NO151640B - AMMUNITION UNIT, EXERCISE FOR EXERCISE FORM - Google Patents

Description

The present invention relates to an ammunition unit

which can be launched at supersonic speed and is fin-stabilised, for training purposes intended to replace combat ammunition with conventional ogival or conical nose parts and of a type which, up to a maximum firing distance, has ballistics substantially equivalent to the ballistics of corresponding conventional combat ammunition, but which has a maximum shot range that is significantly reduced, e.g. to half, in relation to the conventional combat ammunition, comprising a front tip-shaped part, a cylindrical middle part and an elongated tail part, the length of which exceeds the respective length of the middle part and the tip and is designed with a number of fins.

The training ammunition is intended to form a more economically advantageous alternative to the combat ammunition that it is intended to replace during training. A requirement for practice ammunition is thus that it has at least essentially the same ballistics as the combat ammunition in question. A quantity of practice ammunition that fulfills this requirement has previously been known.

In order for the requirement for essentially the same ballistics up to the firing range to be met, it has been assumed until now that e.g. maximum firing ranges for the ammunition in question must correspond to that of the combat ammunition to be replaced. This, in turn, has meant that relatively large areas had to be canceled for practice shooting in question.

The ammunition unit according to the present invention

aims to solve i.a. the problem of being able to reduce the requirement for available shooting range lengths. In this case, the invention utilizes the insight that a tip in the form of a spike provides advantages from, among other things, stability point of view. What can essentially be considered to be characteristic of the new ammunition unit is in this case that the front tip-shaped part is made up of a previously known cylinder-shaped tip, so-called "spike", the diameter of which is significantly reduced in relation to the diameter of the middle part and whose length is 1.6 -

2.0 times the diameter of the middle part and that the tail part is designed in such a way that the fins with full caliber measure extend along essentially the entire length of the tail part and join at the front

to the rear part of the middle part.

The essential thing in this case is the length of the cylindrical tip in relation to the outer caliber measurement of the middle part. In accordance with a preferred embodiment, in this case said length should be 1.6 - 2.0 times the diameter of the middle part, preferably 1.65 - 1.85 with an absolute preferred value of approx. 1.7 times the diameter of the intermediate part.

Further developments of the invention's basic idea include further specific tasks, e.g. when it comes to the construction of the tail section.

By using a point in the form of a spike, a dead air area is obtained around this at supersonic speed, so that the radial surface facing the direction of flight of the ammunition unit does not exert any braking effect on the ammunition unit. At subsonic speed, on the other hand, the air flows along the mantle surface of the tip and said radial surface, so that it later exerts a large braking effect on the ammunition unit, which can thus maintain a substantially unaffected ballistic trajectory as long as it travels at supersonic speed, but undergoes a rapid deceleration as soon as it travels above subsonic speed. Said deceleration means that the ammunition unit will get

its significantly reduced maximum firing range. The tip used has a mainly stability-increasing effect both in supersonic and subsonic speeds and in the passage of the sound barrier itself. When using the proposed tip, the distance between the Tp and T^ points is effectively increased by a distance value corresponding to up to a caliber. The proposed shape of the tail section also contributes to the aforementioned stability function.

The new ammunition unit's shape contributes to the fact that an efficient and thus economical production method with cold flow pressing can be used. With the cold flow pressing, an increased holding strength is automatically obtained, which makes e.g. curing. Thereby, the dangers of e.g. crooked fins due to hardening. The cold flow pressing means that the ammunition unit is pressed in one step, which means that the ammunition unit is obtained in a substantially finished state. It will only be necessary to turn and apply the belt and possibly the steering bead. The design of the ammunition unit and the method used in its manufacture lead to savings in material, energy and costs.

