DE103680C - - Google Patents

Description

^Λ (I

IMPERIAL

PATENT OFFICE.

The present invention aims, on the basis of a novel togetherness, of a Storey and train system to reduce the cross-sectional area of the storeys without how it has hitherto been the custom to reduce the diameter of the bullets and the caliber, so that from now on one maintains the craftsmanship's precision, with a larger diameter of the projectile and barrel tilt a floor with a significantly smaller cross-sectional area can, with the exclusion of the great disadvantages which result from the reduction of the barrel diameter (Caliber) assert that these are difficult parts of the barrel manufacture, big ones Length of the projectile in relation to its diameter, which requires a strong twist and especially the significant gas tensions. The proof of this is given below with an example by calculation The formulas and so on that appear authoritative to the inventor are used here.

All these disadvantages do not apply to the projectile according to the present invention, which provided with 3 to 4 longitudinal grooves cut almost to the axis of the bullet which run uniformly deep along the entire length of the story, with the tip of the story may maintain a conical shape or the shape of a paraboloid of revolution.

If these longitudinal grooves of the bullet were to increase or deepen backwards, so with regard to the theory on which this invention is based, no point, because only the largest cross-sectional area of the projectile may be taken into account, which divides the necessary weight into the total weight of the projectile Cross-sectional loading results, while the above-mentioned case only reduces it to the disadvantage would.

It would be just as pointless if the longitudinal grooves were not used for the sake of the floor guidance completely penetrated or a cylinder-shaped one at the rear end of the projectile Part wanted to attach or adapt, because then only the effect of a projectile with full cross-section results in musts, but not those of the storey according to the present one Invention.

However, there must be a cylindrical sealing plug between the propellant charge and the projectile stored so that the powder gases do not escape through the grooves can. However, this plug separates from the bullet immediately after it leaves the muzzle because of its comparatively low specific gravity, it is the same is made of a material that is as light as possible and, moreover, not at all with the projectile is connected, but only needs to lie flat against it, hence no guidance has to worry about.

In the present case, the new kind of togetherness ensures the precise floor plan this floor with the traction system. Above all, the bullet must have at least three grooves, because under this one Number would have to create a chisel-shaped storey for its precise self-guidance there is never any security, unless it is a matter of

act contactor bullet, which you can always insert exactly into the trains of the tube, which However, this case should not be considered here.

This already shows that this is how the story and the train system belong together must be such that the storey can be positioned in the transition cone of the The course is able to assume a safe leadership by itself, whichever condition is necessary is to be achieved by the present invention.

With a large number of grooves, however, precise guidance would be easy and without A special traction system can be obtained, but then the cross-sectional area cannot be sufficient reduce, because one cannot make the grooves sufficiently wide and deep in this way; thus a maximum of four grooves can still be considered.

The profile of the grooves, intended for themselves alone, can, however, be designed in a variety of ways The only thing you have in mind is the greatest possible reduction in the cross-sectional area to keep - this is the main thing, because the size of the air resistance and the Resistance in the aim depends only on the size of this area - provided that it is all other factors involved here, such as B. density of air, specific gravity of Projectile material, length of the projectile and the projectile tip, etc., remain the same.

This already illuminates z. B. from the following empirical formula for calculating the Penetration power, which is:

~ - Gv ²

In this formula:

D is the penetration depth of the bullet in cm,

β a coefficient which depends on the material to be penetrated by the projectile, G weight of the bullet in g,

ν speed of the projectile at the beginning of penetration in m,

Q. Storey cross-section in qmm.

The possible deformation of the projectile in the target is not taken into account in the above formula, but this fact is quite irrelevant for the following proof.

As can now be seen from this formula, the penetration force D in one and the same target must be greater, the smaller the cross-section of the projectile, if G and ν remain unchanged.

