Monday, 25 November 2019

German Explosive Ordnance - Rockets (Part 4)







German Explosives





HS 298


No picture available


V-1
Length Overall: 328 centimeters
Length of Fuselage: 180 centimeters
Span of Wings: 129 centimeters
Span of Horizontal Stabilizer: 53 centimeters
Height of Vertical Rudder: 29 centimeters
Diameter of Fuselage: 39 x 20 centimeters


V-2
Length Overall: 249 centimeters
Length of Fuselage: 191 centimeters
Span of Wings: 127 centimeters
Span of Horizontal Stabilizer: 53 centimeters
Height of Vertical Rudder: 31 centimeters
Diameter of Fuselage: 39 x 25 centimeters


Principal Weights
Launching Weight: 120 kilograms
Weight at Target: 98 kilograms
Weight of Propulsion Unit: 33 kilograms
Weight of Explosive: 48 kilograms


Performance
Average Horizontal Speed: 240 meters per second
Mach. No.: 0.75
Max. Range: 3.5 kilometers at 5,000 meters altitude (approx.)
Min. Range: 0.6 kilometers
Ceiling Above Launching Point: 1.3 kilometers
Max. Elevation for Attacks from Below: 50 degrees


Propulsion Motor
Total Rocket Motor Weight: 27 kilograms
Booster Charge Weight: 5 kilograms
Main Powder Charge: 6 kilograms
Weight (Empty): 16 kilograms
Total Propellant Weight: 11 kilograms

Duration of Burning of Main Rocket: 25 seconds
Duration of Burning of Booster: 5.5 seconds
Thrust of Launch with Booster: 150 seconds
Booster Impulse: 1,200 kilograms per second



In April 1944, production of 2,500 Hs. 298's was ordered by RIM with a peak production rate of 300 airframes per month.  In July 1944, the RIM ordered the production of an additional 2,000.



Description: This missile was designed primarily as an air-to-air weapon to be carried on fighter aircraft as well as the bomber types.  The fuselage is of the conventional type mounting twin vertical tail surfaces at the ends of the single horizontal tail surface, the horizontal tail surface being mounted high on the fuselage.  The arrowhead wing is placed about the center of the fuselage.  The nose, like the Hs 117, is symmetrical, the asymmetry on this missile being the vertical plane.

For the propulsion system this missile uses a two-stage powder rocket.  Spoiler type of aerodynamic controls is used.  This missile used a short length of launching track mounted underneath the parent aircraft.



The following detailed report is written around the Hs 298 V-2, as this model is considered the basic model of the series.


Airframe


Description: The fuselage is a stressed aluminum skin structure.  The wing and tail are cast magnesium with an aluminum covering.  The cast magnesium wing frame is extremely light in weight and rigid.


Aerodynamic Characteristics/Peculiarities: The missile is controlled in roll and yaw by trailing edge spoilers on the wings.  It is controlled in elevation by spoilers on the horizontal stabilizer.  Trailing edge spoilers were used because they gave an adequate and simple control as compared to other systems and produced less drag.

The forward part of the fuselage of this missile, like that of the Hs 117, is non-symmetrical; however, in this missile the asymmetry is in the vertical plane.  The reason for this change is not known.  The after section of the fuselage also has a peculiar shape in that it ends in two tubular shapes, placed one above the other.  The top one is the smaller of the two and accommodates either a flare or a light for the purpose of recognition and enabling the pilot to follow it.  The lower circular cross section accommodates the powder rocket motor.



Power Plant


Propulsion Motor Data: The power plant is a powder rocket with two combustion chambers exhausting through the same nozzle.


Fuel: The fuels of this motor are dry powder.  The booster is a single perforated charge with a round hollow shaped charge having a very slow burning rate.  In the hollow cavity of this charge are placed alternate slugs of material, first a slug of powder with a very high burning rate (apparently similar to black powder) followed by a slug of inert material.  These slugs are packed one against another throughout the core of the main slow burning powder.  This combination presented only few problems, the main one being the sensitivity of the fuel to temperature.  For a time it was thought necessary to heat the projectile while still attached to the launching aircraft, but experiments in this direction had not been completed.


