NL2004922A - ELECTRICITY GENERATOR AND METHOD. - Google Patents

Description

ELECTRICITY GENERATOR AND METHOD

The present invention relates to an electricity generator, such as a windmill for generating electrical energy. The present invention furthermore relates to a method for updating control software in control electronics for such an electricity generator.

Windmills are known in many shapes and sizes. However, wind turbines can only generate energy if a number of conditions are met. Such conditions include a minimum speed, a maximum wind speed, and many other conditions. In particular, relatively small-sized wind turbines are subject to a number of limitations in daily use, which have made them cost-effective up to now. The present invention has for its object to improve the relatively small device in such a way that it can be used operationally better against acceptable total lifetime costs compared to the total lifetime benefits.

In order to achieve this object, the present invention provides an electricity generator for generating electric energy based on wind energy, comprising: - a frame rotatable to be groundable with respect to the earth, - a substantially annular air-conducting member for arranging on the frame of air during the energy conversion process, - a rotor comprising rotor blades which is substantially arranged within the air guide member, - a power generator for generating electrical energy on the basis of a rotational movement of the rotor.

In a first preferred embodiments, the electricity generator comprises generator control electronics comprising means for converting the electrical energy from a form generated in the power generator to a direct current. This makes it possible to discharge the electrical energy from the generator control electronics in a simple manner. The removal of the direct current requires fewer conductors that are mutually isolated from each other than for the number of phases of a multi-phase generator according to the prior art.

In a further preferred embodiment, the generator control electronics is arranged on the frame, preferably within the rotor. It is hereby achieved that with the smaller number of phases of the previous embodiment it can be used for transport and relatively simple transition from the rotatable frame to the earth.

More preferably, the power generator is a multi-phase power generator. According to the present invention, these phases become applicable for the purposes described below.

In a further preferred embodiment, the generator control electronics comprise motor control electronics for controlling the generator as an electric motor, preferably by controlling at least one phase. This makes it possible to rotate the rotor in a light wind. Where existing wind turbines cannot start in low wind conditions, a wind turbine according to the present embodiment will already rotate and can profit efficiently from the marginal wind. The marginal wind will slightly accelerate the rotating rotor, which is measured by the generator control electronics which will stop or reduce the drive current of the motor control electronics based on this measurement. As a result, the start-up problem of the prior art is effectively marginalized.

The generator control electronics further preferably comprises measuring means for measuring the rotation speed of the rotor on the basis of a signal of at least one phase. The results of these measurements can be used effectively for, for example, driving the motor control electronics and / or for example for keeping track of wind data.

The inventor of the present invention has realized that braking the electricity generator at high wind speeds is of great importance. There was no suitable solution for this in the prior art. The inventor has therefore provided that the generator control electronics comprise means for reversing the flow direction in at least one of the phases on the basis of the rotational speed, preferably switching current from a regularly switched phase to a reverse switched phase. This makes it possible to reverse 1 or more phases, which effectively slows the rotor. The remaining phases remain available for the generation of electrical power.

An alternative to this is the preferred embodiment in which the generator control electronics comprise a load resistor for braking the rotor in case the resistance of the power generator is insufficient for braking the rotor. This effectively prevents too high a speed of the rotor.

In a further preferred embodiment, the electricity generator comprises a photovoltaic cell for generating electrical energy from light, such as sunlight, which photovoltaic cell is preferably arranged in the outside of the air-conducting member, which photovoltaic cell is further preferably a flowing has a transition with the further surface of the air-guiding member, more preferably has a flat course with respect to the rest of the surface of the air-guiding member. The energy generated by means of the photovoltaic cell can be advantageously utilized to provide energy for driving the rotor in the absence of wind. This reduces efficiency losses due to rotating the rotor in the absence of wind.

For providing an electrically conductive transition between the rotatable frame and the ground, the electricity generator preferably comprises a slip ring, such as preferably a mercury slip ring or a brush slip ring, for transferring the current from the rotatable frame to the ground, which slip ring preferably is arranged in cooperation with a bearing. With the aid of such a slip ring an infinite rotation of the rotatable frame becomes possible. A mercury slip ring offers the advantage that a liquid provides the electrical contact, whereby wear is excluded. A brush slip ring has the advantage that a simple interchangeability of the slip ring can be achieved. The slip ring is here preferably embodied as an exchangeable cassette and provided with contacts for the rotatable side and contacts for the earth side.

