Lumber said:I like the idea of a swarm full of small, semi-expendable drones supporting a contingent of ground forces, providing ISR and medium calibre fire support.
HOWEVER, I can see there being a lot of fear about leaving shot-down drones and all their munitions lying around after a battle.
Unmanned flying drone will deliver up to 3000 pounds of on demand supplies at 300 mph to combat squads sending requests by cellphone
The DARPA Aerial Reconfigurable Embedded System (ARES) is being built by prime contractor Lockheed Martin’s famed Skunk Works with Piasecki Aircraft under a $77 million DARPA contract. Lockheed is providing the software, Piasecki the hardware.
The hardware is a 41-foot span, unmanned flying wing in a tiltrotor configuration. Two ducted proprotors about eight feet in diameter, embedded near a stubby fuselage, will swivel up to let ARES take off and land like a helicopter and tilt forward to let it fly like an airplane.
The fuselage will be able to carry various plug-and-play payload modules – cargo, sensors, life support gear, even remote-control ground attack weapons are among the ideas — and deliver them to troops on austere battlefields or let those troops employ them.
To lift its “useful load” — payload module plus fuel — of up to 3,000 lbs., the 7,000-lb. maximum takeoff weight ARES demonstrator will be powered by two non-tilting Honeywell Aerospace HTS900 helicopter engines in the fuselage, each generating 989 horsepower. Ashish Bagai, DARPA program manager, expects the aircraft to cruise as fast as 170 knots (195 mph), with a ceiling of 20,000 feet, and have a mission radius of about 175 miles out and back. But that’s just the demonstrator. The contractors are working toward a variant able to cruise at 250 knots with a mission radius similar to the V-22 Osprey.
ARES is now scheduled to fly next fall at earliest, a few weeks after the September 2017 flight of Bell Helicopter’s new V-280 Valor tiltrotor and Sikorsky-Boeing’s SB1 Defiant compound helicopter, both being built for the Army-led Joint Multi-Role Technology Demonstrator program
“You could take a big Chinook or a -53 and very efficiently drop 10,000 lbs. of stuff on a small unit, but then they’re no longer mobile,” Piasecki said. “They’re going to stand around and guard their food. So it’s a transition from a traditional logistics push mentality to an on-demand logistics pull mentality.”
DARPA aims for a full-featured Field Vehicle (FV) to cost around $1 million, compared to $400,000 for a Humvee and $4 million for a light helicopter
Lockheed claims their craft can be configured for several missions including reconnaissance, medical evacuation, and strike. It is to carry a detachable payload module such as a cargo pod, casualty evacuation module, light vehicle, or even a small boat. The front section of the flight vehicle has management system computers that are controlled by a ground control station to plot its flight.
October 26, 2016
US Army top future robotic systems are combat drones with triple the range and various self driving ground vehicles
US Army's top five priorities for robotic systems
1. In fiscal 2018, the Army will begin fielding improved General Atomics MQ-1C Gray Eagle drones, which carry sensors and four AGM-114 Hellfire missiles. Today, the Gray Eagle can stay over a target area eight hours at a range of 725 miles from its base, Allyn said. The Improved Gray Eagle will have greater payload capacity and near triple the range (about 2000 miles) of the existing system.
In July 2015, the Army's Gray Eagle procurement plan was amended to include the extended-range Improved Gray Eagle, purchasing an initial 36 units for the Army’s intelligence and special forces groups; the first 19 IGEs were ordered in June 2015 for the first delivery in September 2017 and completion by September 2018.
