CH713042B1 - Method and device for generating electrical, can be fed into a power grid AC power. - Google Patents

Abstract

The invention relates to a method and a device for generating electrical, in a power grid (10) einspeisbarer energy from the sound energy of at least one noise source (1). The device has at least one sound transducer (2) for detecting the sound energy of at least one noise source (1). In operation, the sound energy is converted into electrical signals, stored in a memory (6, 7) and then fed as AC power into the power grid (10).

Description

Description: [0001] The invention relates to a method and a device for generating electrical power that can be fed into a power grid.

One reason for the present invention is the increasing international demand for renewable energy, which virtually calls for a device that is simple, does not require an external power supply for start-up, is economical, and is a cheap system for energy regenerative technology. In this case, only a technically simple, robust, maintenance-friendly and thus also cost-effective device, as can be provided by the present invention, come into question. The inventive method can also be carried out by means of simple components whose mass production has already been proven with high quality for use as electrical energy components.

There are various methods known to convert the sound energy obtained from noise into electrical energy and consume them again immediately or store it in a battery. These methods have the common disadvantage that the electrical energy generated from noise energy can not be fed as AC power into a power grid. This will give you a valuable profit. Under certain circumstances, the stored energy will be lost immediately due to the battery self-discharge.

The following is already known from the prior art: US 2015 229 242 A1 discloses a costly device with mechanically movable parts in order to convert sound energy into electricity energy. US 2008 174 281 A1 discloses a costly device that converts the sound energy into electricity energy. This device is intended to replace a battery. US 2009 051 229 A1 discloses a costly, partly mechanical device which charges an existing battery. US 2007 205 881 A1 discloses a method which uses the movement of a vehicle to generate electric power which merely serves to charge the vehicle battery. WO 2015 140 536 A1 discloses a method which uses the sound energy from a drum to convert it into electricity energy, which is used for subsequent use in another device. US 7 219 449 B1 discloses a method for generating and storing current energy in a shoe by its movement. US 201 652 252 A1 discloses a method which utilizes the mechanical motion of a railway vehicle to generate electric power used within the vehicle. US 2010 227 521 A1 relates to piezoelectric materials, in particular active fiber composite materials comprising piezoelectric materials. US 2012 153 780 A1 relates to piezoelectric materials, in particular three-dimensional active fiber composite materials comprising piezoelectric materials.

It is provided in any of these documents to feed the energy gained from noise in a power grid.

An object of the present invention is to develop methods and apparatus so that the disadvantages of the above-mentioned prior art are at least partially resolved.

This object is achieved by the method according to claim 1 and the device according to the independent device claim.

In the inventive method, the sound energy of at least one noise source is converted into electrical energy, which is fed into the power grid in the end. For this purpose, a device which is constructed, for example, in the subsequently described form is particularly suitable. A component of the device according to the invention is the provision of at least one sound transducer for detecting the sound energy and converting it into corresponding electrical signals. The sound energy is for example in the form of acoustic signals that propagate as sound pressure oscillations from the noise source.

Preferably, the transducer does not require power for its commissioning. Further preferably, it is resistant to high sound pressure and mechanical stress. As sound transducers are e.g. Suitable: voice coil microphone, piezo microphone, microphone array. It is also possible to use any surface of per se known piezoelectric fabrics, preferably those in the form of active fiber composite materials comprising piezoelectric materials, in particular three-dimensional active fiber composite materials comprising piezoelectric materials, e.g. to cover the facade and / or the roof of a building.

Concerning voice coil microphone, piezo microphone, microphone array: they can be used as directional antennas by being mounted as parabolic antennas in a satellite dish. This is particularly advantageous if they are directed towards continuous noise sources. This gives an improved maximum value of the received noise energy.

During operation of the device, the following procedure is then preferably followed to record the sound energy: The output of the converted electrical voltage is fed to a rectifier ("rectifier") in order to convert the energy obtained into direct current. This is fed to a charge controller and a memory. Once this has stored the predetermined amount of current required, the DC stored in the memory egg nem inverter ("converter") is supplied, which converts the DC into AC. Subsequently, the voltage value of this alternating current in a transformer is changed (as a rule increased) in order to equalize the voltage value to that of the power network. This alternating current energy is then fed into the power grid.

A further advantageous embodiment of the invention is that the device may comprise components, preferably from the charge controller of one or more other devices, e.g. Solar plants or wind turbines, be used. Provided that the predetermined current parameter values are the same for all devices and that there are no impedance differences in the coupled module units.

