DE4012094A1 - Underwater sonar detection prevention - involves covering submarine hull with material which absorbs sound waves - Google Patents

Abstract

The method enables underwater vessels or other objects (1) to be protected from being located by means of Sonar devices. The method consists of covering the vessel or other object, either wholly or partly, with a layer (4) of material which absorbs or reflects the sonar waves. This protective layer consists of one or more hollow bodies which are filled with a fluid. Each hollow body is made from an expansible material so that the shape of the body can be changed by varying the volume of the fluid. USE - Anti-sonar device for submarines and underwater structures.

Description

The invention is concerned with underwater camouflage bodies against the location by means of sonar cells. The bodies should be both stationary objects, such as mines, as well as moving objects, such as submarines.

According to the task, this camouflage should be timed in a simple manner limited or can be effected indefinitely. If it is a body moved under water, so In addition, there should be the possibility of camouflage in an inadequately suitable condition to keep, however, the flow resistance all if slightly increased or in a state in which they the body against the detection by sonar waves in the highest possible protection, but then a relatively large increase the flow resistance is accepted.

The invention is described below by way of example with reference to the drawing described; it is characterized by the features of the patent Sayings marked, the claims in their ranks follow the invention by increasingly special, but also Identify increasingly practical variants in practice.  

Accordingly, several variants are shown in the drawing represents, described in the description and in the claims claimed.

The drawing shows:

Fig. 1 shows a first variant with a double skin which is associated with a sonar against locating object to be protected and is provided with inflatable bodies, which are equipped with a flow medium or fluid to inflate,

Fig. 2, 3 each a variant of Fig. 1 in each case a partial representation,

Fig. 4 in a highly schematic representation of an up pitch of the overall arrangement in different fields can be activated,

Fig. 5 shows a further variant as a schematic sectional view,

Fig. 6 shows a further variant in a Fig. 1 similar view, but with a fluid as a blowing agent is also used,

Fig. 7 shows a still another variant, in the non-functional position,

8 shows the variant of Fig. 7 position. In the function caused by a fluid,

Fig. 9 shows a detail of the variant according to Fig. 7, 8 and

Fig. 10-13 variants that function in principle in the same way, the individual hairs or tubes forming a "fur", but to a greater extent consist of elastic full material and the movement into the operative position is carried out mechanically.

The principle of the invention is shown in FIG. 1. The surface or a partial surface of a body to be arranged in water 1 is covered with a double-walled skin, of which the inner wall 2 rests tightly on the surface of the body and 3 areas of different elasticity are adjacent to one another in the outer wall. Areas 4 of relatively low or no elasticity enclose circular areas 5 with relatively high elasticity. The space 6 between the walls 2 , 3 can be connected to a high-pressure source 7 or to a low-pressure area 8 for dispensing or receiving a fluid. If the space 6 is connected to the low-pressure area 8 , which is the case when the valve 9 is closed between the space 6 and the high-pressure source 7 and the valve 10 is open between the space 6 and the low-pressure area 8 , then the circular areas 5 lie largely in the plane determined by the areas 4 , There is an uninterrupted, largely flat or evenly curved surface. If the pressure in the intermediate space 6 is significantly increased by changing over the valves 9 , 10 by means of an inflowing fluid, the circular surfaces 5 bulge outwards, so that a kind of pimpled carpet is created.

By appropriately matching the elasticity and pressure, the knob-shaped circular surfaces 5 can be given different shapes. You can have, for example, the shape of tubes 5 a ( Fig. 2), which are open at the end 6 facing the end, closed at the outer end. You can also have the shape of ball or ball sections 5 b ( Fig. 3). If they are in the form of small balls or spheres, the distances between the circular surfaces 5 should be chosen so that when the maximum pressure is effective, the small balls or spheres approach each other and, if necessary, touch each other in a point or line or even area. In any case, a strongly jagged surface is created in which sonar waves run dead without being noticeably reflected. A determination of the body camouflaged according to the invention by means of sonar waves is not possible.

The circular surfaces 5 or inflatable bodies can be arched once in one form or another and continuously arched for the duration of the use of the body. This solution can be applied to bodies permanently anchored under water if the camouflage skin is to be protected during transport or after immersion the background in a manner described later is to be adapted and the body is to be anchored in a set water depth and is used for camouflage are to be inflated by means of locating sonar waves, the regions 5 and in the inflated state for the duration of the insert held. The "body" can be, for example, a sea mine.

