RU183847U1 - Sectioned Piezoelectric Generator - Google Patents

Abstract

Sectioned piezoelectric generator refers to electromechanical energy converters, namely to piezoelectric generators operating on the basis of the use of piezoelectric materials, and can be used in any field of technology as a current source. The generator contains a piezoelectric transducer made in the form of a flat round bimorph sectional plate with a load in the center to reduce the frequency of its own resonance and consisting of a set of polarized flat piezoelectric elements combined in sections. The plate is cut into sectors unequal to each other, thereby the piezoelectric generator operates in a non-resonant mode. Piezoelectric elements inside each section, as well as sections between themselves, are electrically connected in series or in parallel. The generator contains a resistor, a rectifier, a storage capacitor, a circuit that controls the charge of the capacitor and a battery. Achievable technical result - the expansion of the passband of the piezoelectric generator.

Description

The utility model relates to electromechanical energy converters, namely to piezoelectric generators operating on the basis of the use of piezoelectric materials, and can be used in any field of technology as a current source.

A known piezoelectric direct current generator, for example RU 2113757, containing a piezoelectric element made in the form of a flat bimorph disk mounted in the center of the disk, and axially deformed by two rollers mounted on the rotor through a flexible insulating gasket. The piezoelectric element may contain many piezoceramic discs to increase power. When the rotor rotates from an external source of mechanical energy, the rollers that are mounted relative to the disk elements in such a way that their deformation is ensured are rolled along the gasket, deforming the piezoelectric elements. When the piezoelectric elements are deformed on the electrodes due to the direct piezoelectric effect, charges arise, while on the external electrodes of the piezoelectric element - charges of the opposite sign, which make up the potential difference.

During the rotation of the rotor and the circular deformation of the piezoelectric element on the electrodes, a constant potential difference arises, corresponding to the strain value.

The disadvantages of this generator are that it is driven by an external energy source, such as wind or water, i.e. requires an additional energy conversion device. In addition, by virtue of its design, it is limited by the size of the piezoelectric element, and therefore, the generated energy is also limited. There is no electrical energy storage.

A piezoelectric generator is also known, for example, US 5801475, containing a cantilever-mounted bimorph piezoelectric element that oscillates under the influence of external vibrations, as a result of which, due to the direct piezoelectric effect, a variable potential difference arises, a resistor, a rectifying element, a storage capacitor, and an output regulatory electronic circuit.

The disadvantages of this generator include its small size and cantilever fixing of the piezoelectric element, as a result, low output power and increased fragility. These disadvantages limit the use of such a generator only to microelectronic devices.

Also known is a piezoelectric generator, for example RU 155155, containing a piezoelectric transducer made in the form of a flat round bimorph sectioned plate with a load in the center to reduce the natural resonance frequency and consisting of a set of polarized flat piezoelectric elements combined in sections. The piezoelectric elements inside each section, as well as the sections between themselves, are electrically connected in series or in parallel. The generator contains a resistor, a rectifier, a storage capacitor, a circuit that controls the charge of the capacitor and a battery. The entire generator is placed in a flat, robust housing that attaches to objects subject to vibration and generates electrical energy due to the vibration energy of the object to which it is attached.

The considered solution is the closest in the aggregate of essential features to the proposed solution.

The disadvantage of this generator is the limited frequency bandwidth, as a result, the low output power at non-resonant vibration frequencies. This drawback leads to the need to use such a generator only in a certain frequency band of vibration of the objects to which it is attached.

The problem solved by the proposed utility model is to expand the bandwidth of the piezoelectric generator when using the free vibration energy of various industrial, construction, road and household structures.

The problem is solved due to the fact that the proposed utility model, like the well-known piezoelectric generator, contains a bimorph piezoelectric transducer included in a circuit containing: a resistor, a rectifier, a storage capacitor and an output regulatory electronic circuit. As in the known one, in the proposed generator, the piezoelectric transducer is made in the form of a disk flat bimorph sectioned transducer, equipped with a load to reduce the frequency of its own resonance, placed in a strong rigid case, the transducer sections are electrically connected to each other, and each section consists of several piezoelectric elements glued together and electrically connected to each other. In contrast to the known piezoelectric generator, in the proposed solution, the bimorph plate consists of a set of sectors unequal to each other.

