DE9304916U1 - Counterforce drive device - Google Patents

Description

Counterforce drive device

The invention relates to a counterforce drive device, which uses the energy generated by utilizing the gravity and buoyancy properties of hollow bodies in a liquid column in the form of a movement of the hollow body in the direction of the buoyancy as a drive to convert this linear movement into a rotating movement.

Counterforce drives are widely known. For example, when lifting sunken ships, hollow bodies are used in such a way that these hollow bodies are attached underwater to the ship to be lifted, possibly filled with propellant gas and are thus used as counterforce lifting or propulsion devices. The disadvantage of this solution is that it takes a lot of effort and a lot of energy to get these hollow bodies to the location so that they can then act as a propulsion device or buoyancy device. The energy present here in the form of a movement in the direction of the buoyancy acts linearly. A conversion of this linear movement into a rotating movement during the buoyancy movement of the hollow body is not possible here.

Solutions in the form of devices that are more energy-efficient when used to lift ships, such as using inflatable bodies as propulsion devices or buoyancy devices under water, have the disadvantage that although they release the energy they receive from the buoyancy to lift ships, they can only convert this energy into a linear movement and not into a rotating movement.

Furthermore, solutions are known that open and close valves by exploiting the gravitational and buoyancy properties of hollow bodies. The energy generated here in the form of a linear movement is only converted into linear movement. A conversion of this linear movement during the exploitation of, for example, the buoyancy of the hollow body into a rotating movement is not possible here either.

In order to eliminate the above-mentioned disadvantages of the prior art, the object of the invention is to create a counterforce drive device which uses the energy generated by utilizing the gravity and buoyancy properties of hollow bodies in a liquid column in the form of a movement of the hollow body in the direction of the buoyancy as a drive for converting this linear movement into a rotating movement.

According to the invention, the object is achieved by the features specified in claim 1.

The advantages of the invention are that the use of low energy converts energy in the form of a linear movement, which is generated by the buoyancy of hollow bodies in a liquid column, into energy in the form of a rotating movement. Furthermore, this device is environmentally friendly, low-maintenance and simple to set up. It is therefore inexpensive, can be used industrially and does not place any demands on the installation site and does not require any additional manpower. In addition, this device is suitable for the direct circulation of waste water.

Currently, solutions are required that focus on improving the energy conversion process and

energy use, reducing environmental impact, improving maintenance, etc. The counterforce drive device according to the invention comes closest to solving these problems and is the most economical solution to date, also because this device can be used for laboratory purposes and for industry. There are no limitations in terms of size.

For clarity, the counterforce drive device shown in Figure 1 is shown using a liquid container with a collecting pipe as a storage space for the hollow bodies and a drive element in the form of an endless conveyor belt that is driven by the hollow bodies. However, it should be emphasized that the structural solution shown here of the liquid container, the collecting pipe as a storage space for the hollow bodies and the drive element can be replaced by other means that solve the same problem and thus have the same effect.

The counterforce drive device consists of a container 1 that is filled with a liquid 2. In the container 1, a drive element 3 is provided with drivers 4, arranged so that this drive element 3 faces a storage space 5 and is spaced from the intermediate container wall 6 by the length of the drivers 4 plus their slip, whereby the drivers 4 are designed so that they receive hollow bodies 7 on this container wall 6 through the side of the drive element 3 facing the container wall 6. The drive element 3 is endless and is movably mounted by the lower deflection element 8 and the upper deflection element 9. A movable flap 10 is arranged at the upper end of the container wall 6, which is directly opposite the storage space 5.

The storage space 5 has a cross-section that is larger than the diameter of the hollow bodies 7 to such an extent that the hollow bodies 7 can move into this storage space 5 under their own weight without friction losses.

At the lower end of the storage space 5, a feeding device 11 is installed in such a way that it creates a connection from the storage space 5 to the container 1, by means of which the hollow bodies 7 pass from the container 1. The feeding device 11 consists of a piston 12, whereby the piston 12 is operatively connected to a drive 13. The feeding device 11 also consists of an inlet opening 14 with the inlet closure 15, an outlet opening 16 with the outlet closure 17 and an ejection opening 18 with the ejection opening valve.
19.

The function of the counterforce drive device is characterized in that the hollow bodies 7 are individually brought by means of a feed device 11 from the storage chamber 5 via the inlet opening 14 by means of a piston 12 to the outlet opening 16, whereby the piston 12 is driven by the drive 13. The drive 13 controls the inlet closure 15 and the outlet closure 17 according to the piston position via a control system. If the piston 12 is in position A, the outlet opening 16 is closed by the outlet closure 17 and the squeezing opening valve 19 is automatically closed by the liquid 2 above it (by the liquid level). The inlet opening 14, however, is free due to the open inlet closure 15 and a hollow body 7 is positioned in front of the piston 12. At the moment of the movement of the piston 12 from position A towards position B, the inlet closure 15 closes the

