New Mars Forums

tahanson43206 wrote:

For SpaceNut ...

Nice image in https://newmars.com/forums/viewtopic.ph … 86#p236186

Please see if your AI Friend is capable of doing more than just offering hand waving and high level overviews.

We need specific equipment recommendations for Calliban's Dome.

GW Johnson is (currently) thinking about cooling air and removing water by creating an opening from the dome for passage of air to outside radiators. I am worried that precious thermal energy would be lost to the dome interior if that were done.

I think  your illustration of a mechanism inside the dome has the opportunity to avoid loss of thermal energy to Mars.

Please see if your AI friend can recommend specific off-the-shelf products to handle the air inside Calliban's Dome.

Also... please consider going back to Calliban's original sketch of what the floor plan might look like. I think we've allowed ourselves to be distracted by the ideas of tiers of layers of housing.  I know that Calliban introduced that idea, but I don't think we should give up on the Italian Plaza vision that Calliban showed us early on.

If we return to the Italian Plaza vision, then we are creating something that wealthy Martians can inhabit, and working Martians can visit for special occasions.

(th)

When calculating the relationship between LED bulbs, the volume of a space (cubic meters), and the mounting height, you are primarily looking at how much light (lumens) is needed to fill a specific 3D volume effectively. 1. Calculating Volume in Cubic Meters (\(m^{3}\)) To find the volume of your room, multiply the length, width, and height in meters. Formula: \(\text{Volume}(m^{3})=\text{Length}(m)\times \text{Width}(m)\times \text{Height}(m)\).Example: A room that is 5m long, 4m wide, and 3m high has a volume of \(60m^{3}\). 2. Determining Light Requirements (Lumens) Lighting is typically calculated based on floor area (square meters), but for high ceilings, you must adjust for volume or height. Residential standard: Aim for roughly 300–500 lumens per square meter for bright areas like kitchens or offices.Height Adjustment: As the ceiling height increases, you need more lumens because light intensity decreases over distance. For ceilings over 3 meters (approx. 10 feet), it is recommended to increase your total lumen count by 25-30% for every additional meter of height to maintain the same brightness at floor level. 3. LED Wattage vs. Installation Height If you are using high-output LED bulbs (High Bay lights), the mounting height dictates the required wattage to ensure the light reaches the ground effectively: Installation Height Recommended LED WattageIdeal Environment0 – 3 meters (0-9 ft)60W (Standard/Low)Residential, Small Garages4 – 6 meters (13-20 ft)100W – 150WWorkshops, Low-rise Warehouses6 – 8 meters (20-26 ft)200W – 250WManufacturing Halls, Medium Warehouses8 – 12 meters (26-39 ft)300W – 400WLarge Logistics Centers12+ meters (39+ ft)500W+Stadiums, Hangars4. How Many Bulbs Do You Need? Once you have determined the total lumens required for your cubic space, divide that by the output of a single LED bulb. Formula: \(\frac{\text{Total\ Lumens\ Needed}}{\text{Lumens\ per\ Bulb}}=\text{Number\ of\ Bulbs}\).A standard 10W LED bulb typically produces 800–1,000 lumens.

Determining the output of an LED bulb relative to a room's volume (\(m^{3}\)) and height (\(m\)) involves calculating the total lumens required to achieve a specific light intensity (Lux). Core Calculation Formulas Total Lumens (lm): Multiply the room's surface area by the target Lux.\(\text{Lumens}=\text{Area\ }(m^{2})\times \text{Lux}\)Area (\(m^{2}\)): Derived from volume and height.\(\text{Area}=\text{Volume\ }(m^{3})\div \text{Height\ }(m)\)Target Lux Levels: Standard guidelines suggest:Ambient (Living areas): 100–300 Lux.Task (Kitchens/Offices): 300–500 Lux.Bright (Bathrooms/Workspaces): 700–800 Lux. BBCode Output for Forums/Calculators The following BBCode block presents these calculations in a structured format suitable for message boards: bbcode[center][size=4]LED Lighting Output Requirements[/size][/center]

