Footage of Redback infantry fighting vehicle undergoing tests of its active suspension system in South Korea in late 2019. Hanwha is bidding the Redback into the Australian Army's Land 400 Phase 3 program.
Video: Hanwha
FNSS PARS 8x8 Tıbbi Tahliye Aracı, PARS araç ailesinin tıbbi tahliye varyantı olarak iki ülkede envanterinde hizmet vermektedir. PARS Tıbbi Tahliye Aracı, yaralı askerleri düşük ve/veya yüksek yoğunluklu muharebe alanlarında ilk yardım, tahliye ve tıbbi bakım sağlamak amacıyla tasarlanmıştır.
FNSS PARS 8x8 Armored Medical Evacuation (AME) vehicle is the medical evacuation variant of PARS FoV’s which is currently in service with two countries. The PARS AME is designed to collect, evacuate and transport wounded troops, with basic first aid and medical care in low and high intensity battle fields.
Landing Craft Utility (LCU) Well Deck Ops – Amphibious Assault Ship USS Bonhomme Richard
Landing Craft Utility (LCU) 1666, assigned to Naval Beach Unit (NBU) 7, enters the well deck of the amphibious assault ship USS Bonhomme Richard (LHD 6).
The LCU is a type of boat used by amphibious forces to transport equipment and troops to the shore. They are capable of transporting tracked or wheeled vehicles and troops from amphibious assault ships to beachheads or piers. (https://en.wikipedia.org/wiki/Landing_Craft_Utility)
USS Bonhomme Richard, flagship of the Bonhomme Richard Expeditionary Strike Group (ESG), is operating in the Indo-Asia-Pacific region to enhance partnerships and be a ready-response force for any type of contingency.
Factual, impartial and current. AiirSource Military brings you the latest insights from the United States Armed Forces.
Visit our channel for in-depth and extended coverage on military events and missions: www.youtube.com/AiirSource
Subscribe and turn on the notification bell to stay updated: www.youtube.com/subscription_center?add_user=AiirSource
Help us translate this video's title & description into more languages: www.youtube.com/timedtext_cs_panel?c=UCd4W_0_E64eeP-o1ZOqVN2A&tab=2
Credits: Diana Quinlan, William Sykes | AiirSource Military
UHAC ship to shore and USS Rushmore b-roll during RIMPAC 2014
The 1/2-scale Ultra Heavy-Lift Amphibious Connector makes its way July 11, 2014 from Marine Corps Training Area Bellows to the USS Rushmore during the Marine Corps Warfighting Laboratory's Advanced Warfighting Experiment (AWE) in Hawaii. This is the first time the UHAC enters the well-deck of a US Navy ship. After taking on the Growler ITV, the UHAC departs the Rushmore and returns to MCTAB. The Lab conducted the AWE during Rim of the Pacific Exercise 2014, to test potential future technologies, solutions and concepts to future Marine Air Ground Task Force (MAGTF) challenges. www.dvidshub.net/video/354333/uhac-ship-shore-and-uss-rushmore-b-roll-during-rimpac-2014
In this video we’ll talk about 7 Real Flying Cars That Actually Fly.
Subscribe Here: bit.ly/2uU9E0w
______________________________________
Details:
7) EHang 184: www.ehang.com/fr/ehang184/
EHang is a Chinese drone manufacturing company and it has designed and developed the world’s first electric-powered autonomous aerial vehicle named 184. It is a low-altitude drone that can carry a single passenger for 23 minutes of flight at sea level.
6) Lilium Jet: lilium.com/the-jet
Lilium Jet's iconic design and pioneering technology bring the vision of fully-electric transition flight to reality. It’s the new mobility service for the modern, urbanized age.
5) Pal-V: www.pal-v.com/en/explore-pal-v
The PAL-V Liberty is a groundbreaking product that inaugurates the age of the flying car. It is a marriage between safety and fun, designed to satisfy the most demanding customers.
4) The Maverick:
The Maverick, a flying car that looks like a buggy with a parachute, was built to make the remotest regions of the world more accessible.
When it's time to fly, Maverick's central telescopic mast raises and acts as a wing spar for its chute, properly known as a ram-air wing.
3) Terrafugia Transition: www.terrafugia.com/
The Terrafugia transition has four wheels, folding wings and a rear-mounted pusher propeller. Powered by a four-cylinder hybrid-electric engine, it can fly 100 miles an hour at altitudes of up to 9,000 feet, with a flying range of 400 miles.
2) AeroMobil 3.0: www.aeromobil.com/
AeroMobil 3.0 prototype was designed and manufactured by engineers led by chief designer and CTO Stefan Klein and CEO Juraj Vaculik, in just 10 months after the release of the previous and much more basic pre-prototype of the flying car, the AeroMobil 2.5.
1) Terrafugia TF-X: terrafugia.com/who-we-are/tf-x/
Known as “the flying car for all of us”, the four-seat TF-X features a plug-in hybrid powertrain which powers both its wheels when on the ground and two electrically driven rotors for flight. It’s capable of vertical take-off and landing, as opposed to needing a runway to become airborne.
_____________________________________________
About My Channel:
Welcome to my channel Inventive tech, In this channel i upload videos about top5s & top 10 tech gadgets 2019. You can buy these gadgets from the company's official websites & some of them are available on amazon & aliexpress. To explore mind blowing smart home gadgets, specs, different gear & advanced artificial intelligence invention. Don't forget to subscribe my channel. Thanks
________________________________________
Our email address for copyright issues: techzdetailsprime@gmail.com.