Operation: Apparently the powder available for the main charge burned too slowly to use the standard end burning technique, so a complicated procedure was worked out.  In order to obtain sufficient area for burning, a conical burning surface is used.  To prevent this surface from degenerating to a section of a sphere as the charge burns, the peculiar core construction was devised.  This consists of alternate plugs of an inert material and a very rapid burning powder.  With the proper geometry of these plugs, the speed of core burning can be maintained which will preserve the original core angle.  The chamber pressure is lower during the burning of the main charge than during the boost.  It was desired to decrease the throat diameter of the nozzle to compensate for this effect, but this was never achieved.



Intelligence and Control System


Description: The radio receiver and other electrical equipment of this missile was made as similar as possible to that of the Hs 117, the main difference being the arrangements to accommodate the two-wire control that is used for this missile.  Since all radio directed missiles are subject to jamming, the Germans, including Wagner's group, have experimented extensively with this two-wire missile control.  All Henschel missiles are adaptable to wire control.

It is interesting to note the crude form of air speed measuring device intended to control the throw of the spoilers in the same proportion to the missile speed.  This device is mounted on the top of the tail portion.  This restriction to the throw of the spoilers is probably done by inserted the spoiler solenoid circuits by means of a resistor on the pivoted, spring returned support of the pear-shaped speed measuring plug.

Power for the electrical system was obtained from a propeller-drive generator. This missile was limited to use against targets with a speed of 140 meters a second or less.



Warhead and Fuze


Warhead: This missile contains a 48kg thin case blast effect charge.  It is reported to be placed around the outside of the propulsion unit, which appears necessary from space considerations and is desirable in that the C.G. of the propellant charge can be held nearer to the C.G. of the entire unit.  A small amount of insulation protects the explosive from the heat of the propelling charge.


Fuze: The missile was designed for the C-98 "Abstandszunder" high-frequency proximity fuze; however, nearly any of the other proximity fuzes would work.  This missile also incorporated a self-destroying fuze which operated at a certain time interval after launching.



Launching Device


This missile uses a rail-type launcher 60 cm in length hung on the carrier aircraft on the under side of the fuselage or wing of either bomb or fighter aircraft.




Next Time: Rockets (Part 5)


Source: German Explosive Ordnance Vol. 1: Bombs, Rockets, Grenades, Mines, Fuzes & Igniters

Monday, 18 November 2019

German Explosive Ordnance - Rockets (Part 3)







German Explosives





HS 293 A-1


Length Overall: 381.9 centimeters
Span of Wing: 310 centimeters
Span of Horizontal Stabilizer: 113.6 centimeters
Span of Vertical Stabilizer: 98 centimeters
Diameter of Fuselage: 47 centimeters
Diameter of Power Unit: 33 centimeters

Height Overall: 109 centimeters (approx.)
Average Chord: 79.3 centimeters (approx.)
Wing Area (Total): 2.4 square meters
Wing Loading (Launch): 441 kilograms per square meter
Wing Loading (Target): 390 kilograms per square meter
Weight of Warhead: 500 kilograms
Weight at Launching: 1045 kilograms
Weight at Target: 967 kilograms
Weight of Fuel: 78 kilograms

Maximum Velocity: 260 meters per second
Average Velocity: 230 meters per second

Maximum Range at:
2.2km Altitude: 4 kilometers
4.0km Altitude: 5.5 kilometers
5.0km Altitude: 8.5 kilometers

Radius of Turn: 800 meters
Designed "G": 3.0 g.




