LT4672B - Lift motor - Google Patents

Abstract

The invention relates to a device for producing torque, comprising at least two bodies (12) which are coupled to each other in such a way that they perform a rotational movement, whereby one (12) of the bodies moves in the direction of gravity and the other body moves in the opposite direction. Each body (12) changes its volume when the direction of movement is changed. The volume of the body (12) which moves in the direction of gravity is smaller than the body (12) moving in the opposite direction.

Description

The invention relates to torque generating devices.

Such devices are often required in the art as machine gears and the like.

Known torque generating device having two gears spaced one above the other and surrounded by a continuous member on which bell-shaped vessels are mounted. The lower gear is embedded in a fluid and is equipped with a source of compressed air from which vented air displaces the fluid from said downwardly facing vessels, forcing the vessels to rise upward while rotating the cogwheels (DE patent 2 408 682, F30B 17). / 00.

The closest embodiment of the present invention is a device having two flywheels mounted in fluid on horizontal axes, connected by a flexible closed coupling member surrounding them, on the outer surface of which are fixedly arranged chambers having openings in the walls facing the longitudinal axis of the coupling. rods with buoys on one end and weights on the other end.

(EP Application No. 0041681, F03B 17/04).

The disadvantage of this unit is that it cannot generate torque or be a power source, because due to its vertical symmetry, the fluid ejection forces acting on the buoys and the weights of the weights balance and do not create the torque that ensures flywheel rotation.

The object of the invention is to provide a torque generating device using buoyancy forces to generate torque.

This object is achieved by a device according to claim 1 of the invention.

For this purpose, at least two bodies are connected to each other in such a way that they can perform a rotational motion in which one body moves in the direction of gravity and the other in the opposite direction when the body changes its volume so that the body or bodies the volume moving in the direction of gravity is smaller than the volume of bodies moving in the opposite direction.

The principle of changing the volume of each body is that it increases when its motion is downward, in other words when its motion is directed by the force of gravity, it changes to an upward motion, in other words, to a motion opposite to gravity. while it begins to decrease as body motion changes again to downward motion. This alternating increase and decrease in body volume as the direction of movement changes ensures that bodies move up at any given moment, since their greater volume experiences greater torque than moving bodies down. In this way, the bodies create a rotating motion.

It is particularly useful if two bodies joined together are so constructed that, despite alternating changes in the volume of individual bodies, the total volume of all bodies is substantially constant,

Although the device according to the invention can also essentially work with an odd number of bodies, it has been found to be preferable for the bodies to be arranged in pairs against each other for a corresponding rotational movement. Particularly constant torque generation is guaranteed by such symmetrical arrangement of the nodes in pairs.

In principle, the device according to the invention can work with any fluid suitable for use in changing the volume of bodies, providing a sufficiently high buoyancy increase, at least by overcoming the frictional forces acting on the device. However, it is better to have the bodies immersed in the liquid for at least part of the rotational movement time. Therefore, the same relatively large increase in buoyancy can be achieved as a detached but perfectly appropriate installation of a device in a liquid such as water, even with relatively small volume changes. For example, an increase in individual body volumes of 1 dm ³ (1 1) increases buoyancy in each case by 9.81.N (1 kp).

Particularly rational, if the individual bodies are connected to each other by a tensile member which moves in a ring through at least one guide means, the guide means has at least one guide gear mounted on an axle from which the torque can be removed.

In order to use as much buoyancy difference as possible for generating torque supplied by each set of two bodies assigned to each other as a pair, it is preferable that all bodies have the same dimensions. In this way the device can be in equilibrium with respect to the operating weights.

In a particular embodiment of the invention, each body is constructed as a piston-cylinder assembly, the piston being movable into its extended and retracted position under gravity as a function of the orientation of the piston-cylinder assembly depending on the force of gravity.

In order to guarantee the displacement of the piston in this device, and in particular its displacement movement, it can only be based on the effect of weight on it, the length of the piston, corresponding to the following equation:

l _k 2 h · p _f p _k where h is the maximum immersion depth of the body, p _f is the density of the fluid and pj. is the density of the piston material.

