Summary
The feasibility of a snow-melting system using low-temperature fluid circulation was examined experimentally.
First, the relationship between pipe embedded depth (d) and pipe pitch (p) were examined by using the steady-state line-source theory. Unevenness of heat flux emitted from the slab surface is approximately 10% at d/p of 0.48 and 20% at d/p of 0.38. The results of analysis of dimensionless heat flow from pipe surface and dimensionless pipe surface temperature showed that recommended d/p is between 0.35 and 0.43 in the case of 1.27 cm pipes and 150 mm pitch.
Two experimental slabs for snow melting were constructed on the campus of Hokkaido University in Sapporo. Slab A featured concrete for the surface layer and the pipe-embedded layer, while slab Β had asphalt for the surface layer over sand and cement in the embedded layer. Both utilized hot-fluid systems. 1.27 cm plastic pipes were embedded in the slab at a depth of 60 mm as dictated by the results of our theoretical analysis. Pipe pitch was 150 mm and the ratio of depth to pitch (d/p) was 0.6.
The continuous experiment, in which low-temperature fluid at either 15°C or 10°C was circulated continuously, was conducted 27 December 1991–17 January 1992. Figure 1 shows the percentages of time during the total experiment in which surface temperature was maintained above 0°C. With fluid constantly circulated at 15° or 10°C, these values were about 98% and 85%, respectively, in the case of slab A, and about 70% and 62%, respectively, in the case of slab B. Therefore, a snow-melting system based on continuous circulation of low-temperature fluid is feasible in the city of Sapporo.
Fig. 1. Percentages of the time the surface temperature was maintained above 0°C.
The intermittent experiment, in which fluid at 25°C and 40°C was circulated intermittently, linked with a snowfall catch sensor and a delay timer, ran 17 January-23 March 1992. The snow-covered area ratio, (i.e. the ratio of snow-covered area to total slab surface area at 2100h) was introduced to estimate the performance of snow melting. These values were classified into ten stages between 0.0 and 1.0 by photographs. Figure 2 shows the relationship between circulated-fluid temperature and required surplus circulating time after snowfall had stopped when the covered-area ratio per daily amount of precipitation was < 0.05. In the case of concrete slabs, a long surplus time is required to satisfy this condition where fluid temperature is <30°C. However, if fluid temperature is >35°C, no surplus time is required. Therefore, 30°C is the minimum circulated-fluid temperature to melt snow with a relatively high efficiency and short surplus time. However, a fluid-temperature increase of 5°C is required in the case of asphalt slabs.
Fig. 2. The relationship between the circulated-fluid temperature and required surplus time satisfied the covered-area ratio per daily precipitation under 0.05.
