RU2470452C1 - Device to produce electric energy by deformation of piezoelectric material under action of outer hydrostatic pressure - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to devices generating electric energy. The device for generation of electric energy comprises a solid body and two covers at the ends, which are deformed under action of hydrostatic pressure. Inside the body there are piezoelectric sensors installed tightly, onto piezoelectric material of which a force is transferred from hydrostatic pressure via covers. Under action of this force piezoelectric material of sensors is deformed, and electric voltage is generated. Some sensors inside the body are connected to each other in series, to increase voltage, creating blocks, and blocks themselves, for increasing of electric current are connected to each other in parallel into a system (8), the output voltage of which (U₁) is also an output voltage of the device. This voltage is sent to terminals (7) through a switch (6).

EFFECT: invention makes it possible to create an electrical energy generator with control of value of produced electric voltage without additional devices.

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Description

The invention relates to devices that generate electrical energy.

A device [1] is known for determining the pressure in a high-current discharge (in a discharge tube), where the deformation of the piezoelectric material in the sensor is carried out by electric charges.

The disadvantage of this device is the high consumption of electrical energy for the deformation of the piezoelectric material, which is many times more than it will be generated.

Known pressure sensor DTC-2 [2], in which the deformation of the piezoelectric material is carried out by air pressure in the intake and exhaust manifolds of the engine.

The disadvantage of this sensor is the high energy consumption for pre-compression of the air, which is much more than the electrical energy generated by the deformation of the piezoelectric material.

The closest, in technical essence, to the claimed device is a device in which integrated piezoelectric sensors [3] are located between the shock absorber connecting the wheel axle with the mass above it and this mass. The mass of the vehicle provides mechanical deformation of the piezoelectric material of the piezoelectric sensors and the creation of electrical voltage in this material.

The disadvantage of this device is that the deformation of the piezoelectric material in it is not uniform in time, and therefore, the output voltage from the integrated sensors is also a variable value. This is because when the vehicle moves on the road, irregularities will occur, when moving through which the gravity from the mass of this vehicle will change. And this requires an additional device for stabilizing the generated electrical voltage. In addition, the constant mass of the vehicle limits the output voltage and current generated by the deformed piezoelectric material of the integrated sensors. Also, with constant weight, there is no way to change the voltage and current from integrated sensors, if necessary.

An object of the invention is to develop a device for generating electrical energy, in which the amount of mechanical deformation of the piezoelectric material will not change in time when generating a fixed value of electrical voltage, but, if necessary, it would be possible to change the degree of this deformation and, as a result, the amount of generated electrical voltage and current.

The technical result of the invention is achieved by a device having integrated piezoelectric sensors, which include piezoelectric material and in which, as a result of mechanical deformation of the piezoelectric material, an electrical voltage is generated, and the device itself contains a rigid rectangular, round or any other shape in plan, at the ends which covers are made of a material capable of elastically deforming under the influence of external hydrostatic pressure. Tightly integrated integrated piezoelectric sensors are located inside the housing, so that the external hydrostatic pressure of water acting on the outer surface of the covers and deforming them elastically, i.e. the position shifting them inside the housing would be transmitted to these sensors and carry out mechanical deformation of the piezoelectric material of these sensors, while part of the piezoelectric sensors are connected to each other in series, forming separate electrical blocks and providing the required voltage value, and the blocks themselves, in turn, are connected with each other in parallel, increasing the value of the electric current flowing through the electric circuit when the consumer is connected. The internal cavity of the casing and the conclusions from it of the electric wires are sealed, and the casing itself is suspended on a rope that has a marking when immersed in water to provide the desired magnitude of the electrical voltage. The rope on which the device is suspended is best made from a corrosion-resistant and durable material, for example, from kapron. It is better to fix the electric two-core sealed wire connected to the blocks of integrated piezoelectric sensors inside the case, not rigidly, but loosely so that there are no mechanical stresses, the load from the mass of the device is completely perceived by the rope. The marking on the rope provides information: to what depth the device was lowered and what electrical voltage is obtained.

What is new is that the device’s body is made rigid and of any shape in plan, into which tightly placed piezoelectric sensors are placed, incorporating piezoelectric material. At the ends, the case is closed by two deformable covers. The internal cavity of the device is sealed, and the conclusions of the electrical wires are also made hermetically. The device itself is suspended on a rope having a marking in the form of the depth of immersion of the device in water and the magnitude of the electrical voltage obtained in this case. The use of new features, in conjunction with the known, and new connections between them ensures the achievement of the technical result of the invention, namely: the creation of an electric energy source with the required characteristics, which can be used in any conditions in the presence of a reservoir, for example, at scientific stations drifting in the Arctic Ocean , at remote weather stations, geological parties, ships, etc.

The invention is illustrated by drawings. Figure 1 presents a section of the device and the loading scheme of the piezoelectric material in the piezoelectric sensors. Figure 2 shows a diagram of the immersion of the device in water and the formation of electric voltage and current. In the proposed device, the hydrostatic pressure of the water “p” is used as the deforming force, see FIG. 1 and FIG. 2, view “a”, when the device 1 is immersed with piezoelectric sensors 9 inside the case, which have a piezoelectric material as their constituent, to a certain depth h. Depending on the immersion depth (either on h ₁ or h ₂ ), the pressure “p” will also act: the deeper the immersion of the device, the greater the value of “p”. This pressure generates a force Q acting on the integrated sensors 9 when the covers 2 are deformed by this force. The magnitude of the force Q is determined by the formula

Q = p in α.

