NL2007638C2 - TURBINE, PREFERREDLY A HYDRAULIC RADIAL TURBINE, A WIND TURBINE AND A SYSTEM INCLUDING A TURBINE. - Google Patents

Description

Brief description: Turbine, preferably a hydraulic radial turbine, a wind turbine and a system comprising a turbine.

DESCRIPTION

The invention relates to a turbine, preferably a hydraulic radial turbine, comprising a rotatable cylinder with a number of protrusions provided on an outer jacket thereof, which protrusions extend substantially in a radial direction away from the outer jacket and substantially in an axial direction along the outer jacket of the extend the cylinder.

A turbine is generally known. The known turbine comprises a rotating blade system with which the turbo machine converts the flow energy of a fluid (liquid or gas) into mechanical energy. The mechanical energy can be used to drive another machine or an electric generator. In an embodiment of the known turbine, this is a hydraulic turbine which acts on pulse transfer of a liquid.

It is an object of the present invention to provide an improved turbine, and in particular a hydraulic radial turbine.

To this end the invention provides a turbine, preferably a hydraulic radial turbine according to claim 1. The turbine comprises a rotatable cylinder with a number of protrusions provided on an outer casing thereof. Because the protrusions are provided on an outer casing of the cylinder, the fluid will be concentrated on the protrusions. Because the protrusions are placed at a radial distance from the pivot point of the cylinder, a relatively long arm is obtained, whereby a relatively high torque can be transmitted with the same fluid force. The protrusions extend substantially in a radial direction away from the cylinder and substantially in an axial direction along the outer casing of the vertical cylinder. According to the invention, the cylinder with the protrusions is rotatably received in a turbine housing which is at least partially cylindrical. The turbine housing comprises an inlet for fluid and an outlet for fluid which are spaced apart in the circumferential direction. Fluid can flow in via the inlet, transfer energy to the rotating cylinder via the projections. The turbine housing is at least partially cylindrical between the inlet and the outlet. Between the inlet and the outlet, the turbine housing, in both the circumferential direction and the axial direction of the cylinder, closely connects to the radial ends of the protrusions of the cylinder. The turbine housing at least partially encloses the protrusions in both the circumferential direction and the axial direction of the vertical cylinder. This enclosing causes the fluid to be forced to exert the force on the protrusion. Because of the enclosure, the fluid cannot simply flow around the protrusion. It thereby prevents energy losses due to fluid flowing away between the radial ends of the protrusions and the interior of the turbine housing, whereby the efficiency of the turbine is increased. An improved turbine is hereby obtained with which the object of the invention is achieved.

The protrusions are more preferably formed by rotor blades or blades, but alternatively the protrusions can for instance be formed by teeth.

The turbine is preferably a hydraulic radial turbine, which operates on hydraulic fluid, such as for example oil.

The inventive idea is also applicable to other turbines, such as for example wind turbines, and / or water turbines. The use of a different fluid is of course conceivable, and is obvious to a person skilled in the art.

An impulse turbine on wind is generally known, for example as a so-called ton mill. The generally known wind turbine has a relatively long shaft which is arranged vertically and to which a number of curved rotor blades are attached. A wind current on the rotor blades provides a rotating movement that can be converted into mechanical or electrical energy. Such windmills are also known from ancient Persia.

The wind turbine according to the present invention, which uses the same inventive concept, is defined in claim 4. The wind turbine according to the invention comprises a rotatable vertical cylinder with a number of rotor blades provided on an outer jacket thereof. Because the rotor blades are provided on an outer jacket of the cylinder, the wind will be concentrated on the rotor blades. Because the rotor blades are placed at a radial distance from the pivot, a relatively long arm is obtained, whereby a relatively high torque can be transmitted with the same wind force. The rotor blades extend substantially in a radial direction away from the cylinder and substantially in an axial direction along the outer casing of the vertical cylinder, and can thereby be curved. The vertical cylinder with the rotor blades is rotatably received in a rotatable vertical turbine housing that is at least partially cylindrical. The turbine housing comprises an air inlet and an air outlet located on opposite peripheral sides of the wind turbine. The wind can transfer energy to the rotor blades via the air inlet and the air outlet, so as to drive the wind turbine. The turbine housing is at least partially cylindrical between the air inlet and the air outlet. Between the inlet and the outlet, the turbine housing, in both the circumferential direction and the axial direction of the cylinder, closely connects to the radial ends of the rotor blades of the vertical cylinder. The turbine housing at least partially encloses the rotor blades in both the circumferential direction and the axial direction of the vertical cylinder. This enclosure ensures that the wind cannot exert any force on the blades locally, so that losses are limited. In particular where the blades or rotor blades move against the wind, shielding the blades with the turbine housing prevents many losses from occurring. It also prevents losses due to air flowing away between the radial ends of the rotor blades and the interior of the turbine housing. An improved wind turbine is hereby obtained, with which the object of the invention is achieved.