Preferably, the rotor blades are rotatably arranged within the inner surface of the air guide member. An advantage of such a preferred embodiment is according to tests that the highest power is achieved.

Alternatively, the ends of the rotor blades are enclosed by an annular connecting member that is rotatably arranged within the inner surface of the air guide member. The advantage here is that the blades are reinforced on the outside. This positively influences the stability of the rotor as a whole, in particular under relatively large loads.

In a further alternative manner, the ends of the rotor blades are enclosed by an annular connecting member rotatably arranged within a slot or recess in the inner surface of the air-guiding member. An advantage of this arrangement is that the air flow after flowing through the inside of the air guide member can flow freely along the inside of the annular connecting member, since these two inside sides together can form a substantially smooth surface.

If the air-guiding member has a cross-sectional profile which preferably has a front side that is relatively obtuse to the rear, and which preferably has a sharp rear side relative to the front side, a low air resistance is achieved, at least the total air resistance of the electricity generator is reduced.

The reduction of the air resistance is further improved in an electricity generator in which the air-guiding member, viewed in cross-section, is arranged substantially at an angle with the axis of the annular shape, which angle is preferably in the range of minus 15 ° to 45 °, more preferably in the range of 0 ° to 40 °, more preferably in the range of 0 ° to 30 °, more preferably in the range of 5 ° to 25 °, more preferably in the range range of 10 ° to 20 °, more preferably in the range of 12 ° to 18 °, more preferably in the range of 14 ° to 17 °. Experiments have shown that such configurations of the air conductor lead to a reduction of the air resistance along the air conductor per se and along the electricity generator as a whole. The pressure fluctuations in the air flow and the air body surrounding the electricity generator are then minimal.

A further aspect according to the present invention relates to an electricity generator in which the air-conducting member is absent or is suitable for guiding the air relative to a rotor that can be rotated vertically. Various aspects of the present invention function in themselves as an improvement without the air guide member, or with an air guide member in another form of a ring shape. This aspect of the present invention is specifically designed to provide separate protection for such aspects.

Different shapes of the rotor blades are provided in which the blades of the rotor have substantially a straight shape, a curved shape, or an increasingly curved shape. Experiments have been made with regard to these shapes in order to be able to use these leaf shapes in conditions with the most optimal wind for each leaf.

One and further preferred embodiment is the generator control electronics programmable for an optimum control depending on common wind conditions per predetermined time periods, such as per day part, a week, month, season. This ensures optimum energy generation in the light of different circumstances.

The generator control electronics preferably comprise a processing unit and a memory. This makes it possible, for example, to program the generator control electronics with software that is suitable for specific conditions of use. This also makes it possible to program the generator control electronics differently when the operating conditions change or the software is improved.

The generator control electronics and the power generator are preferably arranged in a separate housing which is removably attachable to the frame, preferably at the center of the rotor, preferably by means of a threaded or bayonet connection. This makes it possible to convert alternating current supplied from a third generator into a direct current for justified discharge thereof from the rotating frame. Furthermore, it becomes possible to easily replace the generator control electronics in the event of a fault. Furthermore, it becomes possible to use the generator control electronics housing as an air-conducting element.

A further aspect according to the present invention relates to a method for reprogramming generator control electronics in an electricity generator via a computer network, comprising steps for: - making contact between the generator control electronics and a central software server, - transmitting measurement data and / or data relating to to the software version from the generator control electronics to the central software server, - transferring a new software version from the central software server to the generator control electronics.

Further advantages, features and details of the present invention will be described in greater detail below with reference to one or more preferred embodiments with reference to the attached figures. Where appropriate, similar parts of a preferred embodiment are provided with the same reference numerals as similar parts of another preferred embodiment.

FIG. 1 shows a schematic representation of a first preferred embodiment according to the present invention in front view with a cut-away detail.

FIG. 2 shows a schematic representation of a further preferred embodiment.

FIG. 3 shows a schematic representation of a further preferred embodiment.

FIG. 4 shows a schematic representation of a further preferred embodiment.

FIG. 5 shows a schematic representation of a further preferred embodiment.

FIG. 6 shows a schematic representation of a further preferred embodiment in different views.

FIG. 7 shows a schematic representation of a further preferred embodiment in different views.

FIG. 8 shows a number of variants of air-conducting members according to the present invention.

