Difference between revisions of "Electricity/zh"
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*'''发电优先顺序''': | *'''发电优先顺序''': | ||
:在网格需求发电的时候,会先采用可持续的太阳能发电,然后由氢电和核电不足,最后才是电池(因为蓄电有损耗20%其实是相当大),这中次序有效节省发电原料和蓄电损耗。 | :在网格需求发电的时候,会先采用可持续的太阳能发电,然后由氢电和核电不足,最后才是电池(因为蓄电有损耗20%其实是相当大),这中次序有效节省发电原料和蓄电损耗。 | ||
− | :# [[Solar Panel| | + | :# [[Solar Panel|太阳能板}}]] / [[Wind Turbine|风轮机]] |
− | :# [[Hydrogen Engine| | + | :# [[Hydrogen Engine|氢气引擎]] |
:# [[Large Reactor|大号反应堆]] / [[Small Reactor|小号反应堆]] | :# [[Large Reactor|大号反应堆]] / [[Small Reactor|小号反应堆]] | ||
:# [[Battery|电池]] | :# [[Battery|电池]] |
Revision as of 13:05, 8 November 2021
电(Electricity) 被作为《太空工程师》中使大多数设备工作的能源系统存在。
游戏中,电能可通过《发电》类设备生产获得,供给《网格》(含《相连网格》)的《用电》,还可安装《蓄能》设备缓冲电力产能,以作后备供电源用。
Contents
多主题相关小提示
《同网格》 以及 《互连网格》 上的所有设备共享电力
电 的计算 及 基础认知
《太空工程师》中,
- 任何能量传递和转化的效率(即:功率)以 瓦(或W)为记量;下列图表中也会遇到高量级单位千瓦(或KW)、兆瓦(或MW)。
- 电能量的衡量(即:电功)以瓦时(或Wh)为记量(时一般以小时计);意思是 以某功率 持续作业多久(即:功率 x 作业时间)。
- 举个例子:用电设备工作功率 500瓦 ,需要工作 5小时,用于供电的电池设备 需储备电能量为 500瓦(W) x 5小时(h) = 2500瓦时(Wh) = 2.5千瓦时(KWh)
游戏中在蓄电和供电设备信息界面中会常常接触到这些电学数值,下表有助于记忆不同量级单位转换时的比值关系。
量级对照 | 瓦 (W) | 千瓦 (kW) | 兆瓦 (MW) |
---|---|---|---|
兆瓦 (MW) | 1 000 000 W | 1 000 kW | 1 MW |
千瓦 (kW) | 1 000 W | 1 kW | 0.001 MW |
瓦 (W) | 1 W | 0.001 kW | 0.000 001 MW |
发电装置中的,核发电站 反应堆 以 铀锭 为原料发电,其 1公斤(kg)可产出 1兆瓦时(MWh)电能量
- 规模更大的核发电站,只是加速反应,缩短时间,料能效率不变。
- 大网格的“小型核反应堆” 供电功率为 15兆瓦(MW),只需要 4分钟( 0.06~小时)就可令1公斤原料反应完毕(产出 1兆瓦时 电能量)
- 大网格的“大型核反应堆” 供电功率为 300兆瓦(MW),只需要 12秒钟(0.003~小时)就可令1公斤原料反应完毕(产出 1兆瓦时 电能量)
电池蓄电效率为80%,放电无损耗。
- 大网格的“电池” 满足蓄电功率上限 12兆瓦,从0蓄电到3兆瓦时(MWh)满充需要 18.75分钟(需实多段计时测量),而此时耗理应可充3.75兆瓦时,其中这0.75兆瓦时被浪费(即蓄电效率80%,浪费20%),但放电无损耗
- 因此从抑制浪费的角度而言,用不可持续核电reactors还是可持续发电(比如太阳能solar panels )的之间,太阳能更适合为电池充电.
- 电池会试图为自己充电?
- 电池为电池充电,放电方无损耗,蓄电方效率80%.
电能配给优先策略
《太空工程师》的电能被策略性地定义了一个优先顺序,分别为需要发电的优先次序和基于耗电权的优先次序,
- 发电优先顺序:
- 在网格需求发电的时候,会先采用可持续的太阳能发电,然后由氢电和核电不足,最后才是电池(因为蓄电有损耗20%其实是相当大),这中次序有效节省发电原料和蓄电损耗。
- 给电优先顺序:
- 对不同用电的设备安排了如下按子系统类别的用电优先次序,有些子系统可以适应电能供量而调整输出大小(比如推进,电池)会排在相对后序,而有些一旦不足电量就会自动停机(比如输送,防御)会排在相对优先,电池最后。
- (防御)Defense - Interior Turret, Missile Turret, etc
- (输送)Conveyors - Conveyor, Conveyor Tube, blocks that make up the Conveyor Network, etc
- (生产)Factory - Refinery, Assembler, Oxygen Generator, Air Vent, Oxygen Tank, etc
- (门控)Doors - Door, Airtight Hangar Door, etc
- (应用)Utility - Communications, Lights, Rotor, Piston, Medical Room, Gravity Generator, the vast majority of electronics, etc
- (充能)Charging - Jump drive, specifically players inside cockpits or passenger chairs, recharging their suits.
- (翻滚)Gyro - All Gyroscopes
- (推进)Thrust - Standard Thrusters, but not hydrogen based thrusters
- (电池)Batteries - Any Batteries attempting to charge themselves.