Inlet opening 14. If the piston 12 reaches position B, the hollow body 7 is located under the outlet opening 16, which is then opened by the outlet closure 17. The liquid 2 thus penetrates (partially) into the space between position B and position C of the piston 12 and the hollow body 7 is buoyant and reaches a driver 4 located above it. If the hollow body 7 has left the outlet opening 16, this is closed again and the piston 12 moves in the direction of position C, whereby the liquid 2 located in front of the piston 12 is (partially) pressed through the opening discharge opening valve 19 and the discharge opening 18 into the container 1. Then the piston 12 moves back to position A, whereby the squeezing opening valve 19 automatically closes the squeezing opening due to the pressure of the liquid level above it and the negative pressure that arises in the space itself, and the inlet opening 14 is opened up for a new hollow body 7, and the above-mentioned process repeats itself. In the meantime, the hollow body 7 first introduced into the container 1 has set the drive element 3 in motion via the driver 4 located there through its buoyancy. Hollow bodies 7 subsequently introduced into the container 1 reinforce the linear movement of the drive element 3 through additional buoyancy. Due to the fact that the drive element 3 is guided endlessly over the upper deflection element 9 and the lower deflection element 8, the linear movement is converted into a rotating movement of the upper and lower deflection elements 9; 8. If all the drivers 4 of the conveying element 3 located between the outlet opening 16 and the flap 10 are covered with hollow bodies 7, the optimum linear and thus converted rotary movement is achieved and a constant power transmission is ensured, which lasts as long as all the drivers 4, as previously stated, are filled with

hollow bodies 7 are occupied. This is also the point in time at which additional devices to be driven by this counterforce drive device can be switched on, which can be driven by a direct connection to one of the two deflection elements 8; 9 or to both deflection elements 8; 9, but preferably to the upper deflection element 9.

Each hollow body 7 arriving below the flap 10 is pressed by the flap onto the upper side of the carrier 4 located underneath and the upward movement of this carrier 4 then lifts the flap 10 by means of the hollow body 7, this hollow body 7 leaves the liquid 2 and remains on the upper side of the carrier 4 located underneath (due to its own weight and no longer effective buoyancy). After the hollow body 7 leaves the area of the flap 10, the flap 10 returns to its original position and the hollow body 7 slides through the upper side of the underlying driver 4 and its inclined surface, released on this surface and then on the upper side of the flap 10 into the storage space 5. It should also be noted that the piston 12 is provided with an ejection channel 20, which completely absorbs the remaining liquid from the feed device 11 when the piston 12 is in position C and expels it via the ejection opening 18. The drivers 4 are provided with a locking unit 21. At the moment of deflection of the respective driver 4 on the upper deflection element 9, the driver 4 falls to the left onto the drive element 3 and the locking unit 21 connects to the counter-lock 22. During the deflection movement of the driver 4 on the lower deflection element 8, the locking of the driver 4 on the drive element 3 is released by an unlocking element 23, which is arranged on the circumference of the lower deflection device 8, and

the unlocked driver 4, after being deflected and then moving upwards, takes up the position for receiving a hollow body 7 again by means of its own weight. The hollow bodies 7 emerging from the outlet opening 16 are guided under the drivers 4 by means of a guide device 24. When the piston 12 takes up position B, the respective hollow body 7 is placed directly under the outlet opening 16 by a positioning unit 25 and, after the liquid 2 has entered the remaining space between position B and position C of the piston 12 of the feed device 11, it can reach through the outlet opening 16 via the guide device 24 under a driver 4 located above it by means of its buoyancy.

After the outlet opening 16 is sealed by the outlet closure 17, the piston 12 moves from position B to position C, whereby the positioning device is pressed into the recess 26 by the piston 12 and locked. At the moment when the piston 12 moves under the recess 26 during the backward movement, the positioning unit 25 is unlocked and, after the piston 12 leaves this area of the recess 26, it falls back into its starting position.

Reference symbols used

1 container

2 Liquid

3 Drive element 4 Driver

5 Storage room

6 Container wall

7 hollow bodies

8 lower deflection element 9 upper deflection element

10 flap

11 Feeding device

12 pistons

13 Drive

14 Inlet opening

15 Inlet closure

16 Outlet opening

17 Outlet cap

18 Pressing opening

19 Extrusion opening valve

20 Extrusion channel

21 Locking unit

22 Counter-locking

23 Release element 24 Guide device

25 Positioning unit

26 Recess with locking mechanism

^; Position of piston B \

Claims (1)

Claim for protection Counterforce drive device consisting of - a drive element (3) with drivers (4) which is endlessly mounted via an upper deflection element (9) and a lower deflection element (8), whereby the upper deflection element (9) and the lower deflection element (8) rotate around their central axis, whereby the drive element (3) is predominantly located and the lower deflection element (8) is located in a container (1) with liquid (2) and the upper deflection element (9) is arranged outside the container (1) with liquid (2), whereby the drivers (4) in the liquid (2) guide the hollow bodies (7) on their lower surface and after leaving the liquid (2) are located on the surface of the drivers (4) located underneath and after they have raised the flap (10) and this has tilted back into its starting position, on the surface of the flap (10), triggered by the inclination of the driver (4) located underneath into the storage space (5) roll off; and from - a feeding device (11) which is arranged below the storage space (5) and extends into the container (1) with liquid (2), which receives the hollow bodies (7) from the storage space (5), feeds them to the drivers (4) via the outlet opening (16) and the guide device (24), whereby the hollow bodies (7) enter the feeding device (11) under their own power after the inlet opening (14) is opened. HERE IS A PAGE DRAWING