C/M Drop-Station Energy
C/M Drop-Station Energy
GONDOLA ENERGY BY C/M
3-4 year break even to profit installation
US $10 BILLION INITIAL INVESTMENT
CIG is proposing property purchase for use of top-bottom & channels for this purpose at over 100 sites internationally for 2026-2029 meeting 2030-2035 goals for 2050 onward
Stationary Energy
https://cmbennettbrothers.blogspot.com/2025/08/cm-stationary-shipping-container.html
GENERATOR
A simple Energy Generator: C/M Stationary Energy Plant
Drops item
Lifts back up to drop using less Energy
Drops item
Excess for use or storage
SIMPLE ADVANCED MECHANICAL ENGINEERING
Perpetual break even Energy. This allows the excess as CIG with Dr Sydney Nicola Bennett achieved 1980's-2025 & onward
DROPPING YIELDS. SIMPLE
This is one of many Stationary Plants
Larger weights + Lifts up. Larger yields
A mountainside contained effort creates a perpetual generator
USING H.I.3 TO ACHIEVE
100-500 kWh hourly consumption (Gondola operation) then 525-1000+ kWh Energy Generation creating excessive
600 kWh in 24 hours at 25. With additive Yields we are at 24,000 or higher on perpetual gains for Zero Emissions
219,000 - 8,760,000 kWh in 365 days fluctuating variables with maintenance downtime on kWh generation
Small efficient gondola compact system with space for people & tools on people maintenance cart
A 5000 ft long cable one way offers 400 gondolas for ever 25 feet which allows 398 drop blocks & two maintenance gondolas
The Gonola system effect then drop channel works maximizing weight we can lift up while minimizing Energy to do so with or without passengers in maintenance & monitor
As drop bars filter down & break then load onto gondolas that lift then up to drop again
The Energy yields are massive. Multiple drop bars are dropped in separated sequence
Specific yield items are "stroked" when drop bars filter through
This is separate from Air-Pressure - Air-Compression
650 lbs Drop blocks on each gondola then allowance for an empty gondola for maintenance between allowing a maximum of 700 lbs while Energy for the Gondola is less than drop blocks generate
SIMPLE DROP TUBE SYSTEM
Simple round tube with items the drop block hits on the way down then air braking or magic braking so it's low cost to install then maintain
Can be pained beige or other to match the natural landscape
Zero Emissions low cost Energy generators
Open source (partially) & low cost licences from C/M for patents & copyright + trademark
COST - PRICE ROYALTY
C/M licence fee. CIG & S.B.G split royalty on drops (each drop) based on Energy generated & rates allowing a 25/75% yield after generation from use to accomplish which then provides tax revenue (tax cash cow) then R&D fee royalty for CIG & S.B.G & gondola owners cut
Zero Emissions & excess competition effective lowering overall domestic rates in fair tiers
On a 5000 foot line 14-15 minutes & 199 drop blocks drop. If that's $1.00 per drop in royalties & tax division from $3.00 & in 24 hours then numbed begin adding up against rates to grid & alternative efforts for Energy
The returns are variable yet much higher than $1.00 per drop
96 X 199 = 19,104 drops in 24 hours (5000 foot line)
6,972,960 in 365 days
TRADITIONAL GONDOLAS
The weight a gondola can handle depends on the type: a Venetian gondola typically holds about five to six people, while a ski gondola cabin can hold around 4 people with a maximum weight of 700 lbs, and a retail gondola shelving unit can hold hundreds of pounds. Venetian gondoliers handle weight based on visual assessment and balance, while specific gondola systems have designated weight limits for safety.
Venetian gondolas
People: Typically hold up to five to six people, including children.
Weight management: Gondoliers assess weight by sight and help people get in and out of the boat, adjusting seating for balance without discussing weight.
No official weight limit: There is no strict, publicly enforced weight limit per person, but the gondolier can adjust seating to ensure stability.
Ski lift gondolas
Capacity:
A specific gondola cabin may hold up to 4 people with a maximum weight of 700 lbs.
Variable capacity:
For example, a Disney Skyliner gondola can hold up to 10 passengers, but this capacity is reduced to 6 if a wheelchair or mobility device is present.
Gondola shelving
Retail units: These can hold hundreds of pounds per shelf.
Example: A Lozier gondola shelf can hold up to 500 lbs, and they can be specially ordered to hold even more weight.
Adjustable capacity: The weight capacity varies depending on the design and reinforcement of the shelves.