FIG. 9 shows a number of variants of rotor blade configurations according to the present invention

FIG. 10 shows a number of variants of rotor blade configurations according to the present invention

FIG. 11 shows a further preferred embodiment of the present invention in various views.

A first preferred embodiment (Fig. 1) according to the present invention relates to a windmill 1. This windmill one comprises an air guide ring 2 which extends around a rotor configuration 3 in front view. The rotor configuration comprises a rotor core 4 with rotor blades 7 extending substantially radially therefrom. The windmill further comprises a frame 5 to which the air guide ring and the rotor configuration are attached. This frame is described in greater detail below.

The frame is mounted on a bearing unit 6 for rotatable mounting relative to the ground. The bearing unit is provided with means for transmitting current while the frame can be rotated. To this end, the bearing unit 6 comprises slip ring 13 which comprises guide means under rotatability. The bearing unit 6 comprises means for firmly and rotatably receiving a tube part 8 that forms a lower part of the frame 5. This lower part of the tube 8 is received by a plug 10 embedded in a bearing 11. The slip ring 13 is embedded in a plug 12. The slip ring has at least one conductive conductor for conducting electrical current that must be insulated from the ground. For this purpose, this slip ring has a guide element in the form of a mercury reservoir with a contact to the frame and a contact to the fixed part of the bearing.

In FIG. 2 shows a first preferred embodiment of a circuit which according to the present invention is preferably present at the core of the rotor attached to the rotatable part of the frame. This circuit is coupled to the generator 21 which is driven by the rotor with the rotor blades. In this example, the generator is a 3-phase generator that can also serve as a drive motor.

According to the present invention, at least one of the phases is used as a source for a measurement of the rotational speed of the rotor. As a result, a measurement of the driving power of the wind can be obtained efficiently without additional measuring means. The signal to be used for this purpose is converted by the control unit 23 into measured values. An advantage of using the generator as an anemometer is that the control electronics can respond very quickly to changes.

To use the generator as an anemometer, it is necessary that the generator always runs. According to the prior art, a rotor of a windmill has the problem that, once it has come to a standstill, it has a certain minimum amount required to be able to restart it. The consequence of this is that the rotor according to the prior art is not used to measure the wind since the rotor does not always rotate.

A solution according to the present invention is to cause the rotor to rotate fully continuously by means of the motor control unit 22, or in any case to rotate when a measurement of the wind is desired. To this end, the control unit 23 can be configured such that it controls the motor control unit 22 when the wind is not sufficiently capable of keeping the rotor rotating. For this purpose a minimum motor drive signal is supplied by the motor drive unit 22 to at least one of the phases of the generator 21. For this purpose energy can be applied that comes from the solar cell 26.

In the normal operation of the windmill, the generator generates electric current which is supplied to the rectifier 24. The rectifier 24 converts the alternating voltage from the generator after a direct voltage with an order of magnitude of preferably 200 to 400 volts. To this end, a pulse width control is further provided which, depending on the desired resulting current, draws off a part of the signal. This direct current is supplied to a cable 27.

If the wind is very strong and the rotor starts rotating too fast, this can cause damage. In order to prevent such damage, the rotor is braked by coupling the generator to a load resistor 25. The magnitude of the load resistor may have a fixed value or be controlled depending on the necessity of braking the rotor. Furthermore, according to the present invention, it is possible to switch a phase of the 3 phases inverted by means of the control and to supply the current of their second phase thereto, thereby braking the rotor. The third phase will in this case still supply electricity that can be dissipated as useful energy through the rectifier.

In FIG. 3, a conversion unit 31 is shown for converting the electric current from cable 27 to a value that can be supplied to the electricity grid, for example 230 volts AC. A converter 33 is provided for this purpose. Furthermore, a control unit 32 is provided which is in half duplex connection with the control unit 23 of the windmill. This control unit is provided with a display and a USB port. A power supply 34 is furthermore provided which supplies power to the system when the wind and the solar cell cannot provide the required energy.

The control unit 32 controls the input voltage of the converter 33, the input current of the converter 33, the output current of the converter 33, and among other things the speed of the generator. This and other data can also be displayed on the screen. The control unit 32 is adapted to adjust the input voltage of the converter 33 to the wind speed and therefore the speed of the generator and the energy requirement of the converter. For this purpose, a data file with optimum values is available, which can be used to switch under the influence of the wind speed. The control unit 23, incidentally, preferably functions independently, but can be adjusted with data from the control unit 32.