• Room Volume: {Volume} m³

• Ceiling Height: {Height} m

• Target Intensity: 300 Lux (Standard Task Lighting)

[hr]

Step 1: Calculate Floor Area
[indent]Area = Volume / Height[/indent]
[indent]{Volume} m³ / {Height} m = {Area} m²[/indent]

Step 2: Total Lumens Required
[indent]Lumens = Area × Lux[/indent]
[indent]{Area} m² × 300 Lux = {Total_Lumens} lm[/indent]

Step 3: Recommended Bulb Count (Based on 800lm LED)
[indent]Bulbs = Total Lumens / 800[/indent]
[indent]{Total_Lumens} / 800 = {Bulb_Count} Bulbs[/indent]

Note: Higher ceilings (above 3m) may require 20-50% more lumens to account for light scattering before reaching the floor.

Height Adjustment Considerations Light Scattering: For every meter increase in height above standard levels (approx. 2.4m), light intensity drops. High ceilings may require additional lumens to ensure effective illumination at ground level.Mounting Height: A general rule for high-bay lighting is that a light mounted at 15 feet (4.5m) can effectively brighten about 12 feet (3.6m) of space.Logarithmic Scaling: Some advanced calculations use logarithmic formulas for "ceiling height adjustment" because the increase in required lumens is not linear as height grows

The diameters of each of the 26 floors in the parabolic dome range from 200.00 meters at the base to 39.22 meters at the top floor, as detailed below. Step 1: Define the parabolic equation and floor heights The dome is modeled as a paraboloid of revolution. With the base at \(y=0\) m and the vertex at the top, \(y=120\) m, the equation of the parabola can be defined as \(x^{2}=4p(y-120)\). The base radius is \(100\) m (half of the \(200\) m diameter), so we solve for \(4p\): \(100^{2}=4p(0-120)\)\(10000=-120(4p)\)\(4p=-\frac{10000}{120}=-\frac{250}{3}\)The equation is \(x^{2}=-\frac{250}{3}(y-120)\). The floor heights are evenly spaced by a distance of \(120\text{\ m}/26\approx 4.62\) m. Step 2: Calculate each floor's diameter The radius \(r\) at any given height \(y\) is \(x\), so \(r^{2}=-\frac{250}{3}(y-120)\), and the diameter \(D=2r=2\sqrt{-\frac{250}{3}(y-120)}\). The following table lists the height and
corresponding diameter for each floor: Floor Number Height (m)Diameter

To determine the diameter of each floor in a parabolic dome that is 120 meters tall with a 200-meter base diameter, we use the standard parabolic equation for a cross-section. Geometric Parameters Total Height (\(H\)): 120 mBase Diameter (\(D\)): 200 m (Base Radius \(R=100\) m)Number of Floors: 26Average Floor Height: ~4.615 m (assuming uniform distribution: \(120\text{\ m}/26\) floors) Parabolic Equation The radius \(r\) at any given height \(h\) from the ground for a downward-opening parabola is given by the formula:\(r=R\sqrt{1-\frac{h}{H}}\)The diameter at that height is simply \(2r\). 

Floor Diameter Table (BBCode) 