However, the arrangement can also be provided for frequent changes in pressure in the case of a body which is drivable under water. The "body" can be, for example, a submarine. During normal marching, a pressure is maintained in the intermediate space 6 so that the areas or circular areas 5 with the areas 4 surrounding them lie essentially in one plane or regularly curved area. The flow resistance of the boat is hardly increased by the Tarnvor direction assigned to it. If the boat enters a correspondingly dangerous sea area, the circular areas 5 are turned outwards by supplying or increasing the pressure. Although they increase the driving resistance and increase the energy consumption or reduce the speed accordingly, they result in highly effective camouflage against sonar waves. There is a solution that is in any case preferable to "sneak driving" in the past. The solution is simple, cheap, reliable and highly effective. Optionally, the invention can also be used to distort the contour of a body for sonar location. The circular surfaces 5 assigned to a body can be combined into groups A, B, C etc. ( FIG. 4). The circular areas within such a group are connected to a common space 6 and this space is alternately connectable to a high pressure source or a low pressure area for a flowing pressure medium, so that the areas of this group are treated in the same way. The groups relative to each other can, however, be treated differently, so that some areas of the body can be determined by sonar waves, others cannot, however, and an observer is given a completely different image from the observed object.

As a means to increase or decrease pressure basically any fluid, be it liquid or gas, be used. Sea water should be particularly advantageous or process water, like when trimming submarines is already in use.  

Alternatively, the body can also be covered with a double-walled skin, in which 11 individual chambers 12 a, 12 b are formed by means of fluid-impermeable webs or partition walls, which can be filled with pressure medium in different ways, so that decontamination takes place over a large area ( FIG. 5). In some sea areas an adaptation to the sea floor is possible, which can also be useful in terms of preventing sonar location.

A variant of the invention is based on the consideration that sonar waves experience a deflection or refraction when they pass from one medium to another medium. In this variant, the object to be camouflaged against sonar detection or its outer wall is covered with a type of "fur" 13 , the fur hairs being fine, flexible tubes 14 whose open ends facing object 1 are part of a double-walled skin covering the object, whose interior 15 and thus the interior of the capillary tubes can be connected to a pressure source, while the outer ends of the tubes are designed as inflatable bodies 16 ( FIG. 6). The training as a swelling body can be done in such a way that the outer ends are already small balls at Drucklosig speed, which are accordingly enlarged with pressure medium supply or that the outer ends are made of such a lighter than the tubes in the other stretchable material that the tubes The cross-section has no pressure over the entire length; when pressure medium is introduced, the outer tubes end up puffing into balls. The pressure medium is preferably air or another gas, but also a liquid whose pressure is correspondingly higher than the pressure of the water in which the object to be camouflaged is located.

The considerations in the previously discussed solutions and those according to the solutions discussed below according to FIGS. 7 to 9 are not actually directed at the tubes, balls or inflatable bodies made of a correspondingly elastic or flexible material, but rather at their content. The Vorstel development is that in the water between the sonar wave source, that is, the observer, and the object to be observed, a fog of sam is formed from air bubbles in particular, which absorbs the sonar waves and behind which the object to be observed disappears or its contour is dissolved . The balls or inflatable bodies only serve to hold the gas or fog heads or bubbles in the water. The camouflage takes place primarily through the air bubbles enclosed by the balls and not through the wrapping of these bubbles.

To give the impression of a fog or veil made of bubbles is to reinforce and perfect the camouflage seen the vesicles on capillaries of different lengths to attach, so that a particularly dense "fur" with in especially irregularly contoured, relief-like Surface arises that the detection of the contour of the ge additionally obscured object.

It is also provided that the droplets or they enveloping balls have different diameters can, if they are inflated by a pressure medium.

If the balls and capillary tubes are depressurized, so lay close to the object when this ride picks up, so that the flow resistance is only insignificant is increased.  

This embodiment of the invention is shown in Fig. 6 Darge, wherein the two walls, the skin to be assigned to the object to be camouflaged is designated 17 and 18 , and the cavity 15 enclosed by these is to be connected to a variable pressure source. The tubes 14 are connected to the wall 18 further away from the object, so that their interior spaces are connected to the interior space 15 of the skin 17 , 18 . Their ends are formed as balls 16 made of a stretchable material, or formed from a stretchable material in such a way that they form the closed ends of the capillary tubes at Drucklo liquid and are not inflated until the balls shown are loaded with pressure medium. In order to be able to form an uneven surface structure, the capillary tubes are of different lengths or the balls are at different distances from the object to be camouflaged.