It is particularly useful if the individual piston and cylinder assemblies are arranged such that each piston and cylinder assembly is automatically moved from one position to another when the piston is respectively retracted or extended.

In another embodiment of the invention, wherein the cylinder chambers of the individual piston and barrel assemblies are interconnected to allow fluid exchange, the cylinder chambers are connected to each other by a hose.

In this way, the self-contained fluid system may be formed in cylinder chambers connected to one another, the operation of which is such that the pressure created by pushing the piston changes into downward motion can be exerted through the piston and cylinder assembly piston through the self-contained fluid system. an upward movement in which the piston moves to its extended position such that additional pressure assists its movement to the extended position to increase the volume and compensate for any frictional losses.

The fluid used in the cylinder chambers may be simply air or other gases; however, it is also possible to use, for example, very light petroleum products or simple hydraulic fluid, which has the advantage that the pressure can be transmitted exceptionally well.

The invention is illustrated by way of example with reference to the following drawings, in which:

FIG. 1 is a highly simplified schematic view of a device according to the invention having a pair of bodies generating a buoyancy difference,

FIG. Fig. 2a is a simplified schematic view of the piston and cylinder assembly with the piston extended,

FIG. Figure 2b is a simplified schematic view of the piston and cylinder assembly with the piston retracted, and

FIG. Figure 3 is a simplified schematic view of a device according to the invention with a plurality of buoyancy difference generating bodies arranged in pairs.

In the drawing figures, the details corresponding to each other are marked with the same numbers.

As shown in FIG. 1, the torque generating device according to the invention comprises a pivoting device 1 for a tensile element 2 to which piston and barrel assemblies 3 are attached as a pair of bodies which create a buoyancy difference. The guide device 1 has a guide wheel 4, which is mounted on an axis 5, from which the torque generated by the device according to the invention can be removed. For example, an electric generator can be connected to axis 5,

As a guide wheel 4, depending on the tensioning element 2 used, a gear or a cable drum or the like may be used, the tensioning element 2 may be constructed as a chain, a cable, a toothed belt, a tensioning belt and the like.

Each of the piston and cylinder assemblies 3 is held on the tension member 2 by screws 6 or similarly spaced apart by a longitudinal drop of the tensile member 2 to transmit forces acting on the piston and barrel assemblies 3 to the tensile member 2.

Because of the attachment of such piston and cylinder assemblies 3 to the tensile means 2, this means that the spacer means are spaced apart in the longitudinal direction and in the same direction of movement of the piston and cylinder assemblies 3, which means that the piston and and the position relative to the corresponding direction of movement throughout the rotational movement so that when the direction of motion changes with the corresponding force of gravity, they automatically change their position due to gravity.

In order to connect the piston and cylinder assembly 3 cylinder chambers 7 to one another so that the latter are in communication with one another, the hose 8 or the like is provided as a fluid supply line and is secured to the piston and cylinder assembly 3 cylinders 9 through respective connections the part 10 and the connecting members 11 so that the hose 8 is fluidly connected to the respective cylinder chambers 7.

As detailed in the drawings in FIG. 2a and FIG. The piston 12 of the 2b is slidably mounted on each cylinder 9 such that, if the cylinders are mounted with an open end facing downwardly as shown in Figure 2a, due to the weight acting on it, it slides downward into its immersion or extended position. In order for the piston 12 to fall out of the cylinder 9, the cylinder 9 has, for example, an inwardly directed flange 13, while the piston 12 raises an outwardly facing flange 14 interacting with the aforementioned. The sealing means provided on the flange 13, which is not shown in detail, closes the barrel chamber 7 so as to prevent gas but substantially impedes the displacement movement of the piston 12 to ensure that the medium surrounding the piston and cylinder assembly 3 does not enter the cylinder.