Description: The Hs 293 A-1 has principally an aluminum, stressed skin, spot welded structure.  The forward portion of the fuselage is structurally the bomb casing with an aluminum covering or fairing.  Fastened to the rear of the bomb is a vertical plastic beam (about 3/8 inch thick) which runs to, and is fastened to, the after portion of the fuselage.  The radio and the associated gear for the controlling of the bomb are mounted on either side of this plastic beam.  On the after corner of this beam is mounted a roller.  The after portion of the fuselage is a stressed-skin, semimonoque structure with a rail (for the aforementioned roller on the plastic beam) mounted on the top inside of the structure.  Quick disconnection fasteners are mounted at the connection between the rear of the bomb fairing and the forward end of the rear fuselage to be quickly detached and rolled off the bomb and plastic beam, giving quick and complete access to all of the control gear.  The wing and tail are aluminum and of the usual built-up type.



Aerodynamic Characteristics: The missile is controlled in roll by the normal type of ailerons on the trailing edge of the outer portion of the wing.  The ailerons also control the yaw effect.  It is controlled in pitch by the normal type of control surfaces on the trailing edge of the horizontal tail surface.



Control System: The control system consists of the following parts:

A. Receiving set E-230.  This unit could use any of the 18 channels, each of which were 100 kc apart in the band between 48 and 49.7 mc/s and could be changed easily in the field to satisfy the operation requirements for frequencies.

B. "Aufschaltgerate" for damping and smoothing the receiver signals.

C. Three-phase AC gyro for stabilization in roll and yaw.  It has a precession rate of 2 degrees per minute.

D. High resistance double potentiometer for proportioning the data.

E. 210-volt D.C. generator for the receiver.

F. A transformer with built-in relays to activate the aileron surface magnets.

G. Elevator mechanism with an "Oemiz" motor and potentiometer for returning the elevator to its normal position.

H. An iron nickel plate battery of 24 volts with approximately 14 amp/hours.


This missile, because of the type of intelligence used, is limited to use in good, clear weather and with air superiority.  It is subject to jamming, and this, therefore, may limit use to targets where jamming equipment is not installed.

A joystick type of control was used in the parent aircraft.  This control box made use of a very clever cam arrangement which gave proportional control.



Warhead: The warhead was constructed in one section of drawn steel.  The base plate was welded in position.  The nose filling plug was threaded and held in place by two set screws.  A kopfring was welded to the nose just behind the nose plug.  One transverse fuze pocket was located aft of the suspension lug.  A central exploder tube used in the explosive cavity to insure high order detonation of the warhead on impact with the target.




Operation

Upon locating the target, the carrier aircraft makes its approach to the trajectory distance, and in the last of its dive, sets a course such that the target can be seen 30 to 60 degrees to the right of the course.  Shortly before release time and particularly at the moment of release,t he carrier aircraft must be in a horizontal position.  At the time of release the aircraft must have a minimum speed of 334 km/hr if the He-111 is used, and 400 km/hr if the He-177 or the Do-217 are used.

The missile is released and directed to the target by the bombardier.  Immediately after release, the speed of the aircraft may be reduced, but the release altitude and direction should be maintained for a period of approximately 10 seconds.  After this interval of time, it is no essential to maintain release altitude and course direction.  It is important that any change in flight be done slowly and carefully so that the target remains on the side of the bombardier during the entire flying time of the missile.  The field of view of the operator and the freedom of the carrier plane in approach may vary according to the type of aircraft.  In all carrier planes, there should be a field of view of approximately 110 degrees to the right.  The flying time of the Hs 293 A-1 should not be greater than approximately 100 seconds.




Remarks

The Hs 293 is the outgrowth of the "Gustav Schwartz Propellerwerke" glide bomb which was first designed in 1939.  The further development of this glide bomb by Henschel represents their first attempt at a radio controlled missile.

The original Schwartz design was a pure glide bomb guided on a straight course by means of an automatic pilot.  The method of attack entailed high altitudes for the carrier aircraft in order that sufficient range could be attained and still be out of anti-aircraft fire.

Henschell took over the work of further developing this missile in early 1940, and it was decided to use some form of propulsion for the missile so that attacks at low altitude and increased range could be made.  The Hs 293 A-1 was the first model to be used operationally with the new motor.

