EP0986298A1 - Artificial bait - Google Patents

Abstract

For big-game fishing artificial baits are used. Such baits like a wobbling spoon and a blinker are usually pulled in water by the fisher in such a way that they imitate by their bowed shape the movements of real fish. The imitation of nature by certain baits, however, is often inefficient with careful fish. This is why the inventive artificial bait has a caudal fin (3) which can be actively actuated in one direction or the other by means of a pulling member (9) meshing with both flanks (12, 13). Owing to additional breaks in the movement and an elastic design of the caudal fin (3) a particularly misleading imitation of a true fish behaviour is obtained, resulting in optimal bait efficiency, including with big game.

Description

description

Artificial bait fish

description

The invention relates to an artificial bait fish which, when baiting a fish, mimics the attracting movement of a live fish, having a movable tail fin which is firmly connected to the bait fish body.

When fishing for larger predatory fish, live fish have proven to be the best bait. The animal welfare concept largely prevents the use of live bait fish. In addition, these are not always and everywhere available, and they are often only able to withstand the stress on the hook due to injuries when fastening and quickly changing the water depth for a very short time.

For this reason, reusable artificial baits in the shape of fish have been developed in various forms, for example as wobbers, indicators or pirks. These can be used at great depth without any problems and mimic the movement of a real fish when they pull through the water. Due to a special body curvature, certain pilker bait fish generate a wobble movement. In addition, the tail fin of these baits is connected to the fish body via an eyelet, so that it can be moved by the water resistance when baiting. Nevertheless, the bait fish that such bait fish exert on the prey fish is only limited. The movement performed is not sufficiently lifelike. Especially when fishing for large predatory fish, such as pike, their recognition ability is therefore difficult to outwit. The technical problem with which the invention is concerned is therefore to provide an artificial bait fish of the type described in the introduction, the movement of which is so lifelike that even fish that are more difficult to fish show an optimal catch. The cost-effectiveness of such a bait should be taken into account. In addition, other bait features known per se, such as fish size and appearance, should also be realizable with the bait fish.

The solution according to the invention for an artificial bait fish therefore provides that the tail fin has a pulling element on the inside, which acts on its two opposite flanks, which can be alternately tightened on the flank side by a drive, and that the drive is arranged together with its energy supply in the baitfish body.

Essential to the invention is the targeted mobility of the caudal fin due to the flanking alternating tightening of the tension element via the drive. Since the main drive for most fish is via the tail fin, it is absolutely sufficient to move the fish's tail back and forth in one stroke. In this way it is possible to imitate a deceptively real fish movement that does not fail to have an effect on the prey fish. This movement becomes active, i.e. regardless of the water flow, the sinking speed, the bait intake and the bait shape, and thus reliably produced. The means for generating the tail movement in the form of a tension element and a drive with energy supply are simple and therefore inexpensive. With regard to the reusability of such a bait fish, the costs to be applied are relatively low.

A further improvement in the course of movement without measures that visibly change the bait can be achieved if after an advantageous one

Embodiment of the invention, the drive can be controlled in a time-adjustable manner and the control electronics are likewise arranged in the baitfish body. By The movement sequence can be set to pauses of different lengths and distances. This must not be too regular so as not to reduce the impression of the tail movement of a live fish. Irregular tail movements achieve a particularly large illusion effect. In order to avoid a monotonous movement, the break sections can be varied. For example, the drive's control mode allows a pause after several tail movements. The number of successive tail strokes and the pause length can be set as desired, so that a particularly lifelike tail fin movement can be achieved with the artificial bait fish according to the invention. A pausing tail movement also requires less energy than a continuous movement. As a result, the energy supply arranged in the baitfish body can be dimensioned relatively small with its limited resource. Nevertheless, a sufficiently long operation of the bait fish is guaranteed when baiting. The arrangement of the control electronics in the baitfish body does not change its static attracting effect. Due to the small size of the corresponding component, space-saving integration in the bait is readily possible.

