SK126999A3 - Device for producing torque - 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

Torque generating device

Technical field

The invention relates to a torque generating device.

BACKGROUND OF THE INVENTION

Such devices are applicable in the prior art in many ways, in particular as drives in mechanical engineering and the like.

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SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION It is an object of the present invention to provide a further device of the above type which utilizes, in particular, buoyancy forces to generate torque.

This object is achieved by the development of the device according to the first claim.

According to the present invention, at least two bodies are connected to each other in such a way that they can perform a rotational movement in which one body moves in the direction of gravitational force and the other body moves in the opposite direction, each body changing its direction the volume such that the volume of the body or bodies moving in the direction of gravitational force is smaller than the volume of bodies moving in the opposite direction.

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The way in which the volume of each body is varied is that it increases when it moves downwards, which is, in other words, the movement in the direction * of gravitational force, and it changes to an upward movement, which is, in other words, an action against action. gravitational force, decreasing immediately after the body's movement again changes to a downward movement.

This alternating increase and decrease in the volume of the bodies as the direction of movement changes ensures that the bodies moving upward at any given time exhibit higher buoyancy due to their larger volume than the bodies moving downward. Thus, the rotational movement of these bodies is developed.

It is particularly advantageous if the two bodies which are connected to each other are designed such that, regardless of the alternating volume changes of the individual bodies, the total volume of all bodies is substantially constant.

Although the device according to the invention can in principle also operate with an unequal number of bodies, it is preferably provided that the bodies are placed in pairs opposite to each other on the opposite side to the rotational movement. This symmetrical positioning of the bodies in pairs advantageously guarantees uniform torque generation.

The device according to the invention can operate in any fluid which, due to practical changes in the volume of the bodies, brings a sufficiently high buoyancy increase to overcome at least the frictional forces acting in the device. Nevertheless, such a measure is taken to ensure that the bodies are

immersed in the liquid during at least a part of their rotary movement. Due to at least partial but preferably complete placement of the device in liquid, especially water, a relatively large increase in buoyancy can be achieved even with a relatively small volume change. For example, an increase in the volume of individual bodies by 1 dm ³ (1 liter) in each case results in an increase in buoyancy of 9.81 N (1 kp).

In particular, it is particularly advantageous if the individual bodies are connected to each other by means of a traction member which moves in a circular manner via at least one deflection device, the deflection device being provided with at least one deflection wheel which is located on the shaft from which it can be removed torque.

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In order to utilize as much as possible the uplift of the buoyancy to generate the torque, it is provided on each set of two bodies that each set of two bodies, which are mutually assigned as pairs, and preferably all bodies, have the same dimensions. In this way, the device in question can be kept totally balanced in terms of the mass forces acting on it.

In a particularly preferred embodiment of the present invention, each body is constructed as a piston-cylinder unit, wherein the piston is movable to its extended or retracted position by the mass applied thereto as a function of the directional orientation of the piston-cylinder unit relative to the gravitational force.

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In order to ensure for this location that the displacement of the piston, in particular its pulling motion, occurs solely on the basis of the mass applied thereto, the length l _{k of the} piston must satisfy the following equation:

l _k > h. (p _f / p _k ) where h - is the maximum depth of immersion of the body into the liquid, p _f - is the density of the liquid, and p _k - is the density of the piston material.

It is particularly advantageous if the individual piston and cylinder units are located such that each piston and cylinder unit is automatically transferred from its one position in which the piston is pulled out or retracted to its other position in the case of a change in direction of movement. retracted or withdrawn accordingly.

In another embodiment of the invention, the cylinder chambers of the individual piston and cylinder units are interconnected to allow fluid exchange, wherein the cylinder chambers are interconnected in a circular manner, preferably by a hose.

In this way, the fluid system in interconnected, which can be made by separate cylinder chambers, interacts with each other in that the pressure generated by retracting the piston that changes its movement downwardly can be discharged via a separate fluid system to the piston and cylinder unit. that changes its movement to an upward movement, the piston moving out to its extended position,

Thus, this additional pressure on the piston helps to move it to the extended position in order to increase the volume, while also compensating for friction losses.