In as much as all future models under development were very similar to the Hs 293 A-1, it will be the only missile of this series discussed in detail.  The following is a list of projects which emerged from the original Hs 293 A-1:


Hs 293 B: This was a wire-controlled version of the original radio-controlled series, designed to be used in the event of a jamming of the radio control mechanism of the original series of bombs.  The G.A.F. considered that up to 70 percent disturbance was permissible before a change-over to the wire-controlled series would be necessary.  Since these conditions were never attained, the Hs 293 B was never put into use.


Hs 293 C: This missile was a modified version of the Hs 294 and had a detachable warhead, etc., in the same manner as the Hs 294, but a conventionally shaped body.  The fuzes included an impact fuze with a short delay to allow for penetration in cases where the missile struck a ship above its waterline, an impact fuze which detonated immediately on impact after it had entered the water, and a fuze operated by a spinner which detonated the missile after a passage of 45 meters through the water.
 This subtype was designated the Hs 293 C during its development stage, but when large scale production was to start, it was changed to the Hs 293 A-2, and was to replace the original radio-controlled series for general purpose use against shipping targets.


Hs 293 D: This was a projected type of missile to be fitted with a television camera in the nose.  The camera was designed to repeat data back to the missile controller.  The camera was designed to swing vertically and was aimed in the line of flight by a small wind vane on the outside of the projectile.  As the projectile was rudderless, and in theory should not yaw in flight, there was no need to allow for any traverse in the camera mounting.  About 20 of these missiles were built and test flown, but the television gear proved unreliable, and the project was abandoned.


Hs 293 E: This was purely an experimental model built to try out a system of spoiler controls to replace the conventional aileron mechanism.  These controls were incorporated in the final model of the Hs 293 A-2, but were never employed operationally, since by the time the bomb was brought into large scale production, the G.A.F.  had no aircraft left for anti-shipping purposes.


Hs 293 F: This was a tailless missile which was never developed beyond the design stage.


Hs 293 H: This missile was intended to be released and controlled in flight by one aircraft and detonated by a second observing aircraft, which would be flying in position where it would be easy to observe the impact of the missile against the target.  The project was abandoned because it was felt that the detonating aircraft would be unable to remain directly over the target long enough to carry out its function.


Hs 293 V6: This subtype was developed for launching from jet-propelled aircraft at launching speeds up to 200 meters/second.  This involved modification of the wing span of the missile so that it could be carried within the undercarriage of the aircraft.  The Ar 234 aircraft was to be used as the parent plant, and since it was not yet available at the conclusion of the war in Europe, the missile never progressed beyond the design stage.







Next Time: Rockets (Part 4)


Source: German Explosive Ordnance Vol. 1: Bombs, Rockets, Grenades, Mines, Fuzes & Igniters

Monday, 4 November 2019

German Explosive Ordnance - Rockets (Part 2)







German Explosives





HS 117 "Schmetterling"




Design and Performance Data

Length Overall: 429 centimeters
Length of Fuselage: 369 centimeters
Span of Wings: 200 centimeters
Height of Vertical Rudder: 92 centimeters
Diameter of Fuselage: 35 centimeters

Weight (Empty): 150 kilograms
Launching Weight: 430 kilograms
Weight at Target: 175 kilograms
Weight of Assisted Take-off Units: 180 kilograms (90 kg per)
Main Power Fuel: 12.7 kilograms
Main Power Oxidizer: 59.2 kilograms
Compressed Air: 3 kilograms
Explosive: 25 kilograms

Maximum Velocity: 250 meters per second
Average Velocity: 240 meters per second
Maximum Range: 20 kilometers
Service Ceiling: 10.5 kilometers
Absolute Ceiling: 13 kilometers



Main Propulsion System

The main power unit is a liquid rocket with a pressurized fuel feed and a variable automatic thrust.