GONDOLA ELECTRICITY USE
Gondolas use electricity from the grid, which can be powered by renewable sources like solar or wind. Some systems also use a combination of on-board batteries and capacitors to store energy, often charged by the system itself as the gondola enters and exits stations, according to FlemXpress, Wikipedia, and this YouTube video.
Power sources
Electricity from the grid:
The primary power for the continuous loop of the cable is often an electric motor at the terminal station.
Renewable energy:
Gondolas can be connected to renewable energy sources, with some systems powered entirely by local solar or wind energy.
On-board energy storage:
Batteries and capacitors: Some gondolas have on-board batteries and capacitors to provide power for functions like lighting and climate control.
Charging: These onboard systems are recharged as the gondola passes through the stations.
Kinetic energy recovery: A system may convert kinetic energy from deceleration into electrical energy to charge the capacitors as the gondola slows down to enter a station.
Applications and examples
Urban transportation:
The use of renewable electricity makes them an environmentally friendly urban transit option.
Mountain resorts:
Ski lifts and gondolas at resorts can be powered by electricity, with some systems using solar power to offset their energy consumption.
Funfairs:
Even amusement rides with gondola-like systems use electricity from the grid to power their moving parts.
TOTAL ENERGY USE
The energy a gondola uses varies significantly depending on whether it is an aerial lift or a Venetian canal boat. A powered gondola lift uses large electric motors, with energy consumption ranging from upwards of 100 kWh per hour to hundreds of kilowatts, while a traditional Venetian gondola relies on a human gondolier.
Aerial gondola lift energy consumption
The power usage of a motorized gondola lift is determined by factors like its size, speed, terrain, and passenger load.
Power usage per hour (kW/h)
A larger, heavy-duty gondola can consume over 100 kWh per hour.
For a specific, large tri-cable lift in Austria, the total power consumption was 400 kW.
Annual energy consumption (kWh)
A gondola lift in a Colorado ski town reportedly uses about 2 million kWh per year.
Another mountain cable car in St. Gilgen, Austria, consumed 629,100 kWh in 2023, with a solar installation now covering most of its needs.
Factors affecting energy usage
Capacity and weight: Larger and heavier gondolas and cabins require more energy to lift uphill.
Terrain: Lifts on steeper inclines or operating in harsh conditions like heavy snow require more energy.
Operation speed: Many modern systems can operate at reduced speeds during low-traffic periods to save power.
System type: Advanced technology like regenerative braking can recover energy as gondolas descend.
Venetian gondola energy consumption
In contrast to the modern aerial lift, a Venetian gondola uses human power and is a model of efficiency for its purpose.
Propulsion: The boat is propelled by a single person, a gondolier, using an oar in a sculling motion.
Energy cost: A study found that the absolute energy needed to propel a Venetian gondola at low speeds (around 1 m/s) is similar to the energy a 70 kg person uses for walking.
Design for efficiency: The boat's unique asymmetrical shape makes it highly efficient for single-oar propulsion, minimizing the energy required to maneuver it through the canals.
GONDOLA TOWER SPACING
Gondola tower spacing varies greatly depending on the technology, terrain, and capacity, with standard urban systems having shorter spans of 80–90 meters, while advanced systems can span over 1 kilometer, such as the Peak to Peak Gondola with a longest unsupported span of nearly 2 miles (about 3.2 kilometers). Some systems can achieve longer spans with modern technology like 3S (tricable) systems that use two track ropes and one haul rope for stability.
Spacing by system type
Urban systems:
Shorter spans are typical in urban environments, with one example using tower spacing of 80–90 meters.
Standard ski lifts:
While some may be shorter, spans can reach up to 1,000 meters (1 kilometer) in certain conditions.
Advanced and high-capacity lifts:
Systems designed for long, difficult spans, such as those with challenging access or high passenger capacity, often use multi-cable (2S or 3S) technology.
The Peak to Peak Gondola has a longest span of approximately 3,200 meters (nearly 2 miles).
The 3S Bahn in Kitzbühel, Austria, has an unsupported span of 2,507 meters.
Factors affecting tower spacing
Technology:
3S (tricable) and 2S (bicable) systems are designed for longer, more stable spans than traditional systems.
Terrain:
The type of terrain (e.g., mountainous, flat, valley) and potential obstructions heavily influence where towers can be placed.
Capacity and speed:
Systems designed for high passenger volumes can achieve greater speeds and longer spans.
Cost:
The cost of construction, which can be millions of dollars per kilometer, also impacts the feasibility of long spans.