Here: in - the length of the internal cavity of the device; α is its width; and the product (in α) determines the area of action of the force Q (pressure p), where piezoelectric sensors are located under the covers. Figure 2, view "g", shows the dependence of the output voltage U from the piezoelectric sensor, upon deformation of its piezoelectric material, on the magnitude of the deforming force Q (if this dependence is assumed to be directly proportional). This dependence shows that the greater the force Q that deforms the piezoelectric material, the higher the voltage U appearing in this material. In addition to increasing the force Q by immersion to a large depth h, to create the required output voltage for the consumer, the integration (combination) of piezoelectric sensors 9 is used: a part of these sensors is connected to each other, inside the device, sequentially, Fig. 2, view “c”, which summarizes the voltage from each sensor 9, providing a higher voltage U ₁ at the output compared to the voltage U _x from each sensor. The set of sensors connected in this way forms blocks 10 with an output voltage of U ₁ . This voltage will be the output voltage of the device. The number of piezoelectric sensors 9 is selected taking into account the depths of water bodies using the device, the required voltage U ₁ and current when connecting the load. You can provide a fixed value of voltage U ₁ , lowering the device to a predetermined depth h. However, in many cases, different electrical voltages are required for different consumers. For example, for lighting (bulbs) it does not matter what the voltage value is. It can be 6V, and 12V, and 27V, and 220V. But for some consumers, voltage needs to be determined. In particular, charging a motorcycle battery requires a voltage of 6V, for a car battery 12V, for an aircraft battery 27V, etc. Then it is required to change the output voltage U ₁ . To do this, lower the device 1 to different depths: either h ₁ or h ₂ , etc., Fig.2 "a". The deeper the device is lowered, the greater, in magnitude, will be the output voltage U ₁ , because the greater the hydrostatic pressure p, the greater the force Q, the greater the deformation of the piezoelectric material.

The device 1, Fig. 1, includes a rigid (practically non-deforming) body 4 of a rectangular (as shown in the drawing), round or any other shape in plan. Inside the case there is a container formed by its wall. At the ends of the casing there are two covers 2 made of material and thickness, which ensure their deformation under the influence of hydrostatic pressure Between the lids and the housing are placed gaskets 3 to ensure the tightness of the internal capacity of the housing. Along the perimeter of this container is an insert 5 of dielectric material. In the container body 4 are integrated piezoelectric sensors 9, a component of which is a piezoelectric material. The sensors 9 are stacked tightly so that, when the covers are deformed, the latter would begin to exert pressure on the sensors. Part of the sensors 9 are connected in series with each other, forming blocks 10, figure 2 "c". And these blocks are connected to each other in parallel, figure 2 "b". The output of electrical wires from the internal capacity of the device is sealed. Terminals 7 provide a consumer connection. The switch 6 is used to disconnect the device 1 from the consumer without lifting it from a depth and disconnecting the load. The output electrical voltage of the device is voltage U ₁ . It can be measured with a voltmeter. But you can advance on the rope on which the device is suspended and lowered, with its help, into the water, make marks corresponding, when immersed to this depth (the length of the rope corresponds to the depth), to obtain a certain voltage U ₁ . For example, the immersion depth is 10 m, the voltage U ₁ at this depth is 10 V; immersion depth is 50 m, voltage U ₁ is 50 V, etc.

A device for deformation of a piezoelectric material works as follows.

In the initial position, when it is not immersed in water, the hydrostatic pressure p does not act on it, therefore, the covers 2 are not deformed, the piezoelectric sensors 9 are not compressed, and the electric voltage is not generated. When the device 1 is immersed in water at a certain depth h (h ₁ or h ₂ or ...) on the device, the hydrostatic pressure p begins to act on its entire external surface. Case 4 of the device is hard, so it is practically not deformed. The covers 2 are deformed, i.e. their plane moves inside the case. The force Q is provided by hydrostatic pressure p and is determined by the formula: Q = p in α (Fig. 1). The inner surface of the cover 2 is adjacent to the sensors 9. When their surfaces move into the housing on both sides, during deformation, they begin to compress the piezoelectric material of the sensors 9, deforming it. In this case, an electric voltage U ₁ appears at the output of the device. When changing the immersion depth h, the output electric voltage U ₁ and the current strength, which can be used when connecting the load, change.

Using the claimed invention allows to obtain electrical energy without spending material production on its production (not counting the manufacture of the device). This ensures almost complete autonomy and durability of the device, not to mention its complete harmlessness to humans and the environment.

Information sources

1. Website http://polarization.narod.ru.

2. NPP "NTS", Samara.

3. US patent No. 20090045698 A1.

Claims (1)

A device for generating electrical energy by deforming a piezoelectric material under the influence of external hydrostatic pressure, containing integrated piezoelectric sensors, which include piezoelectric material, in which, as a result of mechanical deformation of the piezoelectric material, an electric voltage is generated, characterized in that the device contains a rigid rectangular case , round or any other shape in plan, on the ends of which are placed covers made of material, with individuality elastically deform under the influence of an external hydrostatic pressure; inside the case, tightly integrated integrated piezoelectric sensors are located so that the external hydrostatic pressure of the water acting on the outer surface of the caps and deforming them elastically, i.e. the position shifting them inside the housing would be transmitted to these sensors and carry out mechanical deformation of the piezoelectric material of these sensors, while part of the piezoelectric sensors are connected to each other in series, forming separate electrical blocks and providing the required voltage value, and the blocks themselves, in turn, are connected with each other in parallel, increasing the value of the electric current flowing through the electric circuit when the consumer is connected; the internal cavity of the case and the conclusions from it of the electric wires are sealed, and the case itself is suspended on a rope with a marking when immersed in water to ensure the desired voltage value.

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