Ship Design Philosophy

Spacecraft: Engineering, Manoeuvre Drive, and Pulsing

A. This is inefficient, but you could have a duplicate of the propulsion drive.

B. When we still had actual high burner thrusters, I thought of having two, and alternating one every hour.

C. Ten rounds every hour works out a lot better than one round every one to six hours.

D. In theory, you have to allocate the difference in power between the old and the new acceleration factor.

E. As far as I can tell from the Core rulebook, this is not addressed.

F. However, subsequent supplement indicates that this is required.
 
Spacecraft: Engineering, Manoeuvre Drive, and Pulsing

G. Can, in the current edition, alternate pulsing be leveraged?

H. It would have to cheaper, whether capital outlay, or operating costs.

I. A successful Difficult (10+) Engineer (m-drive) check (1 round, INT) will increase the ship’s Thrust by +1 during the next round.

J. So spacecraft factor/zero is half a percent, compared to factor/one one percent.

K. But spacestation factor/zero is a quarter percent.
 
Spacecraft: Engineering, Manoeuvre Drive, and Pulsing

L. Manoeuvre drive with Thrust 0 consumes tonnage equal to 0.25% of the space station’s total hull and costs MCr1 per ton.

M. Which is half the cost of default spacecraft.

N. Required power = 10% of hull tonnage.

O. In order to use the manoeuvre drive, the ship requires an amount of Power equal to 10% of the hull’s total tonnage multiplied by the maximum Thrust the drive is capable of (multiply by 0.25 if the ship is capable only of Thrust 0).

P. Power is cheap.
 
Spacecraft: Engineering, Manoeuvre Drive, and Pulsing

Q. Customization can reduce capital outlay, or lower operating costs.

R. Volume per se, at this end, doesn't matter.

S. 0.3125 percent of volume at three fifths megastarbux per tonne.

T. Or, energy inefficiency thirteen percent of hull volume, three quarters megastarbux per tonne.

U. Or, in the other direction, two and a half percent of hull volume energy efficiency, one and a half megastarbux per tonne.
 
Spacecraft: Engineering, Manoeuvre Drive, and Pulsing

Q. Primitive hulls cannot have jump and manoeuvre drives installed.

R. Plasma drives can be installed.

S. They have a power requirement of one power point per tonne, compared to ten for manoeuvre drives.

T. Budget variant can be energy inefficient to one point three power points per tonne.

U. Fifty percent energy efficiency at two and a half power points, would be one point two five; seventy five percent would five eighths of a power point.
 
The standard acceleration due to gravity on Earth is approximately 9.8 meters per second squared (9.8 m/s²). This means that for every second an object falls freely, its downward velocity increases by 9.8 meters per second. Over a period of six minutes, the change in velocity would be significant due to this constant acceleration.

To calculate the change in velocity over six minutes, we first need to convert the time to seconds:
6 minutes * 60 seconds/minute = 360 seconds

Then, we can calculate the change in velocity using the formula:
Δv = a * t

where:
Δv is the change in velocity
a is the acceleration (9.8 m/s²)
t is the time (360 seconds)

Therefore:
Δv = 9.8 m/s² * 360 s = 3528 m/s

So, the change in velocity of an object in free fall after six minutes would be
3528 meters per second.


12'700.8
klix per hour.


The average lunar distance is approximately 385,000 km (239,000 mi), or 1.3 light-seconds.[1]


30.31305114638448 hours

Average maintenance cycle thirty five rounds, or three and a half hours.

Second cycle, 25'401.6 klix per hour.

In theory, you have to drift longer, then turnover for deceleration, twice.

So, maybe sixteen, seventeen hours from Terra orbit to the Moon if pulsing on a manoeuvre drive factor/zero.
what do you mean by pulsing? Is there a source or citation?
 
Puls1Motor_en.gif


Basically, turning the manoeuvre drive off and on, continuously.

You could do that with the reactionary rockets, but I haven't come across anything that would leverage that in a worthwhile way.

Originally, conceived as a way to use solar panelling to energize the manoeuvre drive, but the update, and one supplement, has revised that concept.

Now, spacestation surfing.
 
Spacecraft: Engineering, Manoeuvre Drive, and Pulsing

V. Primitive planetoid hulls retain their hull points, so the primary difference between that and default, appears to be, besides lack of gravity tiling, the power grid.

W. Manoeuvre drives default to ten power points per tonne.

X. Jump drives four power points per (core) tonne.

Y. Plasma drives one power point per tonne.

Z. So we know that primitive hull power grids can handle, for engineering, at least one power point per drive local tonne.
 
Spacecraft: Engineering, Manoeuvre Drive, and Pulsing

1. Locally, weapon systems, specifically bays and spinal mounts, don't exceed one power point per tonne.

2. Concentration of energy seems in one tonne turrets.

3. Maximum seems fifty power points for a one tonne quadruple fusion gun turret.

4. Perhaps, rather than calculating power per local tonne, for weapon systems we have stressed energy nexus that can handle a specific amount of power points.

5. Default basic systems power requirement is one power point per five tonnes.

6. You can half that to one power point per ten tonnes, and still retain an artificial gravity field.

7. A primitive hull has one power point per hundred tonnes, and no gravity tiling.

8. However, boiling or freezing zones quadruple basic power requirements to one power point per twenty five tonnes.

9. Thus, I'd say the reason that you can't install manoeuvre drives or jump drives on primitive hulls, is because their power grids can't handle their energy requirements.
 
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Spacecraft: Engineering, Manoeuvre Drive, and Pulsing

A. Which allows us to move on to the acceleration cap.

B. Presumably, because of the weakened structural integrity, via halved hull points.

C. Though, the primitive planetoid hull isn't affected by that, so clear discrepancy.

D. Still the cap is there, Make Acceleration Grate Again.

E. The primitive hull would have to be attached to a propulsion default hull, that has a robust power grid.

F. Though, if insulation issues does allow sustained basic power requirements to one in twenty five tonnes, it should allow a customized energy efficient manoeuvre drive that is within that power cap.
 
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