Thus, it is believed that the device according to the invention is fully immersed in water and that the cylinder chambers 7, which are connected to each other by a hose 8 and form an independent fluid medium system, are filled with air. Instead of air, another medium with a lower viscosity and highest possible density may be used. When using water as above, the lightest possible oil may be used as a liquid in place of the air cylinder chamber 7. As a necessary factor for selecting the fluid medium for the devices according to the invention, the density of the medium for the barrel chambers 7 is lower, preferably very low, relative to the medium surrounding the piston and barrel assemblies 3.

The difference in density between air and water is so great that the mass of air contained in the barrel chambers 7 can be completely ignored in the following description of the invention.

To determine the displacement force Fr transmitted through the tension member 2 to the periphery of the guide wheel 4 to generate torque, the forces acting on the piston and cylinder assemblies 3 will first be evaluated separately. When the surrounding water acts on the piston and cylinder assembly 3 as shown in FIG. 1 on the left, in addition to its weight Gi, creates a buoyancy Fa (Vi) which causes an apparent loss of weight Gi. The buoyancy is known to depend on the piston and cylinder assembly 3 shown in FIG. 1 to the left, volume Vi and calculated by the equation F _A (Vi) = g -pr -Vi. Here g is the acceleration dependent on gravity, and pr is the density of the medium surrounding the piston and cylinder assemblies 3, or in other words water.

Accordingly, the piston and cylinder assembly 3 shown in FIG. 1 to the right is dependent not only on the action of gravity Gr on it, but also on the buoyancy Fa / Vt) which satisfies the equation pA (Vr) = g -pi · Vr, Vr is the piston and cylinder assembly 3 shown on the right , the volume, in other words, the volume of piston and cylinder assembly 3 when piston 12 is retracted.

Given that the forces transmitted from the left and right piston and cylinder assemblies 3 to the tensile member 2 and the buoyancy in each case act opposite to the force of gravity, the resulting force Fr applies the following equation:

Fr = Fa (Vi) -Fa (Vi) + Gr - Gi

From the above buoyancy equations, the equation for the displacement force Fr is given by:

Fr = g -pt - (Vi - Vr) + (Gr - Gi)

Then, as better suggested in the present invention, the piston and cylinder assemblies 3 are designed such that they have the same weight, the weights offset each other, and then a repulsive force Fr acting on the rotating wheel 4 to create a torque on the axis 5. , depends only on the difference Δ V = Vi - Vr between the volumes of the two piston and cylinder units 3. In the case of the piston 12 cylindrical, the volume difference Δ V depends on the product piston stroke lh and the piston cross-sectional area Ak. The resulting equation Fr then applies to the equation below:

Fr - g · ρί -lh 'Ai

In order to guarantee that the piston 12 can be pushed into its elongated position before the force is applied to its free surface area 12 ', FIG. 2a the upward force exerted by the water pressure in each case, the piston length k being best chosen to satisfy the following equation:

Ik b h pt / pk

In this equation, h is the maximum possible plunging depth of the piston and cylinder assembly 3, and hence, the piston 12, i.e. the distance between the lowest position of the free surface area 12 'of the piston 12 and the water surface, and pv is the piston material.

The operation of the device according to the invention will now be explained in detail with reference to FIG. 3 illustrates an embodiment of the invention having a plunger and a cylinder assembly 3, each pair-mounted. In addition to the upper pivoting device 1, this device has a lower pivoting device 4 with a pivoting wheel 15 mounted on the lower axis 16.

As can be seen in the drawing of FIG. 3, the six piston and barrel assemblies 3 mounted on the left side each have a volume greater than AV = Vi - V _r = lh -Ak than the piston and cylinder assemblies 3 mounted on the right side, since the pistons 12 are in an extended position. As a result, the resistive force Fr acting on the tensile element 2, despite friction and other losses, is 6 · gp; -AV. This force Fr causes the piston and barrel assemblies 3 to perform a rotational movement in which the piston 12 of each piston and barrel assembly 3.2a, whose node changes from the upward movement to the downward movement on the right, is displaced by the weight acting on it in the barrel. 9 to reduce volume. At the same time, the piston and cylinder assembly 3.2b in the lower rotation device 17 region changes from downward movement from the right to upward movement on the left, pushing the piston 12 out of the cylinder 9 by increasing its volume under gravity against the water pressure in this area.