BREAK EVEN REPLACING FOSSIL FUELS
A 5000 foot line would likely run below $25 Million USD (2025) then within X time frame the transition from fossil fuels to allows a break even profit low maintenance cost model
Life cycles are 50 - 75 years or longer before 75-90% replacement with 5 year review on Energy drop tubed
The construction cost for the Whistler Peak to Peak Gondola was $51 million Canadian dollars. It was built between 2007 and 2008 and was the most expensive lift ever built in North America at the time of its completion.
Total Cost: $51 million CAD.Construction Period: 2007 and 2008.Significance: At the time of its completion, it was the most expensive lift ever built in North America.
Natural landscape is not affected
A Michigan Hydro station pushes water up & returns net positive Energy like this
Gravity like the Sun. Renewable energy
Energy Generators to Grid & Storage Emeregency Safety Systems
Drop blocks auto connect for a lift back up then disconnect for the drop
THOUSANDS OF INSTALLATIONS GLOBALLY
Gondola is one approach with accumulative managed renewable safe Energy
Wildfire & Earthquake or Landslides are risks yet cost to repair is low enough to justify
If most countries have a Public Sector - Private Sector effort in Gondola & connected renewable Energy then Fossil Fuels reliance will become absoleet
A large safer mountainside could see a managed 10 - 5000 gondolas designed safe for wildlife installed
Infrastructure installation & maintenance
Energy generation profits & dispersion tiers
FLAT AREA ENERGY HAUL
A Sky-Scaper Attachment
A safe attachment for a gondola separate from Elevator would allow for a flat drop to curve outward down to gondola base yet the gondola tower could be designed with a circular wrap in a rectangular square exo-shell
This allows a vertical elevator gondola experience for sky scrapers using cables different from an elevator or a hybrid vertices curve horizontal hybrid allowing a traditional gondola lift option with wind considered then the drop area
C/M Elevator Drop designs are a separate effort as these are externals clipped on
Braking uses air pressure in phases as dropped bars slide through generators slowly generating more speed before a high energy brake then captures to lift them back up for another rub
Increase gondola size & cable size then tower weight capacity to 2500 from 650 & yields increase
Sliding causes friction so we apply low degradation wheel systems & effects to slow down the drop blocks
Plastics on plastics pvc & safe covers work then exo-shell energy generation extractors to grid or storage dispersion
JORDAN R BENNETT IS NOT NIC
The NB-OT Labs even on October 23, 2025 still cannot tell their own ass from a hole in the ground
If they say or think hey. Jump off a cliff. They do it. Monkey see & monkey do. All in & everyone's died
Now they think the brains - bodies of Jordan R Bennett & Dr Sydney Nicola Bennett "Nic" are one person & their separate professional & private lives social circles & interests or activities are one & childhood then teenage years up to age 25 or under & over merge
Few of the same shared social circles then those connected to closet or distant family & others then separate experiences & memory in life
AH SO UM
Is it dumber than a door nail people? Look at me. Like. Factual action consciously chosen leads to
Ah. Stupid
We had this way growing up 1980's - 1998. Our immediate families style & identity in which I carry forward for the female & male effect in my own DNA family as tradition separate from other areas of closet or distant family
Holidays. A style of vocabulary & phrases for backend private versus public life or professional
Measurements even & the whole NB-OT Labs slant eyed cocktail eyed cont hair & a whore whore sucka tity bit
A harmless vocal stop. Recharge debate & go back at it with a why & because intervention like check & balance for safe point A-B
A little stop work clause up in here then green light from red. Offline because oh my
Stop full production or area of & continue then pace back to overall final time output & buffer for allowance of such temporary shut downs
In 8 hours 2x 15 minute breaks then 30-60 minute lunch + 8 hour pay or salary equvilance not 7 & unforseen shut down buffer time created with Emergency Safety System & Plan
Kiss ass is not a stay back candy ass cheat liar not sabateur. Seductrice
TAXATION STRATEGIES
Corporate Tiers
Profit per quarter
Propety taxes- Sq Ft VS use & profit tiers per quarter for owner or owner & leasee
Taxing just on Sq Ft voids a reality aspect of what the space is used for & reality in output then ability to pay a ratio of profit to tax which can fluctuate
This is one if other strategic efforts for Business Sustainability Public Sector Government has to look at with a Foundational Private Sector bail out system Public Sector does not offer but Policies allow for
Offshore comes with fees to import back creating equal to domestic in reciprocal effects
A preservation contract - expand & preserve effect
S.B.G & CIG
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