Main Power Fuel (Tonka): 12.7 kilograms
Main Power Oxidizer (Salbei): 59.2 kilograms
Compressed Air: 3 kilograms
Charged Weight: 159 kilograms
Weight (Empty): 80 kilograms

Total Launching Impulse: 14,000 kilograms per second
Main Thrust Unit Impulse: 12,500 kilograms per second
Total Impulse: 26,500 kilograms per second
Launching Thrust: 3,00 kilograms per second
Maximum Thrust of Main Unit: 380 kilograms
Minimum Thrust of Main Unit: 60 kilograms

Burning Time of Main Unit: 40 to 90 seconds
Maximum Combustion Chamber Pressure: 40 atmosphere
Average Thrust: 220 kilograms
Average Time of Burning: 57 seconds

Overall Length of Main Thrust Unit: 17 inches
Overall Diameter: 4 and 1/2 inches
Throat of Nozzle Diameter: 1 and 7/16 inches
Exit of Nozzle Diameter: 2 and 7/8 inches



Description: This missile, probably better known as the "Schmetterling", is a rocket propelled, radio-controlled, missile for use against bomber formations.  Some versions are for ground-to-air and some for air-to-air operations.  The fuselage is of the conventional type mounting a single vertical tail surface and a single horizontal surface.  The horizontal surface is mounted well above the center line of the fuselage.  The arrowhead wing is mounted on the center line of the fuselage.  The forward section of the fuselage is non-symmetrical in order to accommodate a proximity fuze and a propeller-driven generator.

This missile is launched from the ground from a simple two armed zero length rail launcher.  The two arms support the missile at the wing roots at about the center of gravity.  Two assisted take-off units are used for ground-launching, one above and one below the fuselage.  At the end of burning these ATO units are jettisoned by means of explosive bolts which throw them clear from the airframe.  The air launched version does not use ATO units but is simply dropped from a standard bomb shackle.

Some of these models are automatically homed and some are remote controlled.  A single gyro automatic pilot is used for stabilization.



Details

Airframe - Type and Description: The main units of the fuel system form the backbone of the fuselage.  At the forward end is the steel air flask nested into the forward end of an aluminum Salbei tank.  Next comes an aluminum casting through which passes the main wing spar, and which is also used to space the hydrocarbon tank further aft for the proper distribution of the C.G. of the fuel since it is desired to have the fuel C.G. coincide with the C.G. of the entire aircraft.  On the after end of the hydrocarbon tank another aluminum casting is bolted which supports the main propulsion unit and the air stabilizer structure.  All of these tanks and castings are securely bolted together, forming the entire backbone of the aircraft.  This structure is covered with sheet aluminum.  The nose section, also formed of aluminum, is screwed to the forward end.

The wing and tail are built-up sections consisting of a cast magnesium frame with an aluminum covering.  The case magnesium wing frame is extremely light in weight and is rigid.


Airframe - Aerodynamic Characteristics or Peculiarities: This missile is controlled in roll by spoilers of the trailing edges of the wings.  These spoilers work out of phase with one another.  Yaw is controlled by the trailing edge spoilers on the wings.

Spoiler control was used for this model because, as in other missiles, it gave adequate and easy control as compared to other systems and produced less drag.  The spoilers also present a much more simple method of control than other systems.

This missile is rather unique in that assisted take-off rockets are place both above and below the fuselage mounted in the vertical plane of the center line of the fuselage.  It is also interesting to note the extent of asymmetry of the forward portion of the fuselage.  It was considered by the designer, Prof. Wagner, that horizontal asymmetry would be less harmful than vertical asymmetry, the asymmetry being necessary to correctly place the generator propeller and the fuze.

For reasons of stability, the missile, upon ground launching, makes at least one complete roll about its longitudinal axis.  If at the end of this roll the air speed is not great enough for adequate stability, it will make a second complete roll.  Seldom, however, is the second roll necessary.  This roll event is built into the control equipment and is entirely automatic.  During launching, the acceleration is about 8g.



