NL9100597A - Wind energy harnessing balloon - which uses fabric helical aerofoils to rotate balloon about its longitudinal axis, thus turning electrical generator on top of mast - Google Patents

Abstract

A long, cylindrical, ligher-than-air balloon (C) has fastened on its surface a strip of fabric (D) wound in a helix. This is restrained by cables (E) to catch the wind and stand away from the balloon. The wind causes the balloon to rotate about its longitudinal axis, turning the electrical generator (A), which is pivoted on top of the mast (B). One variant of this method moors the balloon with its longitudinal axis vertical. Sails catch the wind on one side and collapse on the other side to produce a turning moment.

Description

Short designation: Balloon wind motor

The invention relates to a system for collecting wind energy with the aid of balloons.

The difference with existing systems for collecting wind energy is that it is possible to collect much larger amounts of wind energy at relatively low costs by wrapping an elongated, round balloon with a spiral tarpaulin that is held in place with ropes.

The balloons are filled with a gas lighter than air.

As a result, the whole floats in the air and requires relatively very few construction materials to function very low-friction.

I also offer some alternative balloon systems in which the tarpaulin is attached in the longitudinal direction of the balloon, the balloon with the longitudinal axis is transverse to the wind and the tarpaulins concerned alternately catch wind and lie flat against the balloon.

All these systems make it possible to capture much larger amounts of wind energy than existing systems at a relatively much lower price and thus offer a real opportunity to replace existing oil-fired or nuclear power plants entirely with wind power plants. In fact, the amount of energy that can be extracted with these systems is so great that one can store surpluses of energy by pumping large amounts of water into higher basins, from which it is possible to draw in windless hours. Moreover, due to the nature of the system, it is possible to build power stations in many more places, so that the electricity transmission system is less burdened.

Descriptions and drawings of the different systems System W-A:

Figure 1 shows the side view of system W-A.

A = rotating dynamo B = mast C = with gas, lighter than air, filled balloon, round and elongated.

D = spiral cloth attached to the balloon as a thread, as it were wrapped around it.

Figure 2 shows the rear view of system W-A.

Figure 3 shows the cross section of system W-A and shows the slightly bent position of spiral cloth D so that it catches wind by ropes, E and remains from balloon C.

Figure 3 shows the possibility of attaching air chamber F behind balloon C, which can further promote the effect of cloth D by the flow of air through the holes at cloth D. System W-A works as follows:

An air stream lays balloon C with its head at dynamo A in the wind. Then the airflow exerts a force on cloth D which, due to its inclination relative to balloon C, will cause the latter to rotate in the longitudinal direction. This rotary movement is transferred to dynamo A or other device that can process energy. Cloth D cannot blow over because it is stopped by multiple lines E. Lines E can be flexible to absorb sudden gusts of wind. Because the balloon is filled with the help of helium gas, it will not hang on the ground when there is no wind.

System W-B:

System W-B is similar to system W-A, the differences are: 1 Dynamo A is on the ground and can be rotated both horizontally and vertically.

2 Cable G transfers the rotary motion from balloon C to dynamo A.

3 Helium balloon H holds cable G in the air in such a way that balloon C (which here does not contain helium but air in the rear section) is higher with the head than with the tail. As a result, a horizontal air flow under balloon C causes an upward force (in addition to its own upward force from the helium) that keeps the whole unit high up in the air, even in strong winds.

System W-C:

In this embodiment, the gas-filled balloon itself is spirally shaped and exhibits a similar wind response as described in W-A.

System W-D:

In this embodiment, balloon C has been replaced by multiple cone-shaped balloons wrapped with spiral cloth as described under W-A. For example, the spiral cloths are less in each other's wind shelter. The cones are attached to rope G which transports the turning force back to the ground. Balloon H at the end of rope G keeps everything in the air.

System W-E:

The wind blows against vertical balloon C. On one side of this balloon, valves D are blown open and closed on the other side. Valves are limited in their movement by ropes E. Balloon turns around and drives dynamo A on foot B, for example.

System W-F:

Two giant so-called car inner tubes C are fastened together. In the middle between the belts is a pulley with rope G running around it with a double stroke. C hangs filled with helium in the air and drives the dynamo A via rope G, which this time loops to and from Earth.