The fluid used in the cylinder chambers may simply be air or other gas. However, it is also possible to use, for example, very light oil or similar liquids to liquids, which has the advantage that the pressure can be particularly well transmitted.

Overview of the drawings

The invention will be explained in more detail below with reference to an exemplary embodiment, the description of which will be given with reference to the accompanying drawings, in which:

FIG. 1 shows a very simplified schematic view of a device according to the invention, provided with a pair of bodies for generating a buoyancy difference;

Fig. 2a is a sectional view taken out;

shows a very simplified schematic piston and cylinder per unit, the piston of FIG. 2b shows a sectional view of the unit retracted; and a very simplified schematic piston and cylinder, the piston of FIG. 3 shows a very simplified schematic view of a device according to the invention, provided with a plurality of bodies for exerting a buoyancy difference, the bodies being located in pairs.

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In the drawings, the same identical parts which correspond to each other are indicated by the same reference numerals.

DETAILED DESCRIPTION OF THE INVENTION

As shown in FIG. 1, the torque generating device according to the present invention comprises a biasing device 10 of the traction member

11. to which two piston-cylinder units 12 are attached as a pair of bodies for generating a buoyancy difference.

it comprises a deflection shaft 14 of which

The deflection device 10 of the wheel 13, which is located, can be subjected to the torque generated by the device according to the invention. For example, a generator may be connected to the shaft 14 for producing electricity.

Depending on the pulling member 11 used, the gear wheel or the cable drum or the like can be used as the deflection wheel. Accordingly, the pulling member 11 can be configured accordingly as a chain, rope, toothed belt, pulling belt or the like.

In order to transmit forces acting on the piston and cylinder units 12 to the traction member 11, each piston and cylinder unit 12 is retained on the traction member 11 by means of fastening pins 15 or similar means located some distance in the longitudinal direction from the traction member 11.

As a result of this attachment of the piston and cylinder units 12 to the traction member 11, that is, as a result. Also, the fastening means located at a certain distance in the longitudinal direction on the pulling member 11 and thereby in the direction of movement of the piston and cylinder units 12, is achieved that the piston and cylinder units 12 maintain the same direction and orientation relative to the respective direction of movement during so that when the direction of movement is changed with respect to the force of gravity, the piston and cylinder units 12 automatically change their position relative to the force of gravity.

In order to connect the cylinder chambers 16 of the piston units 12 and the cylinders so that the components are connected to each other, there is a hose 17 or a similar fluid pipe member ¹ * ^1, which hose 17 is secured by means of the corresponding coupling and by means of the connections 19 to the cylinders 20 of the piston and cylinder units 12, so that this hose 17 is in fluid communication with the respective cylinder chambers 16.

As shown in detail in FIGS. 2a and FIG. 2b, the piston 21 is slidably disposed in each cylinder 20 such that when the cylinder 20 is positioned as shown in FIG. 2a, that is, with its open side facing downward, then the piston 21 is moved downward to its extended or extended position due to its own weight acting on it.

In order to prevent the piston 21 from falling out of the cylinder 20 during this displacement thereof, the cylinder 20 is provided, for example, with an inwardly facing flange 22 _f while the piston 21 is provided with an outwardly facing flange

23 which cooperates with said ¹ inwardly directed flange 22. Sealing means, not shown in detail in the figures, are provided on the flange 22 and which seal the cylinder chamber 16 in a gas-tight manner so as not to interfere substantially with the displacement movement of the piston 21; this to ensure that the medium surrounding the piston / cylinder unit 12 cannot penetrate into the cylinder chamber 16.

In the following description, it is contemplated that the entire device of the present invention is completely immersed in water and that the cylinder chambers 16, which are through the hose 17 and the fluid system, are filled to be equally utilized and other interconnected to form a separate air. Instead of water, a medium having a low viscosity and as high a density as possible can be used. If water is used, as envisaged in the present case, the oil as light as possible can be used instead of air to fill the cylinder chamber 16.

An essential factor in the choice of flow media for the device of the present invention is that the density of the medium disposed in the cylinder chambers 16 must be lower, preferably many times lower than the density of the medium surrounding the piston and cylinder units 12.

The density difference between air and water is large enough that the mass of air contained in the cylinder chambers 16 need not be fully taken into account in the following explanatory description of the present invention.