Otherwise, a breakdown into individual fields as with the other variants.

A modification of the solution according to FIG. 6 which is expedient in some cases is shown in FIGS. 7, 8 and 9. In the depressurized state, the skin is in turn assigned a plurality of tubes made of elastic material, each concentrically surrounding an opening in the skin and the wall of which is structured so that when depressurized there is an essentially smooth tube contour or deformed in an uncontrolled manner from the external pressure ( FIG. 7), when connected to a pressure source, however, a "string of pearls" arises, in which an annular constriction or constriction 20 with a smaller diameter is formed between two of several barrel or bulge-shaped sections 19 on a relatively larger extension in the longitudinal direction of the "string" lies ( Fig. 8). The diameters of the bead-like or barrel-shaped sections 19 can be the same or different from one another; correspond to the applies to the annular constrictions 20 and the number of bulge or barrel-shaped sections 19 and the narrow places 20 may be the same or different from one to the other "string of pearls". This contour can be generated in that at appropriate intervals in the longitudinal direction of the tube around the relatively thin tube wall un expandable rings 21 are placed ( FIG. 9), which also prevent the tube wall from increasing in diameter in the areas of the rings if the internal pressure is so is increased far that the wall of the respective tube between two successive rings 15 inflates into barrel-shaped or bead-shaped sections 19 . Here, each or several rings 21 can be extended to form sleeves (as shown in FIG. 9), the length of which can be determined in accordance with the respective need. In these cases, the tube walls are made of relatively thin, highly elastic rubber or a corresponding material. Instead, a rubberized tissue can also be used, with some threads of the tissue running in the longitudinal direction of the tube and other threads running in the circumferential direction. The threads running in the circumferential direction and the threads running in the longitudinal direction can be elastically stretchable in themselves, but a spacing of the constrictions 20 , rings or sleeves 21 is provided instead of the threads stretching in the circumferential direction that are not stretchable in the circumferential direction and extend in the circumferential direction, so that the maximum possible tube diameter is limited to a relatively small diameter in the area of these threads, while the other, stretchable threads allow the barrel-shaped deformation of the tube wall.

The solutions described so far have in common that - how already mentioned - the object to be protected against sonar detection disappears behind a fog or gas curtain, whereby the liquid droplets or gas bubbles through the shells made of elastic, correspondingly structured material in be kept together and separate from each other.

In the solutions according to FIGS. 10 to 13, this principle is deviated in that a fog or gas curtain is not formed, whereby elastic material only has the task of holding fog droplets or gas bubbles together and keeping them separate, but rather the envelope material itself takes on a fog-forming function. Each of the many tubes is a relatively tight-walled tube 22 , the wall of which encloses an interior 23 which is rather capillary or cannula-shaped over the entire length and has a correspondingly small cross section. Through this capillary interior of each tube, a thread 24 is guided, the apex 22 a is attached to the outer, closed end of the tube on the wall thereof. With its inner, open end, the tube surrounds a corresponding opening in the skin 4 and is thus connected to it. The thread end guided through this opening is connected to an actuating device, in the simplest case to be taken by an operator with one hand. In the Darge presented in Fig. 10, relaxed starting position, the wall of the tube is substantially smooth cylindrical. The tube offers an external flow or a corresponding flow pressure little resistance, so that all accordingly trained tubes more or less smoothly against the skin 4 or the object to be protected, on which only single-walled skin can rest directly . If a protective function is to occur, a tensile force is applied to the thread 24 of the respective tube, which in the embodiment according to FIG. 11 shortens the overall length of the tube and thereby deforms it into a ball-shaped contour 25 at the outer end. In addition, the outer and inner contour of the tube is preserved, so that a ball held on a flexible handle is formed from practically full material when the tensile force acting on the thread. This formation, which appears similar to that of FIG. 6 externally, can be achieved in that the wall material formed at the end of the tube in the region of the stem and in the region of the ball has a correspondingly different internal structure. This can be achieved, for example, by using fabric coated with elastic material and using the fabric threads in the handle area much closer together than in the ball area, or by using stretchable yarns in the area of the handle, inextensible threads in the area of the handle.

This solution can in turn be further developed in that, according to FIG. 12, a plurality of balls 26 follow one another along the length of the tube. This formation of the tubes in the tensioned state can be effected by choosing the material structure in the sense described above.

