DE29614330U1 - Portable computer - Google Patents

Description

Description Eco-Computer

Portable computers can be used for some time without the power supply, they are then powered by batteries. In order to significantly extend this time, or to virtually avoid downtime without a power supply, i.e. to be able to work more autonomously and at the same time save mains energy, it is proposed to equip the top of the portable computer beyond the screen with solar cells according to protection claim 1, which is provided with a scratch-resistant and transparent plastic layer as a surface according to protection claim 2. This also makes it possible to charge the batteries when the computer is folded up.

Furthermore, claim 3 proposes switching the solar cell module in such a way that the voltage output matches the charging voltage of the laptop or notebook battery. According to claim 4, the combination with nickel-metal hydride batteries (NiMH) is advantageous because they do not have a memory effect, i.e. they can be constantly charged without suffering a loss of performance.

Solar cells with an efficiency of 18% deliver an output of 11 watts at full load on an available area of 20 x 30 cm ² with an irradiation of 1 kilowatt per m ^2. However, the emission of 1 kilowatt per m ² is the average value for direct sunlight. Indoors with possible artificial or indirect lighting, you can assume a minimum irradiation of 100 watts / m ² , and with direct sunlight up to 500 watts / m ² , especially since the screen is opened when the computer is in use and the solar cells are therefore no longer optimally aligned in the direction of the incoming light. Even with light emission of 100 watts / m ² you still get an output of the solar cells of around 1 watt.

Since a charger has an output of about 20 watts and requires 1.5 hours for the charging process, this means an energy of 30 watts h. With a (realistic) average output of the solar cells of 4 watts, they require 15 hours for the

Charging process. In this case, a charger is usually also required. However, if you assume that the solar cells have an output of 10 watts, the charging process only takes 3 hours. An average notebook can be operated for 3 hours, which means that the working power is 10 watts. Therefore, if the computer is used intensively and the average output of the solar cells is 4 watts, the batteries will be empty after 5 hours. This significantly extends the usage time; in addition, the computer can be used again outdoors or when traveling without a power connection after a reasonable charging time.
Due to the low charging voltage of the portable computer's batteries, the chargers used have a low efficiency of between 60 and 80% (depending on the voltage).

Larger screens require more power because the screen consumes most of the power, but there is correspondingly more space available for solar cells.

It goes without saying that solar cells with the highest possible efficiency should be used. However, these are correspondingly expensive. When calculating profitability, it should be taken into account that, given the expected price collapse for solar cells in the next few years due to mass production, costs for solar cells are expected to be less than 2% relative to the total cost of a notebook. At the moment, the relative costs are around 10%. The first markets of interest are southern countries with high levels of solar radiation, as well as people who work outdoors and those who want to demonstrate their environmental awareness. It would make sense to expand the range of accessories and equipment to include a (replacement) screen equipped with solar cells, as described above.

According to the BMWi's Renewable Energy brochure, the solar radiation per day is on average about 2kWh / m ² . With an efficiency of 18%, the annual average daily energy obtained on the area of 20 cm x 30 cm is about 21 Wh. This means that in outdoor use, as well as in areas with high year-round

In direct sunlight , it is worth using a portable computer with solar cells.

Claims (4)

Utility model eco-computer protection claims 1. Eco-computer, characterized in that a portable computer is equipped with solar cells on its top, beyond the screen, which charge the computer's battery(s). 2. Eco-computer according to claim 1, characterized in that the solar cells are provided with a scratch-resistant and transparent surface layer. 3. Eco-computer according to claim 1, characterized in that the solar cell module is switched in such a way that the voltage output of the solar cells matches the charging voltage of the portable computer’s batteries. 4. Eco-computer according to claim 1, characterized in that the solar cell module is used in combination with nickel-metal hydride batteries.