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In order to determine the resultant force Fp transmitted by the traction member 11 to the circumference of the deflection wheel 13 in order to exert a torque; the forces acting on the piston / cylinder units 12 must first be considered separately.

The piston-cylinder unit 12 shown on the left side of the illustration of FIG. 1, acts in addition to its weight C »! furthermore, buoyancy Ej (i i), produced by ambient water, which results in a significant reduction in mass G G. The magnitude of this buoyancy depends in a known manner on the volume Vj of the piston-cylinder unit 12 shown on the left side of the illustration of FIG. 1, and can be calculated based on the following equation:

F ^ (Vi) ⁼ 9 · Pf · V,

I ¹ i where g - represents gravitational acceleration,

Pf - represents the density of the medium surrounding the piston and cylinder units 12, which is, in other words, water.

Correspondingly, the piston / cylinder unit 12 shown on the right side of the illustration of FIG. 1, subjected not only to the mass G _r , but also to the buoyancy F _Ä (V _r ) which satisfies the following equation:

F _{R (In)} = g. p _f . V _r where

In _r - represents the volume of the piston and cylinder unit 12 on the right side, in other words, the volume of the piston and cylinder unit 12 when the piston 21 is retracted.

Taking into account the fact that the forces transmitted from the piston / cylinder unit 12 on the left and right

They also act on the pulling member 11 in opposite directions to

For the pulling member 11, the buoyancy in any case counteracting the force of gravity, the following equation can be obtained for the resulting force F _R :

^f R “ ^f A ⁽ⁱⁿ 1 ⁾ * ^ρ Α < ^ν Γ> + ^G r ^G 1

Using the above buoyancy equations, the following equation for the resulting force F _r can be obtained:

Fr = g. P _f · (V _x - V _r ) + (G _r - G ^)

If, as is preferably the subject matter of the present invention, the piston and cylinder units 12 are constructed in the same manner so that they have the same weight, then these weights interfere with each other and acting on the deflection wheel 13 the resulting force Er to generate torque. the volume difference of the shaft 14 then only depends on a V = ν _χ - V _r between the piston and cylinder units 12. In the case of a cylindrical piston 21, the volume difference a V corresponds to the product of the piston stroke 1 _h and the cross-sectional area of the piston.

For the resulting force F _{R the} following equation can be used:

^f r - 9 · Pf · ^x h ^A k

To ensure that the piston 21 can be moved to its extended position against the force exerted on its free surface 21 *. which is the upward force in the illustration of FIG. 2a, which is exerted as a result of the water pressure applied in each case, the length l _{k of the} piston is preferably chosen to satisfy the following equation:

l _k > h. (P _f / P _a) where: h - is the maximum possible depth of immersion unit 12 and the cylinder piston, and thus the piston 21, in other words the distance between the lowest position of the free surface area 21 'of the piston 21 and the water surface, •.

p _k - represents the density of the piston material.

The operation of the apparatus of the present invention will now be described in more detail with reference to the illustration of FIG. 3, showing an exemplary embodiment of the present invention, wherein the present apparatus is provided with fourteen piston and cylinder units 12 which are in each case placed in pairs with each other. In addition to the upper deflection device 10, the latter is also provided with a lower deflection device 13 with a deflection wheel 33, which is located on the lower shaft 34.

As can be seen in FIG. 3, each of the six left-hand side piston and cylinder units 12 has a volume that is greater by _A V - v _x - v _r - 1 _h . A _k

As well as the volume of the piston and cylinder units 12 located on the right side, since in the present case the pistons 21 are in their extended position.

As a result, the resulting force F _R acting on the traction member 11, unless we consider friction losses and other losses is equal to:

F _r = 6. g. p _f . and in

This resulting force F _R causes the piston and cylinder units 12 to perform a rotational movement, in which case the piston 21 of each piston and cylinder unit 12, which passes from the upwardly moving lava side to the downwardly moving right side, is then self-pushed. as a result of the weight applied thereto into the cylinder 20 in order to reduce the volume.

At the same time, the piston-cylinder unit 12.2b in the region of the lower deflection device 30 passes from a downward movement on the right side to an upward movement on the left side, the piston 21 moving outwardly from the cylinder 20 to increase the volume due to the weight against the water pressure prevailing in this area.