System W-G:

Figure a shows a number of balloons placed one above the other, which are kept at a distance from each other by ropes T so that space remains between the balloons for the wind flap to be blown open through the relevant opening in the blown state. All balloons together form a wind dam which increases the wind force on the openings between the balloons. Balloons transfer the resulting rotary movement to ropes G that are wrapped around pulley U with a double stroke and thus drive both dynamos A via the underlying balloons. . Dynamos A are on rotating rail R.

The top balloon is attached to the outer rail Q with rope S and rolling attachment point P. For example, the wind shield of balloons is always bent forward in the wind and can be the two circles of rail (type of curtain rail) always follow the wind direction. Wind flaps D open when they catch wind from the front and close against the wind when turning back. In addition to the buoyancy of e.g. helium with which the balloons are filled, the entire constellation is also blown up by the wind.

System W-H:

This system consists of a long loop-shaped cable that runs through a series of balloons filled with helium and thereby keep the whole air. At the front of each balloon is a parachute that opens when carried by the wind and closes around the balloon when it is returned in reverse against the wind Figure 2 shows leg X anchored in the ground alternator J.

Axis I passes through the cross wheel over which cable E passes.

Conductors H lead the cable to a point where the cable is anchored by circlips F, i.e. on one of the 4 rods protruding from the cross wheel. As a result, the balloon itself remains untouched by the cross wheel. Leg X is rotatable so that the loop is always in the wind direction.

Figure 3 shows a rear view of the balloon surrounded by the parachute. K represents a type of bicycle inner tube which is wrapped around the cable in balloon B and is connected airtightly to balloon B. Parachutes are constructed in such a way that they are flipped up by the wind and cause an upward force.

System W-I:

Figure 1 shows alternator A, anchored to the ground on which shaft V is mounted vertically. Axis C has a frame of 2, 3 or 4 blades. There are vertically hinged doors in the frame that can close against the frame. When the wind blows from the front, the doors are blown shut. As soon as they have to move against the wind direction, they open up, lay in the wind in such a way that they generate minimal resistance and have closed again when they go with the wind again.

This system can be made very high by means of tension cables to the ground. The doors can be made of a very light and thin plastic.

System W-J:

In this case, a sailcloth thread C is wrapped around a rigid shaft or tube B, held by ropes D in such a position that the wind does not blow the "thread" against the shaft but leaves it almost perpendicular to it. See fig. 2.

The "screw thread" increases in diameter per turn.

System W-K:

This screw C makes only one 360 ° turn, held in place by ropes D.

Shaft B can be a hard, rigid material, but it can also be a cylindrical balloon. The end of this shaft is supported by rods G and wheel H, connected to shaft B by bearing F. Fig. 2 is a front view of the screw.

Fig. 3 is a front view of the support.

System W-L:

In Fig. 1, A is a kind of curtain rail that is anchored in a circular manner in the bottom. From center n.F cables run to the points E mounted on rail A which can move along rail A like a curtain rail.

The 3 points E are interconnected with struts that always keep them the same distance apart.

H is one of three sails hinged around cable B.

When the wind blows under side D, the sail rises into the air. Rope G in combination with sliding point F regulates that the sail H only rises so far that it still catches optimal wind.

When carried along by the wind, sail H then turns in the opposite direction and then folds horizontally again so that it moves against the wind with little resistance.

Fig. 2 is a side view of the high blown sail H held by rope G.

Fig. 3 shows the course against the wind.

Rail A can also be replaced by a "car inner tube"; 5. as described in system W-M and then function floating on the water.

The systems W-L and W-M also lend themselves upside down in the water to extract the energy from running water.

They could even be duplicated with a water system under water and a water system above water.

System W-M:

This system is a horizontally rotating windmill.

Fig. 1 shows the top view.

A is the pivot point of wheel E. C are the masts that are vertical on the horizontally rotating wheel E. A tarpaulin B is attached to each mast (as with a sailing boat), which is limited in its deflection by rope D. For example, most of the eight (or more or less) sails deliver a force that makes wheel E rotate.

Fig. 2 shows a front view. Behind the middle three masts C there is another mast. Wheel E can possibly. rotate on bearing F or on "car inner tube" G. In the latter case, such a mill can function floating on the water. This is shown in fig. 3. For example, on car inner tube G there are eight masts with sails. On shore H is dynamo K, driven by belt or rope L, which spans wheel G in V-shaped pulley slot.

M is a pile driven 0 into the bottom of the water.

Around M there is a wheel around which belt N turns. Belt N also spans wheel G. This way the whole is kept in place.