MUSIC USE IN THIS VIDEO: Dark Tranquility — Anno Domini Beats
________________________________________
Subscribe Here: bit.ly/2uU9E0w
Don't forget to subscribe my channel. Thanks
Yamaha Motor High-performance Electric Motor Prototype(interview with developer)
An electric motor unit developed by Yamaha Motor that achieves the industry-leading high power density for automobiles and other types of vehicles. High output density and efficiency.Leveraging our expertise for a compact and sporty unit. Emotional EV Motors- that's where we're different. global.yamaha-motor.com/business/e-motor/
NASA’s Perseverance Mars Rover Sample Caching System
Watch as NASA-JPL engineers test the Sample Caching System on the Perseverance Mars rover. Described as one of the most complex robotic systems ever built, the Sample and Caching System will collect core samples from the rocky surface of Mars, seal them in tubes and leave them for a future mission to retrieve and bring back to Earth.
The team is on track to launch Perseverance in July 2020 and land in Mars’ Jezero Crater in February 2021. For more information on the Mars 2020 Perseverance mission, please go to: mars.nasa.gov/mars2020/
Credit: NASA-JPL/Caltech
NASA's Mars 2020 Mission | Everything You Need To Know
NASA’s Mars 2020 Mission & Perseverance Rover
This is Mars as viewed on NASA's awesome web-based portal, Mars Trek.
And this point here is the Jezero Crater, where NASA's Mars 2020 Mission will take place.
The launch window for the mission is between July 17th and August 5th of this year and centers around the Perseverance Rover.
The Perseverance is nearly identical to the Curiosity Rover except for redesigned wheels.
Reusing Curiosity’s design makes sense because Curiosity is an engineering marvel and saves NASA a lot of money in development costs.
Aside from the redesigned wheels, Perseverance also has a unique set of instruments needed for the mission.
The Mars 2020 Mission is just a part of NASA's overarching Mars Exploration Program.
The program has four key science Goals, in which the Perseverance will play a significant role in their achievement.
The first goal is to determine whether life ever existed on the planet, and this is why the Jezero Crater was chosen to be the site.
The crater may have contained a large 800-foot lake connected to rivers.
To help achieve this goal, the Perseverance is equipped with three amazing instruments.
— The Planetary Instrument for X-ray Lithochemistry or PIXL.
— The Scanning Habitable Environments with Raman & Luminescence for Organics & Chemicals or SHERLOC.
— And the SuperCam.
PIXL is an X-ray Spectrometer, which allows Perseverance to detect signs of biofilm made by microbes that may have lived on the planet long ago when the climate was warmer.
At just 10 lbs, it is 50 times lighter than the typical lab spectrometer used for the same purpose.
SHERLOC also has a spectrometer, but it uses an ultraviolet laser to determine the chemical makeup of surfaces.
Last but not least is the SuperCam, which examines rocks and soils with a camera, laser, and spectrometers to seek organic compounds.
It can identify the chemical and mineral makeup of targets as small as a pencil point from a distance of more than 7 meters!
The second goal is to characterize the climate of Mars.
The rover will perform astrobiological investigations using the Mars Environmental Dynamics Analyzer or MEDA.
MEDA will continuously measure the characteristics of the Martian atmosphere, including the direction and wind speed, temperature, and humidity, and also measures the amount and size of dust particles.
Dust storms can block out the sun for weeks every seven to 10 years, there are enormous dust storms that cover the entire planet.
And the data collected from MEDA will help predict weather conditions that the first astronauts will face and the eventual colonists.
The third goal is to Characterize the Geology of Mars by studying the rock record.
It will do this using the Radar Imager for Mars' Subsurface Experiment or RIMFAX.
RIMFAX uses radar waves to uncover what lies beneath the Martian surface, capable of detecting ice or salty brines.
Additionally, the rover will use its percussive coring drill to collect rock samples and place them in sealed tubes.
The samples will eventually be placed on the planet's surface and possibly be collected on a future mars mission to be returned to Earth for further study.
Learning the Geology of Mars is foundational knowledge that is important for future colonists.
Lastly, the fourth goal of the Mars 2020 mission is to Prepare for Human Exploration.
The Perseverance has four sub-objectives for this goal, but we are going to zero in on the Mars Oxygen In-Situ Resource Utilization Experiment or MOXIE.
MOXIE is an experiment that aims to demonstrate the ability to produce oxygen from the Martian Atmosphere.
This is critical for two apparent reasons as astronauts and colonists need oxygen to breathe and it can be used as propellant for return trips back to Earth.
The MOXIE takes the Mars atmosphere and heats it up to 800 degrees Celsius, which allows the oxygen to be separated from the Carbon dioxide.
If this experiment is successful, NASA may send a dedicated mission to produce Oxygen on Mars, which would lay the groundwork for human missions and a colony.
So, all the instruments on the Perseverance are astonishing in their own right but to top it off, the rover is equipped with a helicopter.
If successful, the idea is for future Mars rover missions to be outfitted with drones that can scan the surrounding area for interesting objects and places for the rover to explore.
NASA has a long succession of successful Mars rover missions going back 23 years.
Hopefully, the Perseverance continues the succession of successful Mars rovers.
And hopefully, through its discoveries and experiments, it paves the way for the human missions to come.
Что представляет себе человек, услышав слово «скорость»? Суперкары? Ракеты? Самолеты? И этот список был бы неполным без «лодок»… Да, именно лодки! Вода – отличное место, чтобы гнать на огромной скорости без пробок и полиции, и без всяких сложностей вроде взлета и посадки… Вода – это идеальная возможность для каждой лодки и каждого лодочника проявить себя. Особенно, когда речь идет о «самых – самых».