Northrop BQM-74 Chukar
||First flight|| Introduction
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The BQM-74 Chukar is a series of aerial target drones produced by Northrop. The Chukar has gone through three major revisions, including the initial MQM-74A Chukar I, the MQM-74C Chukar II, and the BQM-74C Chukar III. They are recoverable, remote controlled, subsonic aerial target, capable of speeds up to Mach 0.86 and altitudes from 30 to 40,000 ft (10 to 12,000 m).
The BQM-74E is propelled during flight by a single Williams J400 (J400-WR-404) turbojet engine, which produces a maximum thrust of 240 pounds force (1068 N) at sea level. The BQM-74 is launched from a zero length ground launcher utilizing dual Jet Assisted Takeoff (JATO) bottles. When equipped with an air launch kit, the BQM-74 can be air launched from a TA-4J, F-16, Grumman Gulfstream I or DC-130 aircraft. The BQM-74 is used primarily as a realistic aerial target, capable of simulating enemy threats for gunnery and missile training exercises.
Drones are capable of being recovered following a training exercise. A parachute is deployed by remote control or if the remote control link is severed and a flotation kit can be added for sea-based recovery. If recovery of the drone is required, special telemetry warheads are used on the defensive missile in place of explosives. This telemetry warhead is desirable since it allows for extensive analysis of the performance of the defensive missile, including miss distance information that determines if a real warhead would have damaged the target. A direct hit would likely destroy the drone. Gunnery systems would use non-explosive dummy munitions. Since gunnery systems are aimed in front of a moving target so it will fly through the blast-fragments, dummy munitions do not have to directly hit a target. Analysis of radar data would determine if actual explosive munitions would have damaged the target drone.
MQM-74A Chukar I
The Chukar series began in the early 1960s with a US Navy requirement for a new target drone. The company developed a prototype with the company designation of NV-105 and featuring a delta wing, flying it in 1964. The delta wing didn't work out and was replaced by a straight wing, resulting in the NV-105A, which was first flown in 1965. The NV-105A was accepted by the Navy and went into production as the MQM-74A in 1968.
The MQM-74A had a neatly tapered cigar-shaped fuselage, straight mid-mounted wings, an underslung jet engine with the intake under the wings, and a conventional tail configuration with the tailplanes set in an inverted vee. It was powered by a Williams International WR24-6 turbojet engine with a thrust of 121 pounds (538 N), and was launched by RATO booster from the ground or a ship. The Navy purchased 1,800 MQM-74A Chukar Is. Several hundred more were purchased in total by NATO for a multinational test range on the island of Crete, as well as the Royal Navy and the Italian Navy.
Chukar is the name of an Asian species of partridge, introduced to America and as they are hunted for sport, it seems that Northrop felt that the name was appropriate for an aircraft whose purpose in life is to be shot at. The name Chukar is only formally applied to export versions of the drone, but informally it is used for all variants.
In the mid-1970s, the US Naval Weapons Center used the MQM-74A as the basis for an experimental drone designated the XBQM-108, which was to be used to as a demonstrator for a "pogo" or "tailsitter" aircraft that could take off and land straight up and down on its tail. The fuselage, tailfin, radio control system, and parachute recovery system of the MQM-74A were retained, but the drone was fitted with a new wing, a Teledyne CAE J402 engine with a rotating vectored thrust exhaust, fixed tricycle landing gear, and additional flight control systems. The demonstrator was completed and was making tethered flights when the program was canceled.
MQM-74C Chukar II
The Navy liked the Chukar I but wanted a somewhat faster version, and in the early 1970s Northrop developed the improved experimental MQM-74B, which was followed by the production MQM-74C Chukar II. The Chukar II is difficult to distinguish from the Chukar I, but the Chukar II is slightly scaled up and uses an uprated Williams WR24-7 turbojet with 180 pound (800 N) thrust, giving it a top speed of 590 mph (950 km/h).
Like the Chukar I, the Chukar II is ground or ship launched only. At least 1,400 Chukar IIs were built, mostly for the US Navy, but other customers included NATO, the United Kingdom, West Germany, Greece, Iran, Italy, Japan, the Netherlands, Saudi Arabia, and Spain.
BQM-74C Chukar III
In 1978, the US Navy requested a still more sophisticated drone, and Northrop responded with the BQM-74C Chukar III. This improved variant is visibly different from its predecessors, featuring a more cylindrical fuselage, in contrast with the tapered fuselage of its predecessors.
The BQM-74C incorporates a microprocessor-based autopilot that allows it to be programmed for much more sophisticated flight operations. The BQM-74C can be air launched as well as ground launched. The original engine was the Williams WR24-7A AKA J400-WR-402, with 180 pound (800 N) thrust, but in 1986 production was upgraded to the J400-WR-403 with 240 pound (1070 N) thrust. The BQM-74C is stressed for maneuvers of up to 6Gs. More than 1,600 BQM-74Cs have been built.
Northrop built ten BQM-74C Recce UAVs for tactical reconnaissance for US Navy evaluation, but this variant did not go into production.
BQM-74E Chukar III
The BQM-74C has now been replaced in production by the BQM-74E, which is externally all but identical but incorporates the uprated J400-WR-404 engine as standard, and has a third greater range and endurance than its predecessor.