Because each set of two piston and cylinder units 12 is allocated to each other as a pair, so that they are positioned relative to each other relative to the rotational movement, such as the upper piston and cylinder units 12a and the lower piston and cylinder units 12.1b or the units 12.2aa. 12.2b of the pistons and cylinders, the piston 21 being pushed in any case, in other words, by a change from the position of the piston and cylinder unit 12.1a to the unit position; and

12.2a of the piston and cylinder while the corresponding movement from the position of the piston and cylinder unit 12.1b to the position of the piston and cylinder unit 12.2b moves the piston outwards.

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Due to the compression of the air volume in the cylinder chamber 16 of the piston unit 12.2a, which causes an increase in air pressure in a separate system, the piston 21 in the corresponding opposite piston and cylinder unit 12.2b is assisted.

Assuming that, for example, steel having a density is used as the material of the piston per piston / cylinder unit 12

7.87 kg / dm ³ , with the device positioned at its lowest point about 2 m deep in the water, a piston length lc of about 25 cm is required.

If the piston is used appropriately,

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having a diameter w of, for example, -22 cm and a required length of 25 cm, capable of stroking a piston of 20 cm, a volume change of α of about 4 dm ³ is achieved, resulting in buoyancy of about 40 cm N (equivalent to four kilograms of compressed water).

Of the six such piston and cylinder units, it is then possible to obtain a resultant force F _R of 235 N which, depending on the diameter of the deflection wheel 13, generates a corresponding torque on the shaft 14 which can be used to drive the generator to generate electricity.

By suitably selecting the materials and the respective dimensions of the individual components of the device according to the invention, it is possible in a simple manner to obtain torques in a very wide range.

Claims (12)

PATENT CLAIMS A torque generating device (1) characterized in that it is provided with at least two bodies (12) which are connected to each other in such a way that they can perform a rotational movement in which one body (12) moves in the direction of gravity and the second body (12) moves in the opposite direction, each body (12) changing its volume when changing the direction of its movement such that the volume of the body or bodies (12) moving in the direction of gravity is less than the volume bodies (12) moving in the opposite direction. Device according to claim 1, characterized in that the two bodies (12) connected to each other are designed such that, regardless of the alternating volume changes of the individual bodies (12), the total volume of all the bodies (12) is substantially constant. Device according to claim 1 or 2, characterized in that the bodies (12) are arranged in pairs with respect to each other on opposite sides to the rotational movement. Device according to one of claims 1, 2 or 3, characterized in that the bodies (12) are immersed in the liquid for at least part of their rotary movement. Device according to one of the preceding claims, characterized in that the individual bodies (12) are connected to each other by means of a traction member (11) which moves in a circular manner through at least one deflection device (10). Apparatus according to claim 5, characterized in that the deflection device (10) is equipped with a biasing device at least one deflection wheel (13), which is _t arranged on the shaft (14), from which can be taken off torque. Device according to one of the preceding claims, characterized in that each set of two bodies (12) which are mutually associated as pairs, and preferably all the bodies (12), have the same dimensions. Apparatus according to one of the preceding claims, characterized in that each body is constructed as a piston-cylinder unit (12), wherein the piston (21) is movable to its extended or retracted position by means of the mass applied thereto as a function of directional orientation the piston / cylinder unit (12) relative to the gravitational force. • Device according to claim 8, characterized in that the length (1 ^) of the piston complies with the following equation: l _k > h. (Pf / Pfc) where h - is the maximum immersion depth of the body (12) in the liquid, Pf - is the density of the liquid, and p - is the density of the piston material. Device according to claim 8 or 9, characterized in that each piston-cylinder unit (12) is automatically transferred from its one position in which the piston (21) is pulled out or retracted to its other position in the event of a change in direction of movement. in which the piston (21) is respectively retracted or withdrawn. Apparatus according to claim 8 or 10, characterized in that the cylinder chambers (16) of the individual piston-cylinder units (12) are interconnected to allow fluid exchange. Device according to claim 11, characterized in that the cylinder chambers (16) are interconnected in a circular manner, preferably by means of a hose (17).