Solars

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The Gift of the Sun

Solars are often overlooked by newer chief engineers, but are a very good place to start your engineering career. They are the safest way to generate power for the whole station and require minimal experience to set up. In the event of the loss of the primary engine or some other catastrophic reason, the solars are sufficient to power the entire station, if set up correctly.

Locations

There are four solar arrays on each station operated by Nanotrasen. On all stations, the solar arrays are generally on each corner of the station, but are not exactly the same.

The NSS Cyberiad The four solar arrays on the Cyberiad are all connected to the station via maints shafts. The fore port (northwest) solars are located just north of the arrivals shuttle in maints. The fore starboard (northeast) solars are located in maints north of the chapel and east of security. The aft starboard (southeast) solars are located at the far corner of the station in science maints. The aft port (southwest) solars are located just west of engineering.

The NSS Kerberos


The NSS Cerebron

Setting up the Arrays

You'll need:

  • CableCoils.png Approximately 3 cable coils per solar array.
  • Engineer Hardsuit.png An exosuit that permits spacewalks as well as internals.

None of the four solar arrays are connected to the station at the start. You will need to connect the solar panels and the solar tracker to the wire leading from the station. To wire a tile, hold a cable coil in hand and click an adjacent tile. This will add a wire radiating from the center of the selected tile toward your current position. You will see a tiny red knot or "node" in the center of the tile. When extending the wire across the tile, make sure to click the knot in order to form a straight wire.

One of the station's solar arrays

Using this method, connect the solar arrays and solar tracker to the station. Wires with nodes are tricky and sometimes appear to be connected, but do not send power. Ensure that the visible wires in the image do not have any nodes on them.

NOTE: If you are wiring a solar array from scratch, ensure that there is a node underneath each solar array, as well as the solar tracker.

Calibrating the Arrays

Once the solars are all wired, it's time to link them to the system and get them searching for sunshine. The station is rotating in orbit, which means that the solar panels need to constantly rotate to face toward the sun in order to reach maximum efficiency. To make sure they are doing so, go back through the airlock and go to the computer inside of the solars egress. At the top right corner of the screen, there should be a button to search for equipment. This will make the computer check to see which solar arrays are properly wired to the system and check if the solar tracker is wired. (It's also worth mentioning that the computer itself needs to be on one of the nodes to work.) If the solar arrays are properly wired, the computer should indicate 60 connected panels. If there are not 60 panels connected on the computer, double check your wiring. After you have ensured panels are connected, there should be a section in the lower left to set the tracking protocols. Set the tracking on the computer to "auto." If you cannot set it to auto, check your wiring again. You may have forgotten to connect the solar tracker. While manual tracking is an option, the only time you will ever need to manually calibrate a solar array is when something destroys the tracking unit.

Reminder

  • 0 degrees = North
  • 90 degrees = East
  • 180 degrees = South
  • 270 degrees = West

When all the panels of an array face the sun (and are correctly wired) they produce about 90,000 watts of power. It is important to note that THE STATION BLOCKS SUNLIGHT! This means that as the panels rotate with auto-tracking, they move through a series of power levels ranging from 90k (full sun) to nothing (station obscures sun). The rotation cycle takes roughly 5 minutes to complete.

Why is this important?

Because of the SMES! See that big white thing in the solar control room? That's the SMES.png SMES cell. It's essentially a battery used for holding solar energy and transferring it to the station. Also acts as a sort of capacitor to protect the station from solar flares.

Setting Up the SMES Units

A common mistake is to immediately set the input to 90,000 watts (the amount produced by full sunlight) and the output to 80,000 watts. However, this will not work. The SMES cells start at 20% power, but if the engine is off or the station is not supplied with any other kind of power, the station drains them to 0% in a few minutes. An input of 90,000 watts (full sun) might charge the battery for a little while, but once the sunlight is blocked by the station the battery charge begins to drain. This causes the battery to turn off. even when the panels receive sunlight again, the battery won't be sending power unless an engineer turns it on again.

After you have wired the array, set tracking to auto, and verified that the panels are indeed rotating, set the battery like so:

Charging: Auto

Input: 80,000 watts

Output: OFF!

You want to leave output off and let the battery charge before you send the power to the station. Try waiting for a charge of at least 10% (maybe more) before you turn on the output. The battery needs this charge to provide sustained power during the dark phase of the solar rotation. If the battery runs out of charge, you'll have to turn it on again or it will not provide power. While you wait for the battery to charge, you can wire up other solar arrays on the station.

Alternatively, you don't have to set the output on at all. If the engine is up and running, you can leave the solar SMES charging just in you need it later.

When you need it, you can set the output to 50,000 - 75,000 depending on how much power you need. If the output load is equal to the output value you set, it means the station needs more power than it's getting. Crank it up!

These four arms can provide enough energy to power the entire ship in the event of an engine failure. But, given the position to the engine, the wires will likely be eaten away and you will have charging solars that aren't connected to the station.

Hotwired Solars

A far more efficient way to configure the solars is to leave out the SMES cell entirely. This is done by cutting and rewiring the cables in the control room of each of the four solar arrays so that they don't connect to the SMES cell or its terminal, and instead feed directly into the station's power grid.

The practical upshot of this is that the solar arrays will supply the station with power constantly, whereas if they were connected to an SMES cell, power generated at any level lower than the set input would be lost. Setting the SMES cell to a lower input level would harvest this lower energy, but it would cause the cell to waste energy generated at peak times instead.

Wiring the solars directly into the grid removes these problems and hence generates far more power! Of course, the downside of this is that it's impossible to store energy without an SMES cell, so if something goes wrong with the arrays, the power will go out immediately. Solar flares may also sporadically occur.

During a solar flare, the solars produce exponentially more energy. Why is this a bad thing? Well, if the solars are hotwired, all of that power will go directly into the grid and cause APCs to start arcing and shocking people.

Danger

There are a few dangers on the solars, one being the electrical wires! They can shock anyone manipulating or tampering with them, so wear insulated gloves at all times. Never forget or you will get zapped!

In addition, you are vulnerable and alone. This leaves you an easy target for space-walking attackers that need a new cover identity or you could be attacked by a Space Carp. Finally, there is the chance to slip and go drifting off through space. This hazard is easily solved if you act quickly. Simply throw something in the direction of your flight path, like shoes, or a pen. The equal and opposite reaction will start pushing you in the other direction!