Advantageous developments emerge from the dependent claims.

In addition, the uses of the invention are manifold. The uses mentioned below are to be considered as examples only: - In landscape areas where there is a mains power connection, and in buildings already connected to the electricity grid, which are in the range of stronger and frequently active noise energy sources. - In coastal areas connected to the electricity grid and where the repeated powerful sound-noise energies of the waves striking the shores are both frequent and audible. - Areas and buildings connected to the electricity network which are within the zone of audible noise emission from road or motorway traffic. Particularly affected are the areas that are on slopes, because in this case the sound energy of the noise are much more disturbing. - Areas as well as buildings connected to the electricity grid which are located in regions which are often rainy. These include greenhouses - also called glasshouses or greenhouses. The raindrops falling on the roof and facades with a lot of noise cause significant noise-sound energy; to it come the sound energies of occasional thunder and storms.

Furthermore, and in relation to buildings, the use of the method and the device according to the invention can offer a number of advantages: If sound transducers are mounted on the facades, in particular around the windows and the doors, they can collect parts of the sound energy penetrating into the building ., in order to feed them in the end as electrical energy into the power network. The leftover part, resulting from the unabsorbed sound energy, will enter the building as reduced noise energy. This reduction in noise energy gives a quieter acoustics within the building. Furthermore, it is advantageous to install transducers within a building in order to create even quieter acoustics in the rooms. In or on metros and railways connected to a power supply. The accumulated sound energy is most pronounced, especially in the tunnel zones, where the noise emissions of passing rail vehicles are extremely powerful. As a result, a maximum exploitation of acoustic energy can be achieved. Here is a distinction between on the one hand the inventive device, by means of which noise energy can be converted into electricity and fed into the power grid, and on the other hand, previously known devices that are already mounted in the above-mentioned subways and railways and the railways becoming free -Kinetics Energy, eg at a speed reduction, use to feed electricity into the grid. The device according to the invention can also be mounted on vehicles which are powered by electricity, e.g. Trolleybuses - also trolleybuses, called trolleybuses. The accumulated sound energy of the city noise is converted into electrical energy and then fed into the power grid. - In covered passages for vehicles, for example in tunnels for subways, railways or motor vehicles, especially in motorway tunnels. In the passageways, when driving the vehicles, significant noise energies are generated which can be harnessed by the present invention.

Advantageously, a security against lightning is installed for the entire device system.

Further specific design features and their advantages are apparent from the following description and the following drawings.

The invention will be explained in more detail with reference to an embodiment which is illustrated in the drawings. Show it

1 shows an embodiment of the invention in a drawing block view,

2 example symbols for some questioned noise sources,

3 and 4 examples of buildings that are already connected to the mains and that are in the range of sound energies from different noise sources,

5 shows a mains-powered railway with a mounted inventive device,

Fig. 6 is a tunnel route, which can also be used for mains electricity operated railways, and

Fig. 7 is a building in the area of the noise-sound energy of the waves beating on the coast.

Claims (8)