[table][tr][th]Floor[/th][th]Height (m)[/th][th]Diameter (m)[/th][/tr][tr][td]Ground (1)[/td][td]0.00[/td][td]200.00[/td][/tr][tr][td]2[/td][td]4.62[/td][td]196.11[/td][/tr][tr][td]3[/td][td]9.23[/td][td]192.15[/td][/tr][tr][td]4[/td][td]13.85[/td][td]188.10[/td][/tr][tr][td]5[/td][td]18.46[/td][td]183.95[/td][/tr][tr][td]6[/td][td]23.08[/td][td]179.70[/td][/tr][tr][td]7[/td][td]27.69[/td][td]175.34[/td][/tr][tr][td]8[/td][td]32.31[/td][td]170.86[/td][/tr][tr][td]9[/td][td]36.92[/td][td]166.25[/td][/tr][tr][td]10[/td][td]41.54[/td][td]161.49[/td][/tr][tr][td]11[/td][td]46.15[/td][td]156.59[/td][/tr][tr][td]12[/td][td]50.77[/td][td]151.53[/td][/tr][tr][td]13[/td][td]55.38[/td][td]146.28[/td][/tr][tr][td]14[/td][td]60.00[/td][td]141.42[/td][/tr][tr][td]15[/td][td]64.62[/td][td]135.53[/td][/tr][tr][td]16[/td][td]69.23[/td][td]130.05[/td][/tr][tr][td]17[/td][td]73.85[/td][td]124.30[/td][/tr][tr][td]18[/td][td]78.46[/td][td]118.25[/td][/tr][tr][td]19[/td][td]83.08[/td][td]111.87[/td][/tr][tr][td]20[/td][td]87.69[/td][td]105.11[/td][/tr][tr][td]21[/td][td]92.31[/td][td]97.90[/td][/tr][tr][td]22[/td][td]96.92[/td][td]90.14[/td][/tr][tr][td]23[/td][td]101.54[/td][td]81.69[/td][/tr][tr][td]24[/td][td]106.15[/td][td]72.28[/td][/tr][tr][td]25[/td][td]110.77[/td][td]61.42[/td][/tr][tr][td]26[/td][td]115.38[/td][td]48.35[/td][/tr][/table]

 Usage Notes Floor 1 starts at ground level (0m height), representing the maximum 200m base.Floor Heights assume a standard vertical spacing of approximately 4.62 meters per floor, which is within the range for high-ceiling commercial or mixed-use structures.The top floor (26) is located at 115.38m, leaving approximately 4.62m of clearance to the 120m apex

Dehumidification systems remove excess moisture from the air to improve comfort, health, and building integrity by preventing mold, allergens, and structural damage, using methods like refrigeration (cooling coils to condense water) or desiccants (absorbing moisture). These systems range from portable units for basements to whole-house integrated systems or large industrial setups, often connecting to HVAC or operating independently for precise humidity control (aiming for 40-60% RH).
Types of Systems
Refrigerant Dehumidifiers: Use a chilled coil to cool air below its dew point, condensing water into a collection pan or drain, similar to an air conditioner but focused on moisture removal.
Desiccant Dehumidifiers: Employ moisture-absorbing materials (desiccants) to pull water from the air, offering precise control in varied temperatures, ideal for industrial or low-humidity needs.
Whole-House Systems: Integrated with your HVAC, these handle humidity for the entire home, often using a dedicated dehumidifier to reduce the AC's load.
Portable Units: Standalone devices for specific rooms, basements, or crawl spaces.
Ventilation Preconditioning: Systems that dehumidify incoming outdoor air before it enters the building, reducing load on main systems.
Key Benefits
Health: Reduces mold, mildew, dust mites, and allergens, improving respiratory health.
Comfort: Eliminates that "sticky" feeling, making indoor air feel cooler.
Property Protection: Prevents warping, rot, musty odors, and pest issues in homes and structures.
HVAC Efficiency: Allows air conditioners to focus on temperature (sensible load) rather than moisture (latent load).
Common Applications
Residential: Basements, crawl spaces, whole homes, especially in tight, energy-efficient houses.
Commercial/Industrial: Warehouses, manufacturing, data centers, hospitals, pools, and ice rinks requiring specific low humidity levels

SpaceX Starship uses 304L stainless steel, typically in large rolls or sheets for construction, with specific thicknesses around 4 mm (0.156 in), though thinner gauge sheets (like 0.8-1.2mm) are common for various finishes and sizes (e.g., 2000x1000mm, 2500x1250mm) from suppliers. While standard industrial sizes (4'x8', 4'x10') exist, Starship uses large, custom formats for its cylindrical sections, with some reports mentioning rolls over 72 inches wide.
Key Details:
Material: 304L Stainless Steel (low carbon version).
Thickness: Around 4 mm (0.156 inches) for main structure, but thinner for other parts.
Formats: Large sheets or rolls, not small standard sheets.
Standard Sheet Sizes (for general use): 4'x8', 4'x10', 5'x10' (and cut-to-size).
Specific SpaceX Use: Reports mention rolls 1828.8mm (72 inches) wide for building the rocket's body.
So, while standard sizes are common in the industry, Starship uses massive, specific sizes to form its huge cylindrical tanks and body sections.