Now, however, it could be objected that the latter cannot be true, because as a result, that those deep grooves are made in the storey, the absolute weight of the The projectile is reduced, but one must not be careful that the smaller it is the weight of the bullet will be, the greater the initial velocity of the bullet must, provided that the absolute weight does not sink too low, so does the applied weight Amount of propellant can reach combustion in the course of the weapon before the projectile the mouth is running out.

So the loss of the absolute weight has at the same time an increase in the initial speed, so that this works out Product of the numerator does not change in the fraction of the above formula, although its factors change mutually change. This can be done with the help of an empirical and approximate correct formula for calculating the initial speed must be demonstrated.

The same is:

A =

-Vi

In this formula:

A is the muzzle velocity of the projectile in m per second,

α is a coefficient that depends primarily on the type of propellant, but also on the friction of the projectile during its course, i.e. on the traction system and projectile material,

P weight of the powder charge in g,

G Weight of the bullet in g.

If one now substitutes the relevant values for two cases in the above formulas, then the predicted is proven by the billing route.

Let it be:

α = 1700,
β = ο, οοι,
P = ag ,.
G = 15 g,
Q = 50 qmm.

i. Case:

A = 1700 * I / = 620 m.

Hence [close to the mouth]
15 ■ 620 ²

D = 0.00

= 115 cm.

If you now take G = 10 g instead of 15 g, so is in this

2nd case:

A = IOO -y - = 759 m.

Hence [close to the mouth]

10-759 '
50

= 115 cm.

The decimal places have been deleted as irrelevant.

So in both cases it arises

D - 115 cm.

It is therefore clear that, if Q = 30 qmm, a much larger one will result Penetration depth results in mufs.

However, this is only true if the projectile is at the same time sufficiently large Retains a cross-sectional load of approx. 0.3 g per 1 sq mm.

In the second case presented, D would have to be lower, because as soon as Q = 50 qmm in both cases, the floor of the second case must be much shorter if the same projectile material is present, so that it can only have an inadequate cross-sectional loading.

However, the present invention makes a bullet despite the weight reduction keep the original cross-sectional load because it is not shortened, but that weight reduction takes place as a result of the deeply incised longitudinal grooves. Consequently this weight reduction goes hand in hand with the reduction in the cross-sectional area Hand.

The following examples prove this.

Assume that the specific gravity of the material chosen for this is in both Felling = 10.

A 30 mm long cylinder with a diameter of 8 mm has a cross-sectional area = 50.266 mm.

Hence its volume = 1.50798 ecm. This results in an absolute weight of 15.0798 g. It is therefore the transverse

■. ,, ι c, 0798

Cutting load ———— = 0.3 g per 1 sqmm. 50.260

Longitudinal grooves are now made in this cylinder so deep that its cross-sectional area = 30 sqmm, the volume of the same also sinks to 0.9 cmm, the absolute weight to 9 g, but the cross-sectional load of

- = 0.3 g per ι qmm remains, as can be seen,

still upright.

Thus it has now been proven that this novel reduction in cross-sectional area and absolute bullet weight is rational, hence the basis of this new invention based on no deception.

However, the advantages sought by the new invention are gradually being achieved Long-known way also by the fact that one z. B. the projectile diameter of 8 mm a 30 mm long bullet with a full cross-section reduced to 6 mm in diameter, without changing the length of the storey, but in this way become even accepted those disadvantages which were emphasized in the introduction to the description because in this case the length of the storey is in proportion to the diameter of the storey bigger; one must therefore shorten the twist length of the barrel by the necessary number of turns to maintain the stability of the projectile. Enough for the new storey but the old twist length is completely off, because the diameter is that of the old bullet diameter is the same, although the cross-sectional area appears to be reduced.

For example, experience has shown that it is sufficient for a storey with a full cross-section of 8 mm in diameter and approx. 30 mm length a twist length of 250 mm, because the same results in one Initial speed of only approx. 600 m per second a number of tours of

_r 1000

600 = 2400

250

per second, thus a speed of the circumference of the bullet around the longitudinal axis

= 25.13 x 2400 = 60 3 12 mm = 60.312 m

per second.

