal
sahaja. Pada skala masa bermusim, korelasi mungkin signifikan (p<0.0001) juga, tetapi pekali korelasi menurun terlalu ketara,
seperti yang untuk suhu tanah, suhu udara dan kelembapan relatif.
Sebagai alternatif, korelasi mungkin tidak signifikan (p>0.05),
seperti untuk kelembapan tanah. Keputusan regresi ikut langkah menunjukkan
bahawa kepentingan relatif faktor meteorologi adalah 48,63, 21,94,
14,44, 8.12 dan 6.87% masing-masing untuk radiasi solar, suhu tanah,
suhu udara, kelembapan dan kelembapan tanah pada skala yang diurnal.
Kata kunci: Fluks haba
mendatar; kawasan bandar; pembinaan; suhu tanah
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*Pengarang untuk surat-menyurat; email: hudan@rcees.ac.cn
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