Operation

Because aerodynamic characteristics at high speed change rapidly with small changes in speed, to make the control problems as simple as possible, it was decided that the speed of the missile should be held as nearly constant throughout the flight as was practicable.  This was accomplished by automatically regulating the thrust output of the main jet in relation to the velocity of the missile, 240m/s, being the arbitrary average velocity.  This regulation was accomplished by balancing the two pressures taken from a pitot static tube across two opposed aneroid barometric elements which, in turn, by means of electrical contacts, actuate an electric motor which operates a fuel control valve limiting the flow of fuel to the combustion chamber.  A constant proportion of the two reactants entering the combustion chamber must be maintained at all times at a ration of 2 parts nitric acid to 1 part hydrocarbon.  If one or the other of the reactants is allowed to collect in the combustion chamber an explosion will occur.  The nitric acid is also used to cool the nozzle.  It flows into the cooling jacket at the after end of the nozzle and then flows forward and enters the combustion chamber where it meets the hydrocarbon.  No ignition apparatus is necessary as these two fuels are self-igniting.

Professor Wagner was not satisfied with the motors which were developed by Dr. Sbyrowsky of BMW, feeling that they were too heavy.  Dr. Conrad, of the Berlin Technical High School, had been obtained by BMW to improve the motor design.  Dr. Conrad was experimenting with un-cooled liquid fuel motors for this project and at least two forms of combustion chamber material had been tried; one a form of graphite and the other a material built up of many layers of a very pure ceramic material such as silica or alumina.  These showed considerable promise and might have been incorporated in later designs.  Other liquid fuels were also being considered.  By means of various refinements it was hoped that the missile speed could be raised from a Mach No. 0.75 to 0.8.

Both reactant tanks are built of aluminum and are carefully machined.  The outside casting is bored so that a closely fitting piston (without rings) will slide in it.  In operation the liquid side of the tank is initially full, forcing the piston against the head.  As air enters the head, the piston travels to the right, forcing liquid out of the tank.  The object of this design is to insure that when the tanks are less than half full no slugs of compressed air are fed down the reactant pipes as the aircraft performs tight maneuvers.  Although the motor would re-ignite after stopping, a collection of one of the two reactants would cause an explosion.  On the forward side of the air bottle is a connection to which is T'ed a filling plug and pressure gauge which reads up to 250kg/sq.cm.  The bottle is charged with air to 220 atms.  On the aft connection to the bottle is a diaphragm which is punctured by an electrically fired squib.  The outlet from this connection leads to a regulator which delivers air to the two reactant tanks at 40 atms. (590 lbs/sq.in.)  On each side of each reactant tank there is a diaphragm valve which is blown when the 40 atms. pressure appears at that point.  This is done to prevent any possible contact of the reactants during storage or handling, and also to insure that both fuels enter the combustion chamber at the same time in order to prevent an explosion.  At full thrust, nitric acid enters the combustion chamber through 16 holes, and the hydrocarbon through 8 holes of equal size.  The thrust regulation is obtained by the aforementioned regulator motor, operating (through a gear train) a rotary valve plate which blocks off the holes limiting the amount of fuel which can enter the combustion chamber (fuel pressure being constant) and also maintaining the fuel ratio of 2 to 1.




Control System

This missile at first mounted a Friesecke & Hoptner receiver which operated at about 6 m.  The equipment was considered as too complicated and heavy for the missile and consequently was superseded by a further development of the "Staru" radio receiver for the Hs 293.  This new receiver was of the super-regenerative type having a much smaller form factor than the previous Hs 293 receiver, and was designated the E230-3.

For controlling the missile, the controlling ground station sends out a high-frequency signal which, by modulation with a lower frequency and appropriate keying, conveys to the missile directions for altitude, or elevation, and azimuth.  By referring to its gyro the missile is able to interpret and follow these signals.  On the ground, the signals are manually initiated by means of a "joy-stick" control which sets the pitch and yaw directions for the missile to follow, and which the missile will follow until the position of the stick is changed.