A proposed embodiment of an ammunition unit according to the invention will be described below with reference to the drawings, where fig. 1 is a perspective obliquely from the rear showing a practice projectile, fig. 2 is a perspective obliquely from the front showing the projectile of fig. 1, fig. 3 shows the projectile according to fig. 1 and 2 seen from the side, fig. 4a shows, viewed from the side, a principle sketch of the tuft flow ratio at supersonic speed for the practice projectile in fig. 1-3, fig. 4b shows, seen from the side, a principle sketch for the air-flow conditions at subsonic speed for the practice projectile in fig. 1-3, fig. 5a shows in diagram form balli-stick curves for maximum firing distance for partly a practice projectile according to the invention, partly a corresponding conventional combat grenade, fig. 5b shows in diagram form ballistics curves for maximum firing ranges for partly the practice projectile according to the invention and partly a corresponding conventional combat grenade, fig. 6a shows, seen from the side, a cylindrical blank which is used as a starting blank in the production of the new garnet by means of tools for cold flow pressing and fig. 6b shows, seen from the side, and in principle the moments in the production, where the practice projectile has been given its final form in a symbolically shown tool for cold flow pressing.

Fig. 1-3 aims to show a practice projectile which is provided with a mainly cylindrical part 1, a tip 2 which joins this and a tail part 3. The pro-projectile tip 2 is formed by a so-called spike which in principle is previously known . The tip is mainly cylindrical in shape and has a diameter d which is significantly reduced in relation to the diameter D of the cylindrical part and as an example it can be mentioned that the tip's diameter d is approx. 1/3 of the middle part's diameter D. The tail part is provided with fins 3a which e.g. can be in a number of six.

The mainly cylindrical tip 2 is given a length L.. which in the case shown is approx. 1.7 times the diameter D of the intermediate part. The said length can be varied depending on caliber, type of ammunition, etc. between 1.6 and 2.0 times said diameter D, preferably between 1.65 and 1.85 times said diameter.

The length of the tail part is greater than the respective lengths L.. of the tip 2 and the middle part 1. Lg- The fins of the tail part extend along the significant part of the length of the tail part with full caliber measure. In connection with the middle part, the fins r are taken down below the caliber measure and have slanted upper edges 3a' which extend outwards and backwards counted from the middle part. The intermediate part is rearwardly provided with a surface 1a which has the main shape of a truncated cone. Said surface rather in relation to the longitudinal axis of the projectile with an angle "K" which is between 10 and 20°, preferably approx. 15°. The narrowest part of the conical surface faces and is connected to the ends of the fins. The length of the conical surface is 1-3%, preferably 2% of the total length of the projectile. Said conical surface helps to control the airflow sweeping down along the middle part in its longitudinal direction between the fins 3a of the tail section, thereby improving the stability of the projectile.

In the case shown, the length of the middle part is shorter than both the tip and the tail part. The intermediate part carries a front annular outer groove and a rear annular outer groove for a front guide bead 4 and a belt 5. Both the guide bead and the belt are made of plastic, e.g. acetal or equivalent.

In fig. 3, the center of gravity of the projectile is shown with

Tp and center of pressure with Tc, while the distance between Tp and Tc, which is important for stability, is shown with A.

Fig. 4a and 4b show the air flow conditions at the projectile's supersonic or subsonic speed. In fig. 4a, the compression shock wave is indicated by 6 and a dead air area in the form of a rotationally symmetric area around the tip denoted by 7. The mentioned area is limited by the lateral outer surfaces of the tip 2, a radial front surface 1b on the middle part and a right conical shaped imaginary outer surface 8 which extends from the front end surface of the tip to the periphery of the radial surface 1b. An undisturbed flow takes place in the direction of the arrow 9 along the straight, conically shaped outer surface 8, and means that there is no

there is some braking effect from the radial surface.

The above implies that the projectile, as long as it has supersonic speed, can assume a ballistic trajectory corresponding to the ballistic trajectory of a projectile equipped with an ogival-shaped, conical-shaped or otherwise shaped nose. The use of the spike-like point results in an advantageous return movement in the projectile's longitudinal direction of Tp and Tc as well as an advantageous long distance A, which together guarantees a sought-after high stability for the projectile in and of itself. It should be noted in this connection that the projectile becomes stable not only at supersonic speed, but also

when passing through the sound barrier and at subsonic speed.