The technical solution presented here proves the technical result achieved, namely, an increase in the bandwidth of the transducer, since each sector of the bimorph plate has different sizes and masses, the frequencies of their own vibrations will be different, so the frequency band of the piezoelectric generator becomes wide.

The set of features formulated in paragraph 2 of the utility model formula characterizes a piezoelectric generator in which the transducers in each section are connected in series.

An additional technical result achieved is an increase in the output voltage of the piezoelectric generator and a decrease in the generator’s own electric capacity.

The set of features formulated in paragraph 3 of the utility model formula characterizes a piezoelectric generator in which the transducers in each section are connected in parallel.

An additional achievable technical result is an increase in the electric charge generated by the piezoelectric generator.

The utility model is illustrated by drawings, where:

in FIG. 1 shows a diagram of a piezoelectric generator;

in FIG. 2 is a schematic illustration of an embodiment of a component of a piezoelectric generator — a bimorph transducer;

The piezoelectric generator (Fig. 1) has a bimorph piezoelectric transducer 1 (Fig. 2), a resistor 2, a rectifier 3, a storage capacitor 4, a circuit that controls the charge of the battery 5 and the battery 6.

The piezoelectric transducer (Fig. 2) is made in the form of a flat bimorph round circular sectioned plate, clamped around the perimeter, consisting of a set of flat piezoelectric elements combined in sections 7-10 by gluing or soldering. The piezoelectric elements inside each section, as well as the sections between themselves, are electrically connected in series or in parallel, depending on what voltage and what power is required from the piezoelectric generator. In the above example, the converter (Fig. 2), the upper part consists of four sections 7-10 with three elements in each, connected in series. All sections are connected in parallel. A similar device has a lower part, which also consists of four sections of three elements each. The electrodes of the upper and lower parts are soldered to leads 11, 12, from which the alternating voltage is removed and then goes to the rectifier. The upper and lower parts are glued to the base metal elastic round plate 13, cut into unequal sectors. To reduce the natural frequency, the converter is equipped with a load 14 fixed in the center of the plate. The sections are clamped around the perimeter and are connected to each other only in the center - at the place of cargo placement.

The transducer generally rests on a plate 15 tightly mounted on an oscillating surface. Thus, the piezoelectric generator can withstand large static and dynamic loads without breaking.

The output voltage of the converter through the matching resistor 2 is fed to the input of the rectifier 3, and then the rectified voltage is fed to the input of the storage capacitor 4. After the storage capacitor through the electronic control circuit 5, the voltage is supplied to the input of the battery 6.

The generator operates as follows.

The bimorph converter 1 is attached to a vibrating element of a building, industrial, domestic or road structure, for example, to the floor, or to a road or railway track. In this case, the converter can oscillate at the frequencies of the bending resonances of each of the sectors under the action of an external exciting force f. Moreover, due to the fact that each sector has different sizes and masses, the frequencies of their own vibrations will be different, so the frequency band of the generator becomes wide. The amplitude of the alternating voltage at the output of the converter in this case is maximum. During vibration, as a result of the direct piezoelectric effect, an alternating voltage arises at the output of the converter, which is supplied to resistor 2, and then to rectifier 3. After rectification, the electric charge is accumulated on the storage capacitor 4, then fed to circuit 5, which controls the battery charge. The energy of a charged battery is used by the consumer. Thus, the free energy of vibration of various objects is used.

Achievable technical result - the expansion of the passband of the piezoelectric generator.

Claims (3)

1. A partitioned piezoelectric generator comprising a piezoelectric transducer housed in a sturdy flat casing and made in the form of a multilayer flat round circular sectioned bimorph transducer, the sections of which are electrically connected to each other and contain several glued and electrically interconnected piezoelectric elements, with a load in the center, included in a circuit consisting of a resistor, a rectifier, a storage capacitor and a battery with a charge current regulator, characterized I mean that the sizes of the sections of the piezoelectric transducer are not the same sizes and are mechanically separated from each other. 2. The piezoelectric generator according to claim 1, characterized in that the transducers in each section are connected in series. 3. The piezoelectric generator according to claim 1, characterized in that the transducers in each section are connected in parallel.

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