DE248636C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

~ M 248636 CLASS 65 d. GROUP

Patented in the German Empire on October 20, 1909.

The invention relates to a self-propelled torpedo, the weight of which by receiving large ^; Amounts of control cables, explosives, operating and heating means is greater than its buoyancy, and which receives the buoyancy necessary for swimming through floating surfaces which are arranged in front and behind in such a way that the resultant of the buoyancy forces goes through the center of gravity of the torpedo. Around Here

ίο at i. those that occur when moving in the water To limit the resistance of the torpedo equipped with hover surfaces as much as possible and 2. the buoyancy of the front hover surfaces through small adjustments to change the surface inclination angle significantly, a lower one at the torpedo head Buoyancy and an upper counter surface arranged, the projection of which is essentially falls into the projection of the torpedo cross-section to increase the resistance to avoid the torpedo while driving.

In order to keep the buoyancy of the torpedo changing with the speed of travel To be able to regulate the front hover surface, the warhead can be rotated in the torpedo body stored. Its rotation around a horizontal axis perpendicular to the torpedo longitudinal axis changes the inclination and thus the buoyancy of the hover surfaces.

Here, the opposite surface falls to the task set under 2, the buoyancy already through to change small angular adjustments considerably more than the lower surface alone could.

This effect of the opposing surface is explained by the fact that the effective lift Representative difference between the two opposing surface pressures in the event of a change in angle grows or decreases faster than the upwelling of the lower surface alone grows would.

For example, results with a certain torpedo speed and a certain inclination and size of the bottom surface of the buoyancy kg to 2250, so the increase buoyancy kg with a ⁰ to 3 larger angle of inclination to 2900, to 2900 to 2250 = 650 kg. If the lower surface is connected to an equally large counter-surface in such a way under the same assumptions that both the unchanging peak angle] of 38 ⁰ to include, at a certain (against the first example somewhat enlarged) so is inclination of the buoyancy of the lower face only 3450 kg, the downward pressure of the opposing surface 1200 kg, the effective buoyancy thus 3450-1200-2250 kg. If this area system is ^{rotated by 3 0} , as in the first example, the corresponding numbers are 4300 kg and 750 kg, the effective lift 4300 - 750 = 3550 kg and the increase in lift 3550 - 2250 - 1300 kg. It can therefore be seen that for the above assumptions, the increase in lift with the same angular ^{adjustment (3 0} ) results in values that are twice as large (1300 kg) for the system with a counter surface than for the system without a counter surface (650 kg).

The use of the counter surface therefore allows extremely sensitive height control of the torpedo.

In order to expand the limits of the buoyancy, the lower floating surface can also be used enlarged or reduced.

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The drawing shows a self-propelled torpedo with artificial lift and, on an enlarged scale, the warhead with the two types of surface change.
Fig. Ι and 2 show the torpedo in plan and plan, and that is α with the warhead. the front floating surface b together with the counter surface c, d are the rear floating surfaces and e are the screws. The front and rear floating surfaces and the opposing surface combine in their buoyancy effects in such a way that the torpedo can run horizontally at all speeds.

3 and 4 show the warhead α with the floating surface b and counter surface c in elevation and plan. For the purpose of setting the two surfaces according to the running speed, the head α is rotatably mounted in the torpedo body g by means of two pins /. The rotation can take place, for example, with the aid of a lever system h and a push rod i from a regulating device connected to the screw shaft or from the depth apparatus or from both, the push rod i in the example executing a reciprocating movement. The directions of movement have been indicated in the drawing by arrows.

5 and 6 show the second arrangement in elevation and plan, in which both the inclination of the surfaces b and c and the size of b can change depending on the running speed or diving depth.

The head α with the surfaces b and c is rotatably mounted in the torpedo body, for example by means of the joint k located at the top. On the floating surface b lie sliding or, as shown, pivotable surface pieces m about the pivot I. The rotation of the head α can be effected by a lever system η and a push rod Ό from the depth apparatus or a regulating device operated by the screw shaft. The displacement of the surface pieces m can also take place by means of the push rod 0 and the connecting rod q acting on a lever system p , or also, independently of the rotation of the head a, by a second push rod. The arrows shown indicate the directions of movement of the push rod 0 and the areas m for the movement transmissions assumed as an example.

Claims (2)

Patent Claims: 1. Self-propelled torpedo with artificial buoyancy created by hover surfaces, characterized in that the bottom and top of the head are designed as a front floating or counter surface and that the head itself, for the purpose of changing the buoyancy, is rotatably mounted in the torpedo body about a horizontal axis is. 2. Self-propelled torpedo according to claim 1, characterized in that the lower Area of the head can be increased for the purpose of further changing the lift. 1 sheet of drawings.