In the latter case according to FIG. 12, the material structure of the tube should be chosen so that the outer contour of the respective tube is crowned in the area of each bead in the tensioned state outwards or convexly curved, but also the inner channel 23 of the tube is narrowed so far is that in the region of the spherical beads 26 the thread 20 is completely surrounded by the tube material without play ( FIG. 13). Purpose of this solution is, in addition to the robustness achieved, which is essentially shared with the solution according to FIGS. 10, 11, that sonar rays encounter a largely constant material structure in the beam direction when hitting a tube, as is the case in the embodiments according to FIGS. 1 to 8 with the pressure medium and the very thin shell material is also largely the case. In the embodiments according to FIGS. 1 to 8, this is due to the predominant proportion of pressure medium, which is only held together by the sleeve of the tube, in the embodiments according to FIGS. 10 to 13, the predominance of the elastic material over the gas inclusion in the narrow channel 19 lead back.

These solutions can also be divided into individual fields according to the principle of FIG. 4.

Claims (13)

1. A device for protecting underwater bodies against sonar detection, characterized in that the body to be protected is completely or partially surrounded by a sonar wave absorbing or reflecting the layer. 2. Device according to claim 1, characterized in that the layer of one or more of a fluid filled hollow body or hollow body. 3. Apparatus according to claim 2, characterized in that the / the hollow body filled / filled with a fluid consists of expandable material, the volume of the / the hollow body / hollow body can be changed by changing the fluid filling ( Fig. 1-6) . 4. The device according to claim 3 in association with one body movable under water, characterized in that that the hollow body (s) in one of fluid completely or largely drained a flow resistance stood the body as low as possible, in against a state filled to the maximum with fluid Sonar location occupies maximum protective contour.   5. The device according to claim 4, characterized in that the layer ( 3 ) is formed by a surrounding on the body when setting a selected internal pressure at a predetermined distance, in pressure-free, possibly adjacent to the body, double-walled skin, the outside ( 4 ) is filled with a large number of expandable individual bodies ( 5 ). 6. The device according to claim 5, characterized in that the individual bodies have the shape of tubes ( 5 a) which are open at the end near the skin ( 3 ) and at a for filling fluid to a central high pressure source ( 7 ) or for emptying can be connected to a low pressure area ( 8 ) and are closed at the outer end. 7. The device according to claim 6, characterized in that the individual bodies have the shape to be filled or emptied hollow spheres or hollow spherical sections ( 5 b) instead of the shape of tubes. 8. Apparatus according to claim 6 or 7, characterized in that the individual body ( 5 ) have such a distance from each other that they stand in the fluid-filled to stand one another flat or at least point-wise. 9. Device according to one of claims 6 to 8, characterized characterized that several individual fields to groups are interconnected such that the individual body to fill or fill a group with fluid are emptying while the single body of a group in its entirety independent of the individual bodies fill one or more other groups with fluid or to be emptied.   10. Device according to one of claims 6 to 9, characterized in that the individual body ( 12 a, 12 b) by fluid-tight webs ( 11 ) between the cover surfaces ( 2 , 4 ) of a double-walled skin ( 3 ) are formed, the body surrounded in its entirety or in part or assigned to it. 11. The device according to one of claims 1 to 10, characterized characterized in that the fluid is a gas or a liquid is. 12. The apparatus according to claim 4, characterized in that each of the individual bodies consists of rubber or comparable material and is tubular and has a closed end and is attached to the skin with its open end, surrounding an opening in the skin, wherein the tube body ( 18 ) is relatively thick-walled and encloses a cannula-shaped, ie a ge ring-shaped cross-section interior ( 19 ) which is penetrated by a thread ( 20 ) which is attached to the outer, closed end ( 18 a) of the tube body and is passed through the skin opening in order to be assigned to an actuating device at this end, so that each tubular individual body can be shortened ent against its bias in its longitudinal direction or in the case of ineffective actuating device and correspondingly elongated thread in its relaxed state it has its maximum length extension ( Fig . 7, 8). 13. The apparatus according to claim 12, characterized by a Material structure with which the tube body relaxes condition has a smooth inner and outer wall and in tensioned state at the end of a bead, if necessary also several successive ones in the longitudinal direction of the tube  Bead forms, with the convexly curved outer contour each bead the initial outside diameter of the tube enlarged, the and also convex interior contour of each bead the cross-section of the cannula-shaped Interior of the tube body is reduced, if necessary until each bead with its convex inner surface on the Thread is present.