Jonathan Wu Spårvagnsaktiebolagsskensmutsskjutare
#6
1. I would install solar panels both horizontally and south-facing. I'd place the panels horizontally because the longest-lasting strongest solar radiation waves occur throughout the summer months there. I also chose place solar panels that were south-facing. I could have also chosen the east or west but opted otherwise. The West had a consistent amount of radiation but was relatively weak. The East had stronger radiation, but that only occurred during the summertime, and yet, was weaker than the horizontal option. The south, however, was weak during the summer but extremely strong in the winter. This, the balance of strong radiation between summer and winter calls for horizontal and south.
2. The temperatures here are, for the most part, not in the comfort zone. It is almost always cold, year-round, but when it does become hot, it tends to exceed to comfort zone and become TOO hot. It would thus be ideal for the occupants of the house, before they install a mechanical system, to consider a change in insulation of the house.
3. Demand for heating/cooling depends on the time of day. It would seem quite logical that the demand for heating, as shown on the charts, drops to nothing because nobody is in the building. The demand for heating occurred in the winter during the mornings and evenings, while the demand for cooling occurs during the day.
We see the demand for cooling drop when air ventilation is equipped, but the demand for heating remains indifferent.
4. The variations of clouds in the sky during the winter is more prominent and consistent. Daylight in the summer is more frequent than in the winter. We can resolve this by adding movable shades. During the summer, the shades can block out the sunlight which would reduce heat, and during the winter, the shades could be open for to allow sunlight which would add heat. During the winter, the shades would need to open enough to allow the sun to heat up the room, but not for too long so that coolness from outside is conducted through the thinly insulated glass.
#6
1. I would install solar panels both horizontally and south-facing. I'd place the panels horizontally because the longest-lasting strongest solar radiation waves occur throughout the summer months there. I also chose place solar panels that were south-facing. I could have also chosen the east or west but opted otherwise. The West had a consistent amount of radiation but was relatively weak. The East had stronger radiation, but that only occurred during the summertime, and yet, was weaker than the horizontal option. The south, however, was weak during the summer but extremely strong in the winter. This, the balance of strong radiation between summer and winter calls for horizontal and south.
2. The temperatures here are, for the most part, not in the comfort zone. It is almost always cold, year-round, but when it does become hot, it tends to exceed to comfort zone and become TOO hot. It would thus be ideal for the occupants of the house, before they install a mechanical system, to consider a change in insulation of the house.
3. Demand for heating/cooling depends on the time of day. It would seem quite logical that the demand for heating, as shown on the charts, drops to nothing because nobody is in the building. The demand for heating occurred in the winter during the mornings and evenings, while the demand for cooling occurs during the day.
We see the demand for cooling drop when air ventilation is equipped, but the demand for heating remains indifferent.
4. The variations of clouds in the sky during the winter is more prominent and consistent. Daylight in the summer is more frequent than in the winter. We can resolve this by adding movable shades. During the summer, the shades can block out the sunlight which would reduce heat, and during the winter, the shades could be open for to allow sunlight which would add heat. During the winter, the shades would need to open enough to allow the sun to heat up the room, but not for too long so that coolness from outside is conducted through the thinly insulated glass.