On the ground, the courses of the target and the missile are followed by means of an optical sighting device.  From observations with this device, missile course corrections are set which will bring it to the target.  No homing devices had been applied to this missile, although they had been discussed and were under development in several firms.  Professor Peterson of AEG had been working for some time on a universal radar ground computer for guiding flak missiles to their target.  RIM wanted Wager to incorporate this in the Hs 117 control, but he wished to keep it in its original simple state.  In the future he intended to develop homing devices to supplement his visual control for use in thick weather.  It is reported that Wagner would have liked to have this missile beam-guided to a radar followed target, but he felt that German radar was too inaccurate for the job.

Various developments for the radio control of this missile were being carried out be several firms.  Some work was being done in the range from 20 to 40 centimeters.  These frequencies were desirable since they could be beamed and were interfered with less by the jet than the longer wave lengths.  Shorter wave lengths were not considered, since suitable tubes were not developed.  In some cases, jet interference could be reduced by changing reactants.  In all cases solid powder gave the most trouble.  It was considered that Telefunken was doing the best work in radio control.  They were concentrating on 40 cm.

The electrical power for this missile was delivered by a propeller-driven generator located in one of the two noses of the missile.  On the ground, before launching, this same generator was driven by a motor in an outside power source.  During this period the propeller did not turn as it was provided with a three ball free-wheeling cam device.

The missile is stabilized about its longitudinal axis only by one gyro.



Limitations of the Control System

The only apparent limitation of this missile lies in the fact that it cannot be seen and consequently followed in overcast weather.  If homing devices, other than optical, were incorporated, this limitation would no longer exist.



Warhead and Fuze

Warhead: Considerable divergence of opinion existed in the RIM on the effectiveness of warheads with blast effect only as against fragmentation or incendiary pellet filling, but when the tests of the Hs 117 had been completed in the summer of 1944, the first series was ordered in August of that year with a blast effect warhead weighing 25kg filled with "Trialen" which was manufactured by Wasag at Reinsdorf near Wittenberg.


Fuze: It was intended to use a proximity fuze whenever developed and available.  The performance specifications for the fuze required operation between 6 to 10 meters.  It was intended that a small clock work arming device would arm the missile about 10 seconds after take-off.  Another device is incorporated, probably working off of the control gyro, which explodes the main charge if the missile rolls over on its back in flight, in which case all controls would be revered, making the missile uncontrollable from the ground by an operator who would not be aware of this condition.  Another timing device was incorporated which operated 120 seconds after launching to destroy the missile.



Auxiliary Equipment

This missile is equipped with two assisted take-off units, one above and one below the fuselage, each provided with nozzles offset at an angle such that the lines of thrust intersected at about the C.G. of the aircraft.  In launching, the lower booster is fired first, thus forcing the missile upward and forward off the launcher which is a simple two-armed cradle supporting the missile at the wing roots (zero length rails).  There is a 2 and 1/2-meter firing lanyard, which fired the top unit automatically.  Both units then burn until their powder is burned out by which time the main jet has been ignited and takes over.  Each assisted take-off unit has a total weight of 90 kg and contains 40 kg of powder charge.  Burning takes place from the inside out only since the outside is treated with "Polygon", a plastic preparation which prevents burning on the surfaces to which it is applied.  

The booster thrust totals 3,500 kg lasting for about 4 seconds.  It burns at a rate of about 5.8 grams per second.  This thrust brings the missile up to a speed of about 240 m/sec.  These boosters units are known as SG (Schmidding Geraet) 33.  They were developed by Schmidding in Bodenbach, and used powder made by Wasag, located near Wittenberg.  At the end of the booster burning time, the boosters are jettisoned by means of a powder charge and piston device.  Also under discussion as a method of dropping the boosters was a device which depended upon the reduction of the pressure within the booster unit itself.




Launching Device

This missile is launched from a simple two-armed cradle which supports each wing at its root in such a  way that an upward and forward motion of the projectile will carry it free from the launcher.  There is no movable dolly on this launcher.  The launcher is manually aimed in elevation and azimuth in response to signals received from a fire-control point.  Sighting devices for the launcher were contemplated but were never incorporated.








Next Time: Rockets (Part 3)


Source: German Explosive Ordnance Vol. 1: Bombs, Rockets, Grenades, Mines, Fuzes & Igniters