Figures 4 and 5 show alternatives for the schematic representation of control units of Figures 2 and 3. In this embodiment, the micro-control unit 23 is directly connected to the generator 21 and the rectifier to control unit 24. The solar cell 26 has meanwhile become an inverter connected to the rectifier 24.

In the case of both embodiments of the circuits of Figs. 2 to 5, the following further applies. The motor control 22 preferably has the option of a mere control of 10 to 100 W, preferably 20 to 70 W, more preferably 30 to 50 W. This motor control, together with the control unit 23, is capable of running the transfer seamlessly. of the rotation by the engine and allowing the rotation to take over from engine power to wind force.

In FIG. 6 shows an example of the structure of the frame with the air guide ring 2. In this example, the ring is supported by the frame tube 8. Further, in this example, the rotor core 4 is supported by 2 upper rotor core supports 61, a front lower rotor core support 63. and their rear lower rotor core support 62. In the preferred embodiment of FIG. 7, the structure of the frame is different and extends in the frame tube 8 up to the rotor core for direct support of the rotor core by this frame tube 8. An additional reinforcement is provided by means of fins 71. In the rotor core there is located in the generator 73 with there behind the electronics unit 73 which comprises the electronics 74 of figures 2 and 4. This housing is made up of 2 parts so that the parts can be replaced independently of each other in a simple manner.

At the front of the generator is a rotor shaft 75 on which the rotor with the rotor blades can be mounted.

The rear part 76 of the rotor housing is preferably attached to the front part 77 by means of a screw connection, whereby the rotor housing can be opened in a simple manner. As a result, the electronics 74 and / or the generator 73 can be replaced in a simple manner.

Figure 8 also shows diagrammatically some cross-sections of configurations of the air conductor. Depending on the wind condition, one of these configurations or intermediate configurations in terms of deviation angle can be chosen within the understanding of the present invention.

In FIG. 9 different configurations of the rotor blades are shown. FIG. 9 A, a configuration with rotor blades 91 with a loose tip is shown. In FIG. 9B a rotor blade 92 is shown, the parts of which are mutually connected by means of a ring 93. This ring 93 is designed such that it fits into a slot 94 which is fitted on the inside of the air guide ring 2 '. This makes it possible to use a ring 93 to reinforce and stabilize the ends of the rotor blades while at the same time achieving that the ring per se experiences as little air resistance as possible from the flowing wind or that the flowing wind has as little resistance as possible from the ring 93. In FIG. 9 C, a ring 95 is shown which interconnects the rotor blades 94. Hereby the ring 95 moves as close as possible within the surface of the air guide ring 2, which therefore requires no adjustments and whereby the air flow through the ring is influenced as little as possible.

Figure 10 shows three rotor blade configurations in cross-section and a perspective view. The left view shows a rotor blade configuration where the rotor blades are flat. The middle representation shows a rotor blade configuration in which rotor blades have a similar rectangular shape as the left display and curvature. The right-hand view shows a rotor blade configuration in which the blades have and curvature and also show a widening from the rotor core to the rotor tip. As a result, the rotor blades have a relatively large surface area relative to the surface area within the ring. Experiments have shown that the different blades provide different advantages depending on the wind speed.

In FIG. 11, a configuration of the air-guiding member is shown in which, in addition to the previously shown aspects, a solar panel 99 is included at the top. The solar panel must follow the shape of the ring. Therefore, an amorphous solar cell type is preferably used which can be of flexible design and can therefore be arranged in a simple manner in a curved form on the outside of the substantially annular air-conducting member 2.

This solar panel provides solar energy converted to electrical energy that can be used to drive the rotor during the windless period. It is also possible to store this solar energy in a battery for wind stillness during dark hours. It is also possible to convert this solar energy into a suitable form for delivery to the electricity network. An important object of the solar cell according to the last invention is to provide energy for allowing the rotor to rotate in times of calm or insufficient wind for maintaining the rotation, even without a load on the generator, in other words even when the generator has been switched off and the rotor can rotate freely. In that case, an at least single phase of the generator is used to drive the rotor.

In the foregoing, the present invention has been described with reference to a few preferred embodiments. Different aspects of different embodiments are considered to be described in combination with each other, all combinations considered to be considered by a person skilled in the art on the basis of this document to be included in the understanding of the invention. These preferred embodiments are not limitative of the scope of this document. The rights requested are defined in the appended claims.