The attachment of the traction element inside the bait fish on its two flank sides can be done directly, for example, by means of appropriately provided eyelets. However, it is advantageous if, according to a next embodiment of the invention, a strut is arranged at the level of the points of attack of the tension element between the two flanks. This can then simply attack directly on the strut. This offers sufficient mechanical stability both for the transmission of the necessary tensile forces and for the bait fish itself. Furthermore, in the manufacture of the bait fish it is possible to prefabricate the entire interior apparatus to a large extent, which then only has to be covered or cast in by the fish skin. Subsequent assembly work is not necessary. This ability to preassemble is further simplified if, after a further development of the invention, the strut is arranged on an elastic rod which is connected to the housing of the drive. The elasticity of the rod enables a rigid, right-angled connection to the strut and supports the required restoring force when moving the tail. Additional improvements in the production of the actual bait fish shape result if, in addition, the strut, together with other frames of different widths, which are also connected to the elastic rod, already define the outer shape of the caudal fin, similar to the construction of a ship's hull, in accordance with the invention. The spatial sequence of the bracing with the frames in the tail fin can be almost arbitrary.

The structure of the traction element inside the baitfish body can be designed differently. In principle, the following variants are suitable for bait bodies with without without inner struts. However, since this is particularly advantageous, only embodiments with bracing will be discussed in more detail. According to a next embodiment of the invention, the traction element can have two traction cables, each of which engages with one end at the ends of the strut and is wound with its other ends on an axis of a servomotor which can be controlled as a drive. The direct connection of the two pull cables to the axis of the servo motor is a simple and inexpensive solution. Due to the opposite winding of the two traction ropes, a rope is always wound up and a rope unwound when the motor rotates, so that a rope is tensioned and the caudal fin is pulled in the corresponding direction. For this type of movement generation, however, it is necessary that the motor can be controlled in the direction of rotation and that its direction of rotation is constantly reversible in accordance with the tail stroke.

Therefore, according to a further embodiment of the invention, it is particularly advantageous if the traction element has a traction cable that is guided over two deflections has, whose two ends each engage the ends of the strut and which has a fastening element between the two deflections, in which a cable guide engages, which is arranged on an eccentric disc of a DC motor as a drive. The DC motor used here is a conventional component that is even simpler and therefore cheaper. It does not have to reverse the direction of rotation. The back and forth movement of the tail is rather caused by the rotary movement of the eccentric disc, on which the one pull rope is fastened via a fastening element, for example in the form of a simple slot in the rope, with a rope guide in such a way that it cannot wind up. This serves z. B. a small T-shaped mandrel on the eccentric disc, which extends through the cable slot. The two deflections, by means of which the one pull rope is deflected twice by 90, so that it functions in the same way as the two pull ropes described above, are formed, for example, by simple axles fastened in the fish body.

According to a further embodiment of the invention, the tension element can also have a rigid rod instead of one or two tension cables. It is then advantageous if it engages with one end at one end of the strut and is connected with its other end to an eccentric disk of a direct current motor as the drive. The motor with the eccentric disc could, for example, be identical to that for the pull rope. It would only have to be arranged rotated by 90 so that the eccentric disc runs parallel to the tie rod. The connection between the two can be rotated accordingly. Both tension and pressure can be transmitted via a rigid rod. This reduces the number of components required. In addition, a rigid element is less sensitive to any mechanical obstacles inside the bait during manufacture and use.

The connection between caudal fin and fish body can be realized in different ways; this is, for example, an articulated one Connection with eyelets. If the bait body is open from behind, the drive, the power supply and the control electronics must be protected against the ingress of water, for example by a simple housing. In the case of an articulated connection between body and caudal fin, the caudal fin can be made from a hard material, for example from sheet metal. The traction element is then simply guided past the joint connection into the interior of the body. However, it is particularly favorable if, according to another embodiment of the invention, the caudal fin consists of a bite-resistant, elastic material and is rigidly connected to the baitfish body. The tension element and the associated parts are then fully protected and lie in the open internal connection between the body and the tail. Its elasticity corresponds to that of a real tail fin and produces an even improved, very natural tail movement. The bite strength of the material protects against the attack of larger prey fish, so that the internal parts are protected from destruction and the reusability of the bait fish is guaranteed.