The character block diagram shown in Fig. 1, which illustrates methods and apparatus that convert noise sound energy into electrical energy and feed it into the grid as alternating current, comprises the following elements 1-10: A noise source 1 generates a sound energy. It is provided at least one sound transducer 2, which converts the acoustic signals in the form of sound pressure oscillations in corresponding electrical signals. It advantageously requires no power supply for its commissioning and is resistant to high sound pressure and mechanical loads. He is e.g. designed as a voice coil microphone, piezo microphone, microphone array, any surface of known piezoelectric fabrics, preferably those in the form of active fiber composite materials comprising piezoelectric materials, three-dimensional active fiber composite materials comprising piezoelectric materials, and / or similar utensils , which can convert sound pressure oscillations in the air into corresponding electrical signals. The rectifier ("rectifier") 3 converts the electrical signals from the transducer 2 into direct current. Component 4 represents a variant of an external charge controller - also charging circuit. Component 5 represents another variant, in which the charge controller is installed in the memory («accumulator»). Charge controllers sometimes use several parameters for charge control: * temperature, * voltage, * capacity, * time, * charging current. The memory 6 - also called accumulator or battery - is not discharged until it has stored the predetermined current value. The discharged current is fed via a buffer 7 to the inverter ("converter") 8. The buffer 7 allows the passage of the stored current from the battery 6 in the direction of the inverter 8, but prevents the flow back into the battery 6. Fig. 2 shows examples of some noise sources. From left to right, symbols are shown for: * - thunderstorms, lightning and thunder, * - powerful wind and storms, * - heavy rain, * - any other sources of noise, e.g. caused by road and motorway traffic, construction machinery, waves beating hard on the coast. Fig. 3 shows a connected to the mains residential building, which is within the influence of the noise sources, wherein the reference numerals 11, 12, and 13 designate possible locations to install there sound transducer, preferably in the form of known piezoelectric Fabrics, active fiber composite materials comprising piezoelectric materials or three-dimensional active fiber composite materials comprising piezoelectric materials. Fig. 4 shows a connected to the mains power greenhouse construction, which is also within the sphere of influence of noise sources, wherein the reference numeral 14 denotes an example of a place where sound transducers can be mounted. Fig. 5 shows an example of a railway that is powered by electricity, wherein the reference numeral 15 denotes the power grid connection and the reference numeral 16 indicates an on and / or in the railway mounted inventive device, the sound energy obtained from noise in converts electrical energy and feeds it into the grid as alternating current. Fig. 6 shows a tunnel section 17, which can also be used for mains operated railways. The droning Hall resonance energies produced by fast-moving railways within this route are detected by the device according to the invention present in the respective railways and the sound energy obtained from noise is converted into electrical energy and then fed into the power grid as alternating current. Alternatively or additionally, the inventive device can be attached to the tunnel wall in order to convert the noise generated by the railway into electrical energy and feed it into the power grid. Fig. 7 shows an example of buildings that are connected to the mains and are provided with mounted inventive devices and are in the range of audible noise-sound energy of the waves striking the coast. The recorded noise noise energies are detected by the devices according to the invention present in the building and the sound energy obtained from noise is converted into electrical energy and then fed into the power grid as alternating current. claims 1. A method for generating electrical, in a power grid (10) einspeisbarer energy from the sound energy of at least one noise source (1), wherein at least one sound transducer (2) is used, which detects the sound energy and converts it into electrical signals, wherein the electrical signals Rectifier (3) are supplied, which converts them into a direct current, which is fed via a charge controller (4, 5) to a memory (6, 7), wherein the memory (6, 7) an inverter (8) energized with direct current, the inverter (8) converts into an alternating current whose voltage value is transformed by means of a transformer (9) to the voltage value of the power network (10), wherein the transformed alternating current is fed into the power grid (10). Method according to one of the preceding claims, characterized in that a piezoelectric fabric is used as the sound transducer (2), preferably a fabric in the form of active fiber composite materials comprising piezoelectric materials, in particular three-dimensional active fiber composite materials, the piezoelectric materials include. 3. The method according to any one of the preceding claims, characterized in that are used in carrying out the method components for generating, converting and / or storing electrical energy, which are used by at least one other plant for power generation, in particular a solar system and / or wind turbine , 4. An apparatus for generating electrical energy from sound energy of at least one noise source (1) which can be fed into a power supply (10), the apparatus comprising the following components: - at least one sound transducer (2) for detecting the sound energy and converting it into electrical signals, a rectifier (3), to which the electrical signals can be fed in order to convert them into direct current, a charge regulator (4, 5) which is connected downstream of the rectifier (3) and to which the direct current can be supplied, a memory (6, 7), in which the direct current supplied via the charge controller can be stored, - an inverter (8), which is connected downstream of the memory (6, 7) and is adapted to convert direct current from the memory (6, 7) into alternating current, and - A transformer (9) for transforming the alternating current to the voltage of the power grid (10) to which the transformer (9) is coupled to the transformed alternating current feed. 5. Apparatus according to claim 4, characterized in that the sound transducer (2) is part of a piezoelectric fabric. 6. Use of the device according to claim 4 or 5 for generating electrical, in a power grid (10) einspeisbarer energy, in combination with another system, with which electrical energy from solar and / or wind power can be generated. 7. Use of the device according to claim 4 or 5 for generating electrical, in a power grid (10) feedable energy by the components inside and / or outside of a building and / or an electrically operated vehicle are mounted. 8. Use of the device according to claim 4 or 5 for generating electrical, in a power grid (10) einspeisbarer energy by at least the at least one sound transducer (2) is mounted on the inner wall of a covered passage for vehicles.