Because each of the two sets of piston and cylinder assemblies 3 are assigned to each other as pairs, they are mounted opposite to each other with respect to rotational movement, such as the top and bottom piston and cylinder assemblies 3.1a and 3.1b or the piston and cylinder assemblies 3.2 a and 3.2b, the piston 12 is pushed each time, that is, when the piston and cylinder assembly 3.1a changes to the piston and cylinder assembly 3.2a, when the piston and cylinder assembly 3.1b changes to the piston and cylinder assembly 3.2b respectively is dislocated. Due to the compression of the air volume in the piston and cylinder assembly 3.2a in the cylinder chamber 16, the air pressure inside the separate system increases, resulting in the piston 12 being pushed out in the opposite piston and cylinder assembly 3.2b respectively.

Assuming, for example, that the steel having a density of 7.87 kg / dnP is the material used for the piston 9 of the piston and cylinder assembly 3, the unit is mounted so that its lowest point is in water at a depth of about 2 m and piston height Ik is necessarily about 25 cm. If, for example, the piston has a diameter of, for example, 22 cm and a required length of 25 cm and a stroke of 20 cm can be performed, a volumetric change of AV of about 4 dm- is obtained, which affects its buoyancy by about 40 N (respectively ), In this case, the six such piston and cylinder assemblies will produce a refractive force Fr equal to 235 N, which, depending on the diameter of the rotating wheel 4, produces a corresponding torque on the axle 5 which can be used to operate the power generator.

With proper selection of materials and appropriate arrangement of the individual units of the device according to the invention, a wide range of torques can be created in a simple manner.

Claims (12)

DEFINITION OF INVENTION A torque generating device comprising at least two bodies (3) connected to one another in such a way that they can perform a rotational movement, characterized in that one body (3) moves in the direction of gravity and the other in the opposite direction. , each body (3), when reversing the direction of movement, changes its volume so that the volume of the body or bodies (3) moving in the direction of gravity is less than that of the bodies (3) moving in the opposite direction. Device according to Claim 1, characterized in that the two bodies (3) connected to each other are designed such that, despite changes in the volume of the individual bodies (3), the total volume of all the bodies (3) is substantially constant. 3. A device according to claim 1 or 2, wherein said device is different. that the two bodies (3) are arranged in pairs relative to each other in rotational motion. Device according to claim 1, 2 or 3, characterized in that the two bodies (3) are immersed in the liquid for at least part of their rotational movement time. Device according to at least one of the preceding claims, characterized in that the individual bodies (3) are connected to each other by a tensile element (2) which moves in a ring through at least one rotating device (1). 6. A device according to claim 5, characterized in that the rotation device (1) has at least one rotation wheel (4) mounted on an axle (5) from which the torque can be removed. A device according to at least one of the preceding claims, characterized in that. so that each set of two bodies (3) assigned to each other as a pair of bodies (3) preferably has the same dimensions. Device according to at least one of the preceding claims, characterized in that each body is constructed as a piston-barrel assembly (3), the piston (12) being moved to its extended or retracted position by the action of gravity as a function of thrust, respectively oriented to the piston and cylinder assembly (3). 9. A device according to claim 8, wherein the piston length (Ik) satisfies the following equation: k ž h · pf / pk where h is the maximum immersion depth of the body (3), pt is the density of the liquid and pk is the density of the piston material. Apparatus according to claim 8 or 9, characterized in that the piston and cylinder assembly (3) automatically changes from one position in which the piston (12) is pushed or pushed to another position in which the piston (12) is displaced. ) is pushed or pushed respectively. 11. Apparatus according to claim 8 or 10, characterized in that the cylindrical chambers (7) of the individual piston and cylinder assemblies (3) are connected to each other to allow fluid exchange. 12. Apparatus according to claim 11, characterized in that the cylinder chambers (7) are connected to one another by a ring, preferably through a hose (8).