To protect the drive with its energy supply and the control electronics against the ingress of water, these can be encapsulated, for example, in a watertight manner. If, however, the body and tail are already rigidly connected to one another, it is particularly simple and inexpensive if, after further development of the invention, the elastic tail fin is connected to the baitfish body in a watertight manner. All water-sensitive parts are then safely protected inside the body.

Such a watertight connection can be produced, for example, by arranging a corresponding seal as a ring or sealing compound. In this way, different materials can be securely connected. However, it is advantageous if, according to a next embodiment of the invention, the tail fin and the baitfish body are made in one piece from the same bite-resistant, elastic material. The inner parts can then, for example, in a complete fish body made of plastic be poured in. Corresponding cavities can be provided for the movable parts. The tension element can, however, also be cast in and simply released by a single movement. It is then safely guided in the plastic. You can even replace the power supply by removing the plastic cover and pouring it in again. It is helpful to arrange the components in a small housing, which does not necessarily have to be watertight.

When fishing, the choice of bait fish depends on the type of fish to be attracted. Some fish react not only to movement, but also to the size and appearance of the bait fish. Therefore, the artificial bait fish according to the invention can advantageously also have other features

Attract a fish. It can vary in sizes from about

Finger length can be produced. His body shape can be widespread, i.e. preferred prey, such as roach. As a pirk, it can be provided with four catch hooks or as a blinker, for example, a wide variety of glitter decorations, reflective foils, glow sticks,

Have eye markings and fluorescent colors. Together with the deceptively real mobility of the artificial bait fish according to the invention, such additional bait features guarantee reliable catchability of almost every fish species, especially the larger predatory fish.

An embodiment of the invention is explained in more detail below with reference to the schematic figures. It shows:

1 shows an artificial bait fish with a pulling element having two pulling ropes in section from the side and FIG. 2 shows this artificial bait fish in section from above and

3 shows an artificial bait fish with a pulling element having a deflected pulling rope in a section from above. In Figure 1, an artificial bait fish 1 is shown, which is composed of a bait fish body 2 and a tail fin 3. The term "caudal fin" is also intended to include a thickening section 4 after the narrowest point in the caudal fin 3. In the exemplary embodiment selected, both are made in one piece from an elastic, bite-resistant material, ie the interior of the bait fish 1 is also covered with the filled in elastic material.

In the interior of the baitfish body 2 there is also a housing 5 in which there is a drive 6 in the form of a controllable servo motor, control electronics 7 and a power supply 8 from a battery. It is shown schematically that a pulling element 9 can be actuated via the servo motor 6. For this purpose, this has a first and a second traction rope 10, 11, which are each guided on opposite flanks 12, 13 in the tail fin 3. There is a strut 14 to which the two pull cables 10, 11 engage. These are simply passed through the elastic material and wound in opposite directions on an axis of the servo motor 6 in a manner not shown. Through its controllable reversal of the direction of rotation, one and the other pulling rope is alternately tensioned and the tail fin 3 is moved back and forth. The tails thus produced appear to be deceptively real due to pauses of variable length and distance in the control and bring about the particularly good bait effect of the bait fish 1 according to the invention.

FIG. 2 shows the bait fish 1 described in FIG. 1 in section from above and requires no further explanation. It has identical reference numbers. The two traction cables 10, 11, the two opposite flanks 12, 13 and the strut 14 can be seen clearly here.