Hmm. Yes. If only I had a job. Visions of tearing down my garage, building a brand new one. I could give details, but I found this at Amazon. Amazon Canada has free shipping within Canada. Reflective sticker, self-adhesive, 0.1cm thick (1mm), flexable. 50cm x 100cm, CDN$ 12.64 + tax. If the back wall is 18' high x 15' wide, that's 548.64 cm high x 457.2 cm wide, so make the reflective area 550cm x 450cm. That would require 5.5 x 9 rolls = 49.5 rolls. Purchased in whole rolls so 50 rolls. That's $632 + tax. A slightly larger area, but still expensive. And outside garage wall facing the Walipini could get more mirror covering. More money.

(Ps. I dug the URL of the image out of source code for their website. However, clicking on the image takes you to their store, to buy this item. They shouldn't be upset by free advertising.)

::Edit:: Hah! Even better. You suggested Mylar; I did a search and found this. One roll would do, CDN$ 49.99 + tax. Free shipping within Canada. Intended to reflect light for agriculture.
Growneer 4 x 100FT 2 Mil Horticulture Mylar Reflective Film Roll Highly Reflective Covering Sheets For Greenhouse Increasing Temperature Light
https://images-na.ssl-images-amazon.com/images/I/51+gzsvG8DL._AA160_.jpg

After milling to reduce its particle size, JSC Mars-1A can geopolymerize in alkaline solutions forming a solid material. Tests show that the maximum compressive and flexural strength of the 'martian' geopolymer is comparable to that of common clay bricks.

To build with Mars regolith, milling equipment (like vibratory/planetary ball mills) reduces particle size, while separation methods use techniques like laser sintering, cold sintering (CSP), polymer binders, or microwave systems to bind or melt regolith into structures, often requiring 3D printers for shaping, aiming for materials like bricks, shielding, or metal parts from extracted elements like iron/titanium. Key processes involve size reduction (milling) and consolidation (sintering/binding) to create usable materials like "Mars concrete" or fused components, with focus on robotic, energy-efficient systems.
Milling Equipment & Processes
Ball Milling (Planetary/Vibratory): Used to reduce particle size (PSD) of raw regolith simulant, with planetary mills being faster but roller banks better for large slurries.
Sieving: Separates milled particles into specific size ranges (e.g., 60-mesh).
Separation & Consolidation Technologies
Laser Sintering: Uses high-power lasers to melt and fuse regolith into solid layers, creating paving or structural elements.
Cold Sintering (CSP): Binds regolith with water/alkaline solutions at low temperatures (under 250°C) and pressure, forming strong bricks or blocks.
Polymer Binders: Mixes regolith with polymers (made from Martian CO2/water) for 3D printing concrete-like materials.
Microwave/Solar Sintering: Alternative methods to use focused energy for hardening regolith.
Metal Extraction: Processes like carbonyl metallurgy or vapor deposition extract iron and other metals for 3D printing steel parts.
Additive Manufacturing & End Products
3D Printing (Extrusion/Powder Bed): Deposits processed regolith/binders layer-by-layer, building structures like domes, habitats, tools, or rebar.
Products: Sintered bricks, concrete-like blocks, radiation shielding, metal components (rebar, gears, tools), and coatings.
Key Considerations
In-Situ Resource Utilization (ISRU): The core principle, maximizing use of Martian soil.
Energy Efficiency: Focus on low-energy methods like cold sintering.
Robotics: Automation is crucial for mining, milling, and construction