However, in this case there is a greater initial velocity for the storey at hand, if the cross-sectional area of 50.266 sqmm of the 8 mm bullet is reduced to approx. 35 sqmm, because so the absolute weight also decreases, so that an initial velocity of approx. 700 m per second must result,

which have a number of tours of 700

1000
250

= 2800

per second and thus a circumferential speed of 25.13 · 2800 = 70364 mm = 70.364 m concludes, however, as can be seen, without shortening the twist length. The 6.5 mm Round storey, which in this case also has an initial speed of can assume approx. 700 m, would get with this twist length of 250 mm despite an initial speed of 700 m a circumferential speed of only 18.85 x 2800 = 52780 mm = 52,780 m, which is insufficient and therefore based on a shortening of the twist length It must be enlarged, which is also supported by the experiences made.

Through these examples, the advantages of the present storey appear in line with the calculations proven. However, if the invention is applied to a 6 or even 5 mm bullet on, you get bullet effects that are no longer achieved with round bullets at all can be achieved because one is with the technical means available today is not able to measure the floor diameter of 5 mm and thus the floor cross-sectional area go further after old use

to be partially reduced, while the reduction of the cross-sectional area with the aid of the present invention can still be continued with advantage.

In Fig. Ι the consistently uniform cross-sectional area of such a projectile a with four grooves r, in Fig. 2 of a similar projectile b with three grooves r.

The projectile α is equivalent to a full projectile (without grooves) of 5.3 mm caliber and the projectile b is equivalent to one of only 4.8 mm caliber, although the caliber of the projectiles α and b is 7 mm.

Accordingly, according to the present invention, the smaller caliber is obtained without the barrel diameter to have to reduce.

However, if one were to incline these projectiles α and b from any pipe with a diameter of 7 mm, without taking the tensile profile into account, then no precision would be achieved, because uneven projectile friction would have to result from Schufs to Schufs.

In order to avoid this, the projectile belongs together with a polygonal tensile profile p, the sides of which are not wider than the width of the projectile guide parts and the number of sides can be divided by the number of projectile grooves r, the friction of the projectile in the tube being the same for all possible positions remains great. In Fig. 1, storey α takes guidance on the sides of polygon p, storey b , on the other hand, at the corners, which is completely equivalent, also with regard to the possible intermediate positions, because the outer storey circumference was originally the same as that of the transition cone, which in both Figs. 1 and 2 is shown dotted.

For the sake of guidance, it is also necessary that the grooves form the transverse profile of the projectile possibly cut at the same angle as the helix angle of the associated one Run.

It goes without saying that the corners of the polygon should be somewhat rounded or flattened can be, or the sides can also be designed arcuately.

In addition to the already described effect, this new togetherness of the projectile and barrel achieved other new and significant effects. Such a Success is the reduced wear and tear on the pipe core.

As can be seen from Fig. 2, there are only three corners or three sides in each shot of the polygon is stressed by friction, so that only four times as large a number of shots would have to be done to bring about such barrel wear as is the case with round storeys.

But this success turns out to be still greater when one takes into account that besides that side support in Fig. 1 and that corner support in Fig. 2 still a whole series of intermediate positions are possible.

Another success of this new connection is the higher initial speed, which results from less friction in the pipe without a new powder to have to create.

Such bullets can be made of either suitable metal or metal alloys, too made from lead and hard lead and in the latter case coated with other metal.

The new storey shape can also be seen in FIGS. 3 to 7.

Fig. 3 shows a side view of the projectile. Fig. 4 is a section according to Line I-I and FIG. 5 is a section along line II-II of Fig. 3. Fig. 6 is a longitudinal section of the projectile along line III-III of Fig. 4, while FIG. 7 shows the section along line IV-IV of FIG. 6.

Claims (1)

Patent claim: Storey with three or more depths of equal depth over the entire length of the storey incised longitudinal grooves, whose wings are curved according to the twist of the barrel in a traction system with a polygonal cross-section. 1 sheet of drawings.