In FIG. 3, an artificial bait fish 1 is shown in section from above, in which a pulling element 9 is arranged, which has a single pulling rope 15. This is guided over two deflections 16, 17. Both ends of the pull rope 15 attack on the strut 14. This is connected to the drive 6 via an elastic rod 18, to which further frames 19 are fastened. These frames 19 also determine the outer shape of the bait fish 1.

Approximately in the middle of the pull rope 15, a fastening element 20 is arranged in the form of a simple slot, into which a rope guide 21 in the form of a small dome engages with an anti-slip device. The cable guide 21 is arranged on an eccentric disc 22, which is connected via a motor axis 23 to a simple DC motor as drive 6. The rotation of the motor 6 causes the cable guide 21 to move up and down, which alternately pulls the traction cable 15 back on the flanks 12, 13 and causes the tail movement. Here too, their lifelike nature can be improved by variable pauses in the control. This results in an artificial bait fish 1, which is of particularly simple construction and is extremely robust and nevertheless has optimal catchability, especially for. larger predatory fish, guaranteed.

For this 12 claims

Reference list

1 artificial bait fish

2 baitfish bodies

3 tail fin

4 thickening section

5 housing

6 servo motor

7 control electronics

8 energy supply

9 tension element

10 first pull rope

11 second pull rope

12 first edge

13 second flank

14 strut

15 single pull rope

16 first redirection

17 second deflection

18 elastic rod

19 frames

20 fastener

21 rope guide

22 eccentric disc

23 motor axis

Claims

claims

1. Artificial bait fish which, when baiting a fish, mimics the attracting movement of a live fish, with a movable tail fin firmly connected to the bait fish body, characterized in that the tail fin (3) has an interior on its two opposite flanks (12, 13 ) attacking tension element (9), which can be alternately tightened on the flank side via a drive (6), and that the drive (6) together with its energy supply (8) is arranged in the baitfish body (2).

2. Artificial bait fish according to claim 1, characterized in that the drive (6) can be controlled in a time-adjustable manner and the control electronics (7) are also arranged in the bait fish body (2).

3. Artificial bait fish according to claim 1 or 2, characterized in that between the two flanks (12, 13) a strut (14) is arranged at the level of the points of attack of the tension element (9).

4. Artificial bait fish according to claim 3, characterized in that the strut (14) is arranged on an elastic rod (18) which is connected to the housing of the drive (6).

5. Artificial bait fish according to claim 4, characterized in that the strut (14) together with other frames (19) of different widths, which are also connected to the elastic rod (18), define the outer shape of the tail fin (3).

6. Artificial bait fish according to one of claims 1 to 5, characterized in that the pulling element (9) has two pulling ropes (10, 11) which engage with their one ends at the ends of the strut (14) and with their other ends are wound on an axis of a direction-controllable servo motor as a drive (6) in opposite directions.

7. Artificial bait fish according to one of claims 1 to 5, characterized in that the pulling element (9) has a pulling rope (15) guided over two deflections (16, 17), the two ends of which engage at the ends of the strut (14) and which has a fastening element (20) between the two deflections (16, 17), into which a cable guide (21) engages, which is arranged on an eccentric disc (22) of a DC motor as the drive (6).

8. Artificial bait fish according to one of claims 1 to 5, characterized in that the pulling element (9) has a rigid rod which engages with one end at one end of the strut (14) and with its other end with an eccentric disc (22 ) a DC motor is connected as a drive (6).

9. Artificial bait fish according to one of the preceding claims 1 to 8, characterized in that the tail fin (3) consists of a bite-resistant, elastic material and is rigidly connected to the bait fish body (2).

10. Artificial bait fish according to claim 9, characterized in that the tail fin (3) is watertightly connected to the bait fish body (2).

11. Artificial bait fish according to claim 10, characterized in that the tail fin (3) and the bait fish body (2) are made in one piece from the same bite-resistant, elastic material.

12. Artificial bait fish according to one of the preceding claims 1 to 1 1, characterized in that it has further features for attracting a fish.

With this 2 sheet figures