Further advantageous embodiments of the wind turbine are the subject of the dependent claims 5 to 11. Some embodiments and their advantages will be explained in more detail below. It will be apparent to those skilled in the art that at least some of these aspects are well applicable to a turbine, preferably a hydraulic radial turbine, according to the present invention.

The air inlet is preferably provided with guide walls that extend over a distance in a radial direction, the guide walls defining a flow channel that flows substantially tangentially to the cylinder. In this way wind energy can be transferred to the wind turbine in an improved manner.

Preferably, it holds that the conductor walls, towards the cylinder, are tapered towards each other such that at the location of the rotor blade the conductor walls determine a narrower passage of the air inlet. This increases the speed of the air at the entrance.

In one embodiment, the wind turbine comprises a further air inlet, preferably with additional guide walls. Here too it holds that preferably the guide walls run tapered towards each other such that at the location of the rotor blade the guide walls determine a narrower passage of the air inlet. This increases the speed of the air at the entrance. It is also possible to dimension the narrower passage of the further air inlet differently than the narrower passage of the air inlet. This can be advantageous, for example when starting up the wind turbine.

In order to properly position the air inlet against the wind, i.e. to catch maximum wind, the wind turbine is preferably provided with a wind directional element. This wind directional element can be connected to the turbine housing, which can be rotatable relative to a base of the wind turbine, such that the air inlet can be placed against the wind.

According to an aspect of the invention, a system for temporarily storing energy is provided, as defined in claim 12. The system comprises a turbine and / or a wind turbine according to the invention. The system comprises a storage unit operatively connected to the turbine for storing energy. The storage unit can for instance be a generator, or a battery, or another form of energy storage.

Further advantageous embodiments of the wind turbine are the subject of the dependent claims 13 to 17.

It is preferred here if the storage unit is operatively connected via a hydraulic circuit comprising a hydraulic pump and a transmission unit, preferably a hydraulic turbine according to the invention, to an axis of an energy converter, preferably a windmill according to the invention. The energy is transferable with relatively few losses via the hydraulic system. The transmission unit ensures that energy can be transferred well at many different fluid velocities (preferably wind velocities).

In one embodiment, the storage unit comprises a first pressure container and a second pressure container which are connected to each other via a pipe, wherein a pump unit is provided in the pipe. The pump unit is operatively connected to the transfer unit. Liquid is present in the pressure container. The pump unit pumps the liquid from one pressure container to the other, whereby the air present in that pressure container is pressurized. This pressure is a form of energy storage.

The transmission unit preferably comprises a number of drive units with mutually different dimensions, for obtaining different transmission ratios between the axis of the energy converter, such as the wind turbine and the mechanical axis to which the storage unit is connected.

The invention will be explained in more detail below with reference to the following figure description and the accompanying figures, in which:

FIG. 1 - a sectional view of a wind turbine according to the present invention;

FIG. 2 - a sectional view of an embodiment of a wind turbine according to the present invention; FIG. 3 - a side cross-sectional view of the wind turbine according to FIG. 1;

FIG. 4 - a schematic overview of a system comprising a wind turbine according to the present invention; and

FIG. 5 - a schematic detailed overview of an embodiment of the system according to the present invention.