The Improved Gray Eagle has a maximum gross takeoff weight 4,200 lb (1,900 kg) with its 205 hp engine, compared to the Gray Eagle's 3,600 lb (1,600 kg) MGTOW and 160 hp engine. The Gray Eagle can carry 575 lb (261 kg) of fuel, while the IGE can carry 850 lb (390 kg) of fuel internally with its deep belly design and 500 lb (230 kg) centerline hardpoint. External fuel tanks can add 450 lb (200 kg) of extra fuel, allowing for a 50-hour endurance. The IGE also increases internal payload capacity from 400 lb (180 kg) to 540 lb (240 kg). Empty weight is 1,318 kg (2,906 lb), endurance without the external tank is 45 hours, and engine can sustain an output of 180 hp continuously. General Atomics has added new winglets that can increase endurance a further one percent and allow the addition of a new vertical antennae. A special operations configuration can carry two Hellfire missiles and a SIGINT payload for 35 hours, as opposed to 14–15 hours for the Block 1 Grey Eagle
2. Lighten soldiers’ physical and cognitive load with the squad multipurpose mission transport.
3. Unmanned trucks and platooned trucks
The Leader-Follower program is developing convoys consisting of four driverless trucks led by one manned by a crew of two
4. Future unmanned systems must facilitate movement and maneuver. Scalable control will allow drone operators and recovery teams to transfer control of their aircraft to troops in the field so they can control them during operations.
Common Robotic Systems will have individual, man-portable, miniature and highly mobile unmanned systems which will be capable of providing dismounted forces with ground-based surveillance and reconnaissance, chemical, biological, radiological and nuclear detection, and explosive ordnance disposal capabilities.
5. Future unmanned systems must help protect soldiers. Robots of the future need to be able to find deeply buried IEDs and detect other threats.
Where fixed wing aircraft cannot fly and helicopters cannot land new fancraft can robotically fly
In January of this year, the Air Mule took its first flight: a short, wobbly hop from the side of a parking lot to a space a modest distance away. On Tuesday, Air Mule makers Urban Aeronautics announced two major feats for the Air Mule program. The first is a new name: Cormorant, after the family of coastal birds. The second is a full, autonomous flight on a preplanned route.
Urban Aeronautics’ Fancraft™ technologies comprise an extensive portfolio of patented innovations that transform a basic ducted-fan design into the foundation for a new family of aircraft, uniquely suitable to urban environments, known as Fancraft™.
Three of the core aerodynamic breakthroughs are:
A “Vane Control System” (VCS), that is comprised of a cascade of vanes at both the inlet and outlet of the ducts that can be deflected either in unison (top and bottom) or differentially to generate either pure side force or pure rolling moment. The ducts (front and back) can also be deflected differentially to generate yaw. The bottom line is that the VCS generates 6 degrees of freedom entirely independent of one another and, for the first time, we have a vehicle that can move sideways without the need to roll and vice versa. In addition, the VCS generates such a great amount of control power that the vehicle can withstand gusts of up to 40 knots.
A set of louvers or similar devices at the front of the forward duct and rear of the aft duct that open during forward flight to allow the incoming flow to move through the duct and thereby greatly reduce drag to enable forward speeds of up to 120 knots.
Close aerodynamic tailoring between the lift rotors and the fuselage whereby the fuselage itself functions as an airfoil and generates sufficient lift at high speed (50% of what the aircraft requires) to be able to off-load 50% of the needed lift from the rotors.
In parallel to the 'standard' Fancraft™ design, Urban Aeronautics has developed a unique, patented Fancraft™ configuration that has the potential of obtaining cruise speeds in excess of 200 Kts. This high speed variant is designed in response to operational requirements in the USA and other countries for a ducted fan, high-speed, unmanned cargo delivery capability.
High speed performance is accomplished primarily through a "stagger" built into the three main components of the vehicle: forward fan, centre fuselage and rear fan. A horizontal stabilizer is also mounted at the rear of the vehicle and canted sharply upward.
On the ground and in hover the fans are essentially horizontal to the ground. When in cruise flight the vehicle tilts forward so that the lift fans are acting partly as thrusters. Lift is distributed throughout the fuselage via a unique geometry that interacts aerodynamically both with the incoming flow and with the two fans mounted fore and aft.
The vehicle's vane control system and other company-patented aerodynamic and flight control provisions further enhance the design with regard to safety, gust capability and noise.
UrbanAero's Fancraft™ technologies are patented with 39 patents already granted and 8 additional in the process.