On 6 January 2015 PHT, Filipino fishermen recovered a drone of this kind floating off in the waters near Patnanungan, Quezon Province, Philippines.  The English newspaper The Daily Mail ran a story with several close-up photos of the drone in orange color. The story included an image showing the model and serial number plate, "MODEL NO. BQM-74E". The plate also showed an "acceptance date" of 02 September 2008. The US Embassy in Manila said that the drone was actually fired four months earlier during American naval exercises off Guam and was just washed ashore in the Philippines through ocean currents. The country's Department of Foreign Affairs spokesperson Raul Hernandez appeared to support the US Embassy explanation, adding that at no time was the aerial target drone launched nor did it fly or crash within the Philippine territory. Human rights groups and even left-wing inclined groups/organizations have either condemned, criticized or called for an investigation regarding the incident, saying that drones can be used for surveillance and they can be used for actual combat operations, as well as suggesting it is used on spying on activities of the communist New People’s Army as part of counterinsurgency efforts. However, Maj. Harold Cabunoc, spokesperson of the Philippine Army, denied that drones were taking part in the fight against rebels.
|The factual accuracy of parts of this article (those related to article) may be compromised due to out-of-date information. (February 2012)|
In the 1980s, Northrop built a next-generation target, the NV-144, that was substantially bigger and faster than the Chukar III, but the NV-144 did not enter production. Northrop, now part of Northrop Grumman, is now working toward delivery of the improved BQM-74F variant of the Chukar, previously known as Target 2000. The BQM-74F has general configuration along the lines of the BQM-74C, but features swept wings, an empty weight of 600 pounds (270 kilograms), an uprated engine with 300 pound (1.33 kN) thrust, speed of up to Mach 0.93, and a design lifetime of 20 flights. The BQM-74F will be able to simulate a range of different aircraft and cruise missiles. It will also be able to tow targets and decoys, and will be compatible with current Chukar support systems and infrastructure. The Navy awarded Northrop Grumman a development contract in 2002, and initial deliveries are scheduled for 2006.
Gulf War combat use
In the 1991 Gulf War, BQM-74Cs were used as decoys during the initial air attacks into Iraq. The USAF Big Safari group was put in charge of the decoy effort, which was codenamed "Project Scathe Mean".
The Chukar drones that were available were usually launched from DC-130 director aircraft, and could also be launched from strike aircraft such as F-15s or F-16s. These launch resources were not available, though, so the Navy found twelve ground launchers in their inventory that could be made serviceable, while RATO booster units were found stockpiled in Belgium. Each BQM-74C was fitted with a pair of passive radar enhancement devices to give it a signature similar to that of a strike fighter.
A 40-person team of specialists, obtained from disbanded ground-launched cruise missile units, was assembled in a few days and designated the "4468th Tactical Reconnaissance Group". The 4468th moved on a fast track, with trucks modified and obtained from a California commercial trucking firm, tool kits purchased from Sears, and field gear bought from war surplus stores. The teams were given quick training, equipped with 44 Navy BQM-74Cs, and sent to Saudi Arabia in two six-launcher teams in about two weeks, arriving near the Iraqi border on 15 October 1990. The northern team was sited to cover Baghdad and large military bases in that area, while the southern team was sited to cover Basra and Kuwait City.
When the air war began on the night of 17 January 1991, Iraq was hit by waves of F-117 Nighthawk stealth fighters and BGM-109 Tomahawk cruise missiles. A group of 38 BQM-74Cs were assigned to be launched as diversion for the second wave of attacks, with the launches generally in groups of three, and 37 were launched successfully in precisely timed waves. One group of three was intercepted by Iraqi aircraft, while all the others made it to target.
The drones flew over 500 kilometers (310 miles) at 630 km/h (390 mph), then began to circle Baghdad for up to 20 minutes. Iraqi air defense radars which probed for the drones were engaged by allied strike aircraft firing high-speed anti-radiation missiles (HARMs). The Navy also launched TALDs to contribute to the countermeasures blitz. Iraqi air defenses never recovered from this blow, and though large Allied aircraft losses had been predicted, the Iraqis only succeeded in shooting down 44 manned aircraft. After the war, the 4468th was disbanded, and one of the remaining BQM-74Cs was donated to the National Museum of the United States Air Force at Wright-Patterson AFB in Ohio, where it is now on display.
USS Chancellorsville accident
On 16 November 2013, a BQM-74E hit and damaged the USS Chancellorsville (CG-62), slightly injuring two sailors and making a hole in the superstructure just above the deck. The drone was supposed to turn away more than a mile from the cruiser during exercises to test the latest version of the Aegis Combat System, but instead carried straight on into the ship.
- Crew: 0
- Length: 12 ft 11 in (3.94 m)
- Wingspan: 5 ft 9 in (1.76 m)
- Height: 2 ft 4 in (0.71 m)
- Empty weight: 271 lb (123 kg)
- Gross weight: 549 lb (249 kg)
- Powerplant: 1 × Williams J400-WR-404 turbojet, 240 lbf (1.1 kN) each
- Maximum speed: 606 mph (972 km/h)
- Endurance: 1 hours 8 min
- Service ceiling: 40,000 ft (12,000 m)
|40x40px||Wikimedia Commons has media related to BQM-74 Chukar.|
- "$24M for 60 Aerial Target Drones", Defense Industry Daily, 29 March 2005
- Jonas Cabiles Soltes, "US-made drone falls in Masbate waters", inquirer.net (Online news site of the Philippine Daily Inquirer), 7 January 2013
- Hugo Gye, "Mystery as American drone is found floating off the coast of the Philippines... 1,000 miles away from the nearest U.S. base", The Daily Mail, 7 January 2013
- Tarra Quismundo, Jonas Cabiles Soltes and Mar Arguelles, "DFA backs US claim drone fired in Guam 4 months ago", inquirer.net (Online news site of the Philippine Daily Inquirer), 8 January 2013
- "Navy investigates drone mishap Why did 13-foot drone not turn away from ship, as programmed?". San Diego Union-Tribune. 18 November 2013.
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- This article contains material that originally came from the web article Unmanned Aerial Vehicles by Greg Goebel, which exists in the Public Domain.