Claims (21)

An electricity generator for generating electric energy on the basis of wind energy, comprising: - a frame that can be rotated with respect to the earth, - a substantially annular air-conducting member which can be arranged on the frame for guiding air during the energy conversion process - a rotor comprising rotor blades which can be arranged substantially within the air guide member, - a power generator for generating electrical energy on the basis of a rotational movement of the rotor. An electricity generator according to claim 1 comprising generator control electronics comprising means for converting the electrical energy of a form generated in the power generator into a direct current. An electricity generator according to claim 1 or 2, wherein the generator control electronics is arranged on the frame, preferably within the rotor. An electricity generator according to claim 1, 2 or 3, wherein the power generator is a multi-phase power generator. 5. Electricity generator according to one or more of the preceding claims, in which the generator control electronics comprise motor control electronics for controlling the generator as an electric motor, preferably by controlling at least one phase. 6. Electricity generator as claimed in one or more of the foregoing claims, wherein the generator control electronics comprises measuring means for measuring the rotation speed of the rotor on the basis of a signal of at least one phase. An electricity generator as claimed in one or more of the preceding claims, wherein the generator control electronics comprises means for reversing the flow direction in at least one of the phases on the basis of the rotational speed, preferably switching current from a regularly switched phase to a phase reversed. An electricity generator according to any one of the preceding claims, wherein the generator control electronics preferably comprises a load resistor for braking the rotor. 9. Electricity generator according to one or more of the preceding claims, comprising a photovoltaic cell for generating electrical energy from light, such as sunlight, which photovoltaic cell is preferably arranged in the outside of the air-conducting member, which photovoltaic cell preferably has a smooth transition with the further surface of the air-guiding member, more preferably has a flat course with respect to the rest of the surface of the air-guiding member. 10. Electricity generator according to one or more of the preceding claims, comprising a slip ring, such as preferably a mercury slip ring or a brush slip ring, for transferring the current from the rotatable frame to the earth, which slip ring is preferably arranged in conjunction with a bearing and which slip ring is preferably designed as an exchangeable cassette comprising contacts for the rotatable side and the earth side. 11. Electricity generator according to one or more of the preceding claims, wherein the rotor blades are rotatably arranged within the inner surface of the air guide member. 12. Electricity generator as claimed in one or more of the foregoing claims, wherein the ends of the rotor blades are enclosed by means of an annular connecting member rotatably arranged within the inner surface of the air-guiding member. An electricity generator as claimed in one or more of the preceding claims, wherein the ends of the rotor blades are enclosed by an annular connecting member rotatably arranged within a slot or recess in the inner surface of the air-guiding member. 14. Electricity generator according to one or more of the preceding claims, wherein the air-conducting member has a cross-sectional profile which preferably has a front side that is relatively obtuse to the rear side, and which preferably has a sharp rear side relative to the front side. 15. Electricity generator according to one or more of the preceding claims, wherein the air-conducting member, viewed in cross-section, is arranged substantially at an angle with the axis of the annular shape, which angle is preferably in the range of minus 15 ° to with 45 °, more preferably in the range of 0 ° to 40 °, more preferably in the range of 0 ° to 30 °, more preferably in the range of 5 ° to 25 °, more preferably in the range of 10 ° to 20 °, more preferably in the range of 12 ° to 18 °, more preferably in the range of 14 ° to 17 °. 16. Electricity generator according to one or more of the preceding claims, in which the air-conducting member is absent or suitable for guiding the air relative to a rotor that can be rotated vertically. The electricity generator according to one or more of the preceding claims, wherein the blades of the rotor have substantially a straight shape, a curved shape, or an increasingly curved shape. An electricity generator according to any one of the preceding claims wherein the generator control electronics is programmable for optimum control depending on common wind conditions per predetermined time periods, such as per day part, a week, month, season. 19. Electricity generator according to one or more of the preceding claims, wherein the generator control electronics comprise a processing unit and a memory. 20. Electricity generator according to one or more of the preceding claims, in which the generator control electronics and the power generator are arranged in a separate housing which is removably attachable to the frame, preferably at the center of the rotor, preferably by means of a screw thread. or bayonet connection. Method for reprogramming generator control electronics in a power generator via a computer network, comprising steps for: - making contact between the generator control electronics and a central software server, - transferring measurement data and / or data relating to the software version of the generator control electronics to the central software server, - transferring a new software version from the central software server to the generator control electronics.