Patent Application
20230070841
The present application relates to a cantilever for an energy harvesting system and, in particular, to an improved cantilever for a piezoelectric energy harvesting system.
There are many unutilized energy sources in the environment, for example, thermal energy, electromagnetic waves, and mechanical vibrations. To convert these ambient energies into electric energy, energy harvesting technologies have been developed. Energy harvesting technologies can, for example, be used as an energy source for a battery of a wireless sensor. There are further various energy sources for energy harvesting such as solar power, thermal energy, wind power, and vibration. Further, there are three main types of vibration energy harvesters generation methods: electromagnetic, electrostatic, and piezoelectric.
Therein, energy harvesting technology using piezoelectric materials is one such method that utilizes mechanical energy from various sources such as human motion, acoustic noise, or wind to convert energy into an electric current. When mechanical energy such as an acoustic wave is applied to a piezoelectric polymer film, electrical charges are induced between the two surfaces. Using this property, a piezoelectric material can be applied as an electromechanical energy converter.
The document U.S. Pat. No. 7,649,305 B2 discloses a mechanism for capturing mechanical energy and converting it to electrical energy for use in continually charging or providing emergency power to mobile, battery-powered devices, which comprises a plurality of elongated piezoelectric elements mounted at one or more support points to one or more support structures. The plurality of piezoelectric elements are preferably structured and arranged so that at least each three-dimensional coordinate axis has at least one element with a dominant mode of deflection in a plane normal to the axis, to permit harvesting energy from forces applied in any direction without regard to the orientation of the energy harvesting mechanism to the source of forces.
Among piezoelectric materials, respectively polymers which have strong piezoelectric effects when subjected to mechanical stretching or external excitation, polyvinylidene fluoride (PVDF) films have a comparatively high piezoelectric effect and are, at the same time, cheap and easy to manufacture, chemically inert, lightweight and safe to us. However, as these films are usually very thin, polyvinylidene fluoride films are usually not used as a basis for piezoelectric energy harvesting systems due to their fragility and the very short response times.
It is an object of the present invention to provide an improved cantilever for a piezoelectric energy harvesting system.
According to one embodiment of the invention, a cantilever for a piezoelectric energy harvesting system is provided, wherein the cantilever comprises two layers formed of polyvinylidene fluoride, and wherein a core layer formed of a shim material is sandwiched between the two layers formed of polyvinylidene fluoride.
Therefore, a cantilever for a piezoelectric energy harvesting system is provided, which is based on polyvinylidene fluoride films. Thus, it can be taken full advantage of the use of polyvinylidene fluoride as a piezoelectric material, and, in particular, that polyvinylidene fluoride films have a comparatively high piezoelectric effect and are, at the same time, cheap and easy to manufacture, chemically inert, lightweight and safe to us. On the other hand, however, the problems that usually arise when a cantilever for a piezoelectric energy harvesting system should be based on polyvinylidene fluoride films can be neglected, due to the configuration of the cantilever. For example, the fragility of the cantilever based on polyvinylidene fluoride can be reduced by placing a core layer formed of a shim material between the two layers formed of polyvinylidene fluoride. Therefore, an improved cantilever for a piezoelectric energy harvesting system is provided.
Therein, the two layers formed of polyvinylidene fluoride can have a predominantly β-type crystal structure. Polyvinylidene fluoride has four crystalline phases α, β, γ, and δ depending on the chain conformation. Among them, a is thermodynamically the most stable and nonpolar innature. β and γ are polar phases, wherein crystalline phase β is of great importance due to its spontaneous polarization and piezoelectric sensitivity. Thus, the cantilever can be further improved when the two layers formed of polyvinylidene fluoride have a predominantly β-type crystal structure.
Further, the cantilever can have the form of a rectangular plate, wherein the longitudinal sides of the rectangular plate are longer than the broadsides of the rectangular plate, and wherein the cantilever (is configured in such a way, that the cantilever can be connected to a device which stores or uses energy via one of the longitudinal sides. By configuring the cantilever in such a way, that a longer side of the cantilever can be electrically or electrically and mechanically connected to a device which stores or uses energy, the robustness can be further improved, and therefore, the fragility of the cantilever based on polyvinylidene fluoride be further reduced.
As shim materials, aluminum, steel, brass, and laminated plastic, respectively polyethylene terephthalate (PET) are commonly used.
Therein, according to one embodiment, the core layer can be formed of steel. The use of steel as material for the core layer has the advantage that the cantilever can vibrate in the greatest possible resonance frequency, wherein, at the same time, the vibration wave can be as long as possible.
Further, a core layer formed of steel preferably has a thickness between 50 μm and 150 μm, to achieve the greatest power output.
According to another embodiment, the core layer is formed of polyethylene terephthalate (PET). The use of polyethylene terephthalate as material for the core layer has the advantage that comparatively great power output can be achieved.
Further, a core layer formed of polyethylene terephthalate preferably has a thickness between 400 μm and 560 μm, to achieve the greatest power output.
Further, each of the two layers formed of polyvinylidene fluoride can have a thickness between 20 μm and 50 μm. That the polyvinylidene fluoride layers respectively have a thickness between 20 μm and 50 μm has the advantage, that applied kinetic stress can be converted in a very efficient way. Further, if the layers are too thin there is a potential for migration of extractants through the layers and potential attack from the contents to permeate through the PVDF layers and attack other materials in the construction. Thicker layers would additionally add unnecessary costs.
The two layers formed of polyvinylidene fluoride can respectively be bonded to the core layer by an epoxy resin. By using epoxy resin to secure the polyvinylidene fluoride layers to the core layer, the flexibility of the composition can be enhanced, wherein, at the same time, the risk of breakage of the composition can be further reduced. Furthermore, the use of epoxy resin results in excellent mechanical properties, as well as aging resistance, heat resistance, and corrosion resistance of the composition.
Further, electrodes can be formed on and under each of the two layers formed of polyvinylidene fluoride. By sandwiching the polyvinylidene fluoride layer between two electrodes, a simple, flexible, and compact design is provided capable of producing high volume power densities.
Therein, the electrodes can be formed of aluminum, nickel, or copper. Thus, the electrodes can simply be formed by sputtering metal on the polyvinylidene fluoride film, wherein the metallization of the PDVF film can include aluminum, nickel, or copper, and wherein an electrode can be provided that is more compliant and less susceptible. However, that the electrodes are formed of aluminum, nickel or cooper should merely be understood as an example and other materials can be used for forming the electrodes respectively a metallization on the polyvinylidene fluoride layer, too, for example, chromium, gold, silver, platinum, rhodium, alloys of any of the foregoing, and the like.
According to a further embodiment of the invention, a piezoelectric energy harvesting system is provided, which comprises a cantilever as described above and a device that stores or uses energy, wherein a first end of the cantilever is electrically connected to the device which stores or uses energy.
Therefore, a piezoelectric energy harvesting system is provided, which comprises a cantilever that is based on polyvinylidene fluoride films. Thus, it can be taken full advantage of the use of polyvinylidene fluoride as a piezoelectric material, and, in particular, that polyvinylidene fluoride films have a comparatively high piezoelectric effect and are, at the same time, cheap