System W-N:

Fig. 1 represents a front view of a type of parachute, i.e. the side blown by the wind.

F and E are places ... where; the: desk of the parachute has been replaced by mesh or ropes perpendicular to the cloth. Air that is blown into the parachute by the wind escapes through these openings.

Because side A is further back as side D and side C is further back as side D, the parachute has a propeller-like character that causes it to turn counterclockwise due to the wind escaping from top to right and bottom to the left. The torque is transferred to flexible adapter G and then to cable H.

Cable H is connected to a rotating shaft on the earth that can conduct the energy further. At the back of the parachute is a light gas-filled balloon K that always keeps the case in the air. It is shaped in such a way that it develops an upward force in an air flow (as an aircraft wing) L is a bearing point which prevents balloon K from rotating.

Claims (19)

A device for converting wind energy into rotational energy, comprising: a central rotating body provided with wind-absorbing elements, which convert the force exerted by the wind into rotating the rotating body, characterized in that the rotating body is hollow and with a gas is filled. Device according to claim 1, characterized in that the rotating body is filled with a gas which is lighter than air. Device according to claim 1 or 2, characterized in that the rotating body is thin-walled. Device according to any one of claims 1 to 3, characterized in that the wind-collecting elements are arranged fixedly relative to the rotating body. 5. Device as claimed in claim 4, characterized in that the rotation body is elongated, and that the wind-absorbing elements are arranged at least one revolution around the rotation body according to a screw surface. 6. Device as claimed in claim 5, characterized in that the wind-receiving elements have a component in the wind direction from the outside inwards. Device according to any one of claims 1 to 6, characterized in that at least one end of the rotating body is connected to a member which can be driven on a tower. 8. Device as claimed in any of the claims 1-6, characterized in that at least one end of the rotating body is connected via a flexible shaft to an element which can be driven on the ground, the balloon being in the vicinity of the rotating body to the flexible shaft. Device according to any one of the preceding claims, characterized in that the rotating body and the wind-receiving elements are jointly formed by a hollow, substantially screw-like body. Device according to any of the preceding claims, characterized in that the rotating body is conical. Device according to any one of the preceding claims, characterized in that at least two rotating bodies are arranged, which are interconnected by a flexible shaft, and that the flexible shaft is coupled to at least one balloon. Device according to any one of claims 1 to 3, characterized in that the wind-receiving elements are hingedly connected to the rotating body, and that the movement of the coupling elements transmitting by the wind is connected to the rotating body. 13. Device as claimed in claim 12, characterized in that the rotating body is provided with a groove, which guides a belt, which transfers the force exerted by the wind to an element placed on the ground, absorbing the force. 14. Device as claimed in claim 13, characterized by at least two rotational bodies arranged substantially one above the other, the axes of which rotational bodies lying one above the other are interconnected by tires, and the distance between the axes is such that as much wind as possible is caught . .5. Apparatus according to any one of claims 1 to 3, characterized in that the rotating body is articulated and provided with an opening, so that a substantially band-shaped rotating body is formed, which drives a rotatable element, wherein j. , the separate elements of the rotating body separated by the articulations are provided with elements which absorb the wind in one direction. 16. Device as mainly described in the accompanying text and appended claims. A device for rotationally converting wind energy, comprising a body rotatable about an axis extending perpendicular to the wind direction, which is coupled to wind-receiving elements, which absorb as much wind as possible in a first position, and which minimize wind in a second position. collecting, wherein the wind collecting elements are movable to both positions, and are forced by the wind into their active position. 1 "8. Device according to claim 17, characterized in that the rotating body is a ring, to which at least two wind-receiving elements are coupled, which are formed by flexible material, and which, in their operating position by means of a coupling element, are connected by the wind transfer exerted force to the ring. 19. Device as claimed in claim 17, characterized in that the rotating body is formed by a frame in which hinged blinds are arranged, the frame having a cross-shaped configuration. 20. Device as claimed in claim 17, characterized in that the rotating body has an annular configuration in which hinged blinds are arranged where one extreme position is limited by a flexible element. Device according to claim 17, characterized in that the wind-absorbing elements are formed by a substantially rotationally symmetrical screen made of flexible material, the edge of which is connected to the shaft by cables in at least two places, and wherein the screen has at least partly a screw-plane-shaped configuration, and the screen is centrally connected to the shaft by means of a torsion transfer connection, ..........