Which electricity generation method is best among wind power, thermal power and solar power at the beginning of the Dyson Sphere plan? Let me share with you an analysis of the advantages and disadvantages of wind energy, thermal energy and solar energy for your reference.
Analysis of the advantages and disadvantages of wind energy, thermal energy and solar energy in the Dyson Sphere project
For wind energy, the thermal energy and photoelectricity, each of these three has its own Advantages and disadvantages Compared with Dyson's small stars and clouds, personally, the three are basically on the same level. I just want to share my thoughts on my gaming experience.
Wind Energy
First, let's talk about wind energy. As the first electrical installation at the start of the game, it's definitely something not everyone pcould not get around. Its advantages are obvious: it is simple to manufacture, easy to obtain raw materials, easy to use and scrub, and stable power generation.
The disadvantages are: low energy production, large floor space, difficult installation, high requirements for planetary wind resources and inability to power large-scale production modules.
Wind power is generally used as a transitional energy source at an early stage, and it is recommended to be used at an early stage. In the medium term, wind energy could be used to power mines, oil fields and warehouses far from the center of production. You can also place one or two next to the thermal power station cluster to power the claws to avoid unexpected power outages.
Of course, if your home planet is surrounded by a planet with wind efficiencyne more than 130-40%, filling it with wind pillars is also a good choice.
Solar energy
The second is solar energy. Its advantages are obvious: it occupies a small area, is relatively simple to manufacture and has stable electricity production if any. Tide lock satellite at first it will be mostly covered in solar power. It can last until the small solar stage.
The disadvantages are: low power generation, tedious and time-consuming installation, high requirements for planetary light energy resources, low power supply for large-scale production modules, the need for a dedicated photovoltaic production line, which needs to be grouped in small quantities and has almost no effect.
If there are tide-locked satellites, it is more cost-effective to spend time setting up the solar clusters. But the problem ist that batteries must be transported across planets. Without logistics, transportation stations and energy centers, they are of little use. At the same time, battery manufacturing remains very tedious and time-consuming. And if this planet provides electricity, it must have a solar belt. As a trypophobic patient, to be honest, it is really unbearable to run four or five solar panels along the equator.
Of course, if a novice has the leisure to slowly lay out thousands of boards, this thing is indeed once and for all. As long as he doesn't die after laying the boards, he basically won't do it. run out of power.
Thermal energy
The advantage of the third thermal energy is that compared with photovoltaic and wind energy, the power is much higher. Carrying a set (20 pieces) with you is quite enough. for aliment any early production module. It is suitable for the production of small modules before the output of the logistics tower battery energy center. It is very suitable for sugar by-products in early and middle stages. directly after its release, which avoids the accumulation of oil cracking by-products causing stagnation in production.
Disadvantages: it occupies a large area, it is easy to get stuck when connecting in series with prongs along the chain, and power generation is unstable - if the global power grid is established, the network load must be considered first whenever the plant layout is changed. Otherwise, it would easily cause a global blackout.
In fact, I personally think that thermal energy itself can be used as a by-product of brown sugar and brown sugar in the medium term to preventer the accumulation of petroleum cracking products. Search the forum for ". What if the production line is blocked due to too much hydrogen/graphite? How many people have a love-hate relationship with the byproducts. After all, when the stadium of oil cracking will be achieved, no one will burn coal
Here is my method of using thermal energy (taking as an example the brown sugar production line which produces 120 units/min) :
In order to avoid a global blackout, my thermal power is basically not used globally. The networking is based on on-site combustion of by-products (. graphite, hydrogen) in modular factories on site, and each module is disconnected
For the 120 pieces/min brown sugar production line, the number of factories quantified is as follows: 16 stations. research, 16 refining furnaces, 8 manufacturing stationson secondary, 24 chemical factories, 56 oil cracking stations, 5 ~7 oil pumping stations (related to oil well production), 3 water pumping stations, 352 third-level claws of a power total of 129.34 MW.
1,560 thermal power plants are produced every minute and the thermal power plant consumes 8 MW*0.8/2.16 = 20 hydrogen per minute. A total of 1,560/20 = 78 thermal power plants are needed, with an electricity production of. 2.16*78=168MW. Including the 8 wireless batteries that I carry with me for fast charging, the total power required is 129.34+4*8=161.34 MW.
The power grid workload is 77% and the maximum mecha load load is 96%.
If you like solar energy + wind energy, it is recommended to choose a good seed at the beginning, preferably lava + Gobi double lock + gas planet.
Lava has high yields of copper, iron and titane, the Gobi has high yields of silicon and the gas planets have high yields of hydrogen and heavy hydrogen. The lava is close to the star and has a high light energy utilization rate, and Gobi's wind energy utilization rate is high in the early and mid-term, you can start to arrange the boards and insert sticks to prepare the resource planet afterwards. leave the local star.
The permanently lit side of the lava planet is completely covered in solar panels, while the permanently lit side of the Gobi Desert is completely covered in wind energy rods and the spaces between the rods are filled with solar energy. . It is estimated that the two energy stars brought together by the Yongye hub battery are capable of supplying the Dyson sugar ball in one step.
Required. Piles can improve the bearing capacity of foundations, making foundationse home more stable and more reliable. They can also prevent foundations from leaking and causing damage to the home. They are also very effective in resisting natural disasters such as typhoons and earthquakes. . Wind turbines are electrical equipment that convert wind energy into mechanical work, which causes the rotor to rotate and ultimately produces alternating current. Wind turbines generally consist of components such as a wind wheel, a generator (including devices), a steering (tail), a tower, a speed-limiting safety mechanism, and an energy storage device. Xinjiang Hami Wind Base is a 2 million kilowatt wind power development base built in southeast Hami in August 2010.