Fig. 4b shows the flow conditions at subsonic speed. The air flow 10 can take place along the side outer surface of the tip and the significant radial surface 1b on the intermediate part 1. This means that the radial surface 1b will exert a braking effect on the projectile which significantly reduces its maximum shooting or flying range, e.g. to only approx. half of what applies to conventional combat ammunition that the practice projectile is intended to replace. Fig. 5a and 5b shall show the ballistic characteristics of the practice projectile in relation to a conventional combat grenade. As an example of the aforementioned combat grenade, in this case a 9 cm combat grenade of model 77 marketed by Bofors has been chosen, which has a weight of approx. 3.7 kg. The practice projectile is also of caliber 9 cm and has a weight of approx. 3 kg. The diagram's y-axis shows the pitch's height in meters and the x-axis the shot distance, also in meters. The maximum firing distance for the ammunition in question is 800 m.

The curve a shows the trajectory of the combat grenade and the curve

b for the practice projectile when the grenade is fired from the barrel with Vq = 670 m/s and the practice projectile with Vq = 715 m/s. The curves show that the ballistics for shooting at a distance up to the maximum shooting distance are essentially the same, which means that a thorough training of the cannon operator can be achieved by shooting with the shown practice projectile.

Diagram 5b shows the ballistic curves for maximum shot range, with the y-axis showing the height in meters and the x-axis the horizontal distance in meters. The curve a' for the combat grenade according to the above shows in this case a maximum firing range which is approx. twice as long (6000 m) as the maximum firing range of the practice projectile. This is explained by the fact that the practice projectile slows down sharply when it enters subsonic speed. It should be mentioned that the shown construction of the practice projectile is stable within its entire velocity range, e.g. between 0 and 3 times the speed of sound. This means that the practice ammunition will be easy to trace.

The described practice projectile can advantageously

is set by cold-flow pressing. A blank is then placed into a tool for cold flow pressing and with the tool

the projectile is placed in a single step which entails simultaneous pressing of the tip and the fins. Then takes place an after-

following smaller caliber target turning.

In fig. 6a shows a blank 11 which is used as starting material for the production of e.g. said 9 cm practice pros jectile. The blank has a cylindrical shape with a diameter of 9 2 mm and a length of 200 mm. The tool halves are indicated by 12, 12'. The pressing takes place in a single step and pre-

is set to be completed in fig. 6b, where the tool's sharing

plan is denoted by De and the forming space by F.

When the fully pressed practice projectile is taken

out of the tool, it is turned down to the measurements shown in e.g. fig. 3. The projectile has a length of approx. 465 mm.

Cold flow pressing as such is previously well known

and shall therefore not be described in more detail here.

Claims (4)

1. Ammunition unit that can be fired with supersonic velocity and is fin-stabilised, for training purposes intended to replace combat ammunition with a conventional ogival or conical nose section and of a type which, up to a maximum firing distance, has a ballistics essentially equivalent to the ballistics of corresponding conventional combat ammunition, but which has a maximum firing range which is significantly reduced , e.g. to half, in relation to the conventional combat ammunition, comprising a front tip-shaped part, a cylindrical middle part and an elongated tail part, the length of which exceeds the respective length of the middle part and the tip and is designed with a number of fins, characterized in that the front tip-shaped part consists of a previously known cylinder-shaped tip (2), so-called "spike", whose diameter (d) is significantly reduced in relation to the diameter (D) of the intermediate part and whose length is 1.6 - 2.0 times the diameter of the intermediate part (D ) and that the tail part is designed in such a way that the fins (3a) with full caliber measure extend along essentially the entire length of the tail part and join the rear part of the middle part (1) at the front. 2. Ammunition unit according to claim 1, characterized in that the tip is given a length (L^) which is 1.65-1.85, preferably approx. 1.7, times the diameter of the intermediate part (D). 3. Ammunition unit according to claim 1, characterized in that the middle part (1) towards the rear carries a conically designed surface (1a), preferably a slightly conically designed surface, whose axial length extent is 1 - 3% of the ammunition unit's total length, preferably approx. 2% of said length (L^ + L- + L^) and that the front fins extend below the caliber target with inclined upper surfaces (3a') to join the rear and narrowest part of said conically designed surface (1a). 4. Ammunition unit according to claim 1, characterized in that the middle part (1) is provided with a guide bead (4) made of plastic and a belt (5) also made of plastic.