设备
电源
供电: Large Reactor, Small Reactor, Wind Turbine, Hydrogen Engine, or Solar Panel. 小网格: 太阳能板;小号核能站,大号核能站,氢电站
大网格: 太阳能板;小号核能站,大号核能站,氢电站;风力发电站
用电
常态耗电 待机、使用不同阶段耗电
需电
只需要待机电力 需要其它用电设备提供上游工作流程,但本体设备无需用电
无源
太空球(大,小) 起落架 磁铁头
能源(电能)
Maximum output for Electricity Sources:
Energy Source | Block size | Dimensions [size in m3] |
Maximum Output [kW] |
Mass [kg] |
Mass Efficiency [kW/kg] |
Energy Density [kW/m3] | |
---|---|---|---|---|---|---|---|
Large Reactor | Large | 3x3x3 [421.875 m3] | 300 000 | 73795 | 4.065 | 711.11 | |
Small | 3x3x3 [3.375 m3] | 14 750 | 3901 | 3.781 | 4370.37 | ||
Small Reactor | Large | 1x1x1 [15.625 m3] | 15 000 | 4793 | 3.130 | 960 | |
Small | 1x1x1 [0.125m3] | 500 | 278 | 1.799 | 4000 | ||
Solar Panel | Large | 2x4x1 [125 m3] | 120* | 441.4 | 0.272 | 0.96 | |
Small | 5x10x1 [6.25m3] | 30* | 159.2 | 0.188 | 4.8 | ||
Battery | Large | 1x1x1 [15.625 m3] | 12 000 | 4845 | 2.477 | 768 | |
Small | 3x2x3 [2.25m3] | 4 320 | 1040.4 | 4.152 | 1920 |
(*) Solar Panels have a maximum output depending on their angle to the sun and the amount of actually lit surface. Given values are the maximum achievable output with perfect conditions, therefore efficiency and output may vary.
Large Reactor vs Small Reactor
Comparing them directly, the small reactor provides far more energy for the space it takes up; for example, 20 Small Reactors is equal to the output of a Large Reactor with only two-thirds of the space used. Despite this the large reactor offers greater economies of scale, requires less Conveyor complexity and in general is more useful in a variety of important applications especially as Powerplants for Large Ships, being both lighter and requiring fewer resources to construct. This makes Large Reactors ideal for ships that can take advantage of their reduced mass and accelerate or decelerate more easily, and therefore use less Uranium Ingots. Small Reactors are therefore ideal for stations that do not need to move, situations where physical space is precious or presents relatively light power needs that would not require a larger more expensive reactor. For example, a large reactor only needs 40 Metal Grids while a small reactor needs 4 Metal Grids at approximately 10 Small Reactors (150 MW) you would start to see economy of scale benefits clearly when using the large reactor. Between them however, they use Uranium Ingots equally as efficiently neither one will manage to extract more energy than they would otherwise have to.
Power Usage
Thruster
For power information relating to thrusters, see Thruster Mechanics.
Production (Individual Usage)
Machine | Idle [kW] | Operational [kW] | |
---|---|---|---|
Projector | 0.100 | 0.198 | |
Arc Furnace | 1.00 | 330 | |
Assembler | 1.00 | 560 | |
Refinery | 1.00 | 560 | |
Oxygen Generator | 1.00 | 330 | |
Oxygen Farm | 0.00 | 1 |
Weaponry and tools
Device | Small Ship [kW] | Large Ship [kW] | |
---|---|---|---|
Drill | 2 | 2 | |
Welder | 2 | 2 | |
Grinder | 2 | 2 | |
Gatling Turret | 2 | 2 | |
Missile Turret | 2 | 2 | |
Interior Turret | N/A | 2 | |
Reloadable Rocket Launcher | 0.2 | N/A | |
Gatling Gun | 0.2 | N/A |
Communication
Device | Small Ship [kW] | Large Ship [kW] | |
---|---|---|---|
Beacon | 0 - 10 | 0 - 10 | |
Antenna | 0 - 20 | 0 - 200 | |
Laser Antenna | 181** | 577** |
(**) The maximum power usage of laser antenna include both beaming and rotating at once. Beaming alone would be 180 for Small and 576 For large.
Other device power usages
Device | Small Ship [kW] | Large Ship [kW] | |
---|---|---|---|
Gravity Generator | N/A | 0 - 567.13*** | |
Spherical Gravity Generator | N/A | 0 - 1600*** | |
Artificial Mass | 25 | 600 | |
Interior Light | N/A | 0.06 | |
Spotlight | 0.200 | 1 | |
Medical Room | N/A | 2 | |
Jump drive | N/A | 32 000**** | |
Door | N/A | 0.031 | |
Sliding Door | N/A | 0.01 - 1 | |
Gyroscope | 0.001 | 0.03 | |
Ore Detector | 2 | 2 | |
LCD Panel | 0.1 | 0.1 | |
Wide LCD Panel | 0.2 | 0.2 | |
Text Panel | 0.02 | 0.06 | |
Button Panel | 0.1 | 0.1 | |
Rotor | 0.2 | 2 | |
Advanced Rotor | 0.2 | 2 | |
Piston Base | 0.2 | 2 | |
Collector | 2 | 2 | |
Connector | 0.05 | 5 | |
Camera | 0.03 | 0.03 | |
Sensor | 0 - 30 | 0 - 30 | |
Remote Control | 10 | 10 | |
Programmable Block | 0.5 | 0.5 | |
Sound Block | 0.2 | 0.2 | |
Conveyor | 0.04 | 0.04 | |
Conveyor Sorter | 0.1 | 0.25 | |
Cryo Chamber | N/A | 0.03 | |
Oxygen Tank | 0.001 - 1 | 0.001 - 1 | |
Hydrogen Tank | 0.001 - 1 | 0.001 - 1 |
(***) The power cost of Gravity Generator is directly proportional to the field size and acceleration (absolute value, so 1 g consumes the same as -1 g). (****) Only when charging it's internal battery.