It is noted that the inventive idea is subsequently explained, by way of illustration, mainly on the basis of an embodiment in which a wind turbine is central. It will be clear, however, to those skilled in the art that the wind turbine used is in principle also suitable for use with a different fluid, such as for example (but not exclusively) water and oil. Vertical and horizontal axes can be adjusted if necessary.

FIG. 1 shows an axial sectional view of a wind turbine 1. The wind turbine 1 comprises a vertically placed shaft 6. Around the shaft 6, a cylinder 3 is rotatably placed. The cylinder 3 comprises an outer casing 4. In order to save weight, radially extending ribs 14 are provided such that a largely hollow cylinder 3 is obtained. Resistance elements 5 in the form of blades 5 are provided on the outer casing 4. The blades are provided over the entire axial length 6 of the cylinder 3. The blades 5 extend in a radial direction of the cylinder 3. The blades 5 are also slightly curved. The blades extend, as it were, in a tangential direction, as they are further removed in radial direction from the outer casing 4 of the cylinder.

A turbine housing 2 is provided tightly around the cylinder 3 with the blades. As can be clearly seen in FIG. 1, the turbine housing 2 connects over almost the entire circumference to the cylindrical shape formed by the outer edges of the blades 5.

However, there is not a close connection over the entire circumference. In order to allow the cylinder 3 to rotate due to the wind, an inlet opening 11 and an outlet opening 12 are provided. The inlet 11 is then located on a first circumferential side (left in Fig. 1), and the outlet is on a second circumferential side (right in Fig. 1), wherein the second circumferential side is preferably opposite the first circumferential side.

The inlet 11 extends over a certain length, substantially in a radial direction of the cylinder 3. The inlet 11 is thereby formed by two walls 22 and 23 placed almost parallel to each other, which run slightly tapered towards each other in the direction towards the cylinder. As a result, the flow-through opening for incoming air near the vanes 5 is smaller than the flow-through opening for incoming air at some distance from the blades 5. The walls 22 and 23 are also curved, such that the incoming air is guided in a tangential direction, and thereby being able to properly transfer the force to the blades 5.

FIG. 2 shows an alternative embodiment of the air inlet 11, 11 '. In fact, two air inlets 11, 11 'are present here. The inner walls 23 and 24 are thereby arranged such that a wing-shaped profile 21 is obtained, which is placed substantially centrally in the middle of a large supply opening. Here, too, it applies to each air inlet 11, 11 'that the flow area close to the radial blades 5 is smaller than the flow area at some distance therefrom. In addition, the flow surface of the upper air inlet 11 near the vanes is smaller than the flow surface of the lower air inlet 11 '. The wing-shaped profile 21 comprises a front wall which is positioned such that it coincides with a radial line from the center of the cylinder 3 to the wind direction. The upper air inlet 11 is positioned in a negative tangential direction of the wing-shaped profile relative to the direction of rotation R of the cylinder 3, while the lower air inlet 11 'is placed in a negative tangential direction relative to the direction of rotation R .

Referring again to FIG. 1, it can be seen that the outlet 12 is formed by two conductor elements 31, 32, which are slightly tapered away from each other. The flow-through opening becomes larger as the outlet 12 is further removed from the radial blades 5. The rear wall (top right in Fig. 1) 31 is curved, quarter-circular in shape.

In addition, the wind turbine preferably comprises a wind directional element 15, such as a wind vane. The wind vane is positioned near the rear (near the air outlet 12), and extends radially. The wind vane has a wedge-shaped cross section. The wind directional element ensures that the air inlet 11 (or air inlets 11 and 11 ', see Fig. 2), are directed substantially straight towards the wind direction. FIG. 3 shows a lateral cross-section of the wind turbine according to FIG. 1. Corresponding parts are in each case provided with the same reference numeral. The placement of the rotating cylinder 3 is clearly visible here. By means suitable for this purpose, the rotatable cylinder 3 is attached to the central shaft 6. Shown here are some bearings which are not further numbered. The central shaft 6 (which does not rotate) is further connected to a base 8, with which the wind turbine can be placed stably. An energy transmission 9 is provided on an underside of the rotatable cylinder 3, which may, for example, be gear-shaped. With the energy transfer, wind energy can be converted into e.g. mechanical energy or electrical energy. The skilled person will thereby be able to effect a suitable energy transfer.

FIG. 4 shows a system 100 comprising a windmill as described above. The system comprises an embodiment of the windmill 101 already described, which is connected via a mechanical transmission to a hydraulic pump 102 of a hydraulic circuit 121. The hydraulic pump 30 can for instance be a gear pump. The hydraulic circuit 121, which, for example, operates on oil, comprises a pressure line 112, in which a non-return valve unit 114 is placed. The pressure line 112 opens onto a transfer unit 114. From there, a return line 113 runs back to the pump unit 102. An expansion vessel 103 is also placed in the 8 pressure line.

The transmission unit 104 is further connected to a mechanical axis. In the transmission unit, the flow of the hydraulic circuit is converted into a rotation of the mechanical axis. The transmission unit is preferably a turbine according to the present invention. One or more further components can be coupled to the mechanical shaft, depending on the user's wishes. In the embodiment shown, a generator (105), a compressor (106) and a liquid-air motor (107) are provided. These three components 105, 106, 107 will be described with reference to FIG. 5 will be further explained.

FIG. 5 shows an example of the transfer unit and the further components, as described above with reference to FIG. 4. FIG. 5 shows a part of the hydraulic system 221 (which is connected, for example, to the wind turbine according to the invention, as described above), to the transmission unit 204. The transmission unit comprises a number of hydraulic gears 205, 206, 207, each of which has a different have a radius. The hydraulic gears 205, 206, 207 are fixedly connected to a mechanical shaft which is rotatably suspended in a number of bearings 218, 216, 217. The pressure line 212 of the hydraulic system is by means of a suitable control (e.g. mechanical control, or electrical control) connectable to one or more of the hydraulic gears 205, 206, 207. In this case, it applies that the force exerted on the hydraulic gear wheel depends on the force supplied by the pump, but that the applied torque on the mechanical shaft 215 depends on the radius of the respective hydraulic gear. The hydraulic fluid engages the radial outer side of the respective gear wheel, whereby a larger torque can be applied to the mechanical shaft 215. Thus, with the transmission unit 204, the rotational speed of and the torque on the mechanical shaft 215 can be controlled to a large extent in dependence on the actual wind speed and the power supplied by the pump 102. The transfer unit 204 can also be used well for starting up the further components.

FIG. 5 shows that the further components are formed by a generator 208 for generating energy, a compressor 209 for storing too much energy, and a liquid-air motor 316.

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The liquid-air motor 316 is thereby used when there is no wind, to make the mechanical shaft 215 rotate, and to supply the generator 208 with energy. The liquid-air motor 316 comprises a first pressure container 311 and a second pressure container 317. The pressure containers are connected to each other via a line 318. A pump unit 310 is provided between the two pressure holders 311 and 317, which is drivable by the mechanical shaft 215, or which can drive the mechanical shaft.

An amount of liquid, such as water, is provided in the line 318 and the pressure containers 311, 317. When the pumping unit 310 is operated, it will pump the water into one of the tanks. To this end, a switching unit known per se is provided, such that water can optionally be pumped into one of the two tanks 311, 317. The pressure container is completely sealed and contains some air. By pumping the liquid into the pressure container, the air in the tank will be compressed, so that a high pressure can arise in the pressure container. In the other vessel, where the liquid is being pumped out, a valve may be present to ensure that there is no underpressure in the pressure container that makes pumping more difficult. If the vessel is provided with a high pressure, then this pressure can be used to push liquid from one pressure tank to the other pressure tank. During transport through the tube 318, the transported liquid will drive the pump unit 310, with which the mechanical shaft 215 is also driven. The water will be transported to the other storage tank, where an overpressure of air will be created. This excess pressure can then again be used to drive the pump unit 310 again. Over time, the losses are such that the pressure build-up obtained in the vessel 311 or 322 is so small that the pump unit can no longer be driven sufficiently. At that time the energy stored in the water-air motor has been used up, and new energy must be stored again. This energy storage is then provided by the wind turbine.

The invention has been further elucidated above with reference to a few preferred embodiments. Within the scope of the invention, however, many alternatives are conceivable, which may fall within the required scope of protection of the appended claims.

Claims (18)

1. Turbine, preferably a hydraulic radial turbine, comprising a rotatable cylinder with a number of protrusions provided on an outer jacket thereof which extend substantially away from the outer jacket in a radial direction and substantially along an axial direction along the outer jacket of the cylinder , wherein the turbine comprises a turbine housing in which the cylinder with the protrusions is rotatably received, the turbine housing comprising an inlet for fluid and an outlet for fluid located on different peripheral parts of the turbine, the inlet being substantially tangential to the protrusions and wherein the turbine housing between the inlet and the outlet is at least partially cylindrical and closely aligned with the radial ends of the protrusions of the cylinder in both the circumferential direction and the axial direction. 2. Turbine according to claim 1, wherein the turbine is a hydraulic radial turbine. The turbine of claim 1, wherein the turbine is a wind turbine. Wind turbine (1) with vertical axis, comprising a rotatable vertical cylinder (3) with a number of rotor blades (5) provided on an outer jacket (4) thereof, which blades are substantially radially away from the outer jacket (4) and in Extend substantially in an axial direction along the outer casing (4) of the vertical cylinder (3), the wind turbine comprising a rotatable vertical turbine housing (2) in which the vertical cylinder (3) with the rotor blades (5) is rotatably accommodated, the turbine housing (2) comprises an air inlet (11) and an air outlet (12) which are situated on opposite peripheral sides of the wind turbine, and wherein the turbine housing is at least partly cylindrical between the air inlet and the air outlet and in both the circumferential direction if the axial direction is close to the radial ends of the rotor blades (5) of the vertical cylinder (3). The wind turbine (1) according to claim 4, wherein the air inlet is provided with guide walls (22, 23) extending over a distance in radial direction, the guide walls (22, 23) defining a flow channel that is substantially tangential to the cylinder flows out. Wind turbine (1) according to claim 5, wherein the guide walls (22, 23), towards the cylinder, are tapered towards each other such that at the location of the rotor blade (5) the guide walls have a narrower passage of the air inlet (11) determine. Wind turbine (1) according to one of the preceding claims 4 to 6, wherein the wind turbine comprises a further air inlet (11 '), preferably with additional guide walls (24, 25). A wind turbine (1) according to any of the preceding claims 4 to 7, wherein the air outlet is provided with air outlet guide walls (31, 32), the guide walls (31, 32) defining a flow channel substantially from the cylinder runs away. Wind turbine (1) according to claim 8, wherein the air outlet conductor walls (32, 33), viewed in the axial direction, are tapered towards each other such that at the location of the rotor blade (5) the air outlet conductor walls have a narrower passage of determine the air outlet (12). Wind turbine (1) according to one of the preceding claims 4 to 15 with 9, wherein the wind turbine comprises a wind directional element (15) for placing the air inlet (11) of the turbine housing (2) against the wind. Wind turbine (1) according to one of the preceding claims 4 to 10, wherein the turbine housing (2), with the exception of the air inlet and the air outlet, substantially completely surrounds the vertical cylinder (3) with the rotor blades (5). A system (100) for temporarily storing energy, comprising a turbine according to claim 2, as well as a storage unit (107) operatively connected to the turbine for storing energy. 13. System (100) according to claim 9, wherein the storage unit (107) operates via a hydraulic circuit (121) with a hydraulic pump (102) and a transmission unit (104), preferably a turbine (104) according to claim 2 is connected to an axis of an energy converter (101), wherein the energy converter is preferably a windmill (101) according to any of claims 4 to 11. A system (100) according to claim 13, wherein the storage unit (107) comprises a first pressure container (211) and a second pressure container (212) which are connected to each other via a pipe, wherein a pump unit (210) is provided in the pipe is. The system (100) of claims 12-14, wherein the system comprises a generator unit (105). The system (100) of claims 12-15, wherein the system comprises a compressor unit (106). 17. System (100) according to claim 13 or a claim dependent thereon, wherein the transmission unit (204) comprises a number of drive units (205, 206, 207) with mutually different dimensions. The turbine of claim 1, wherein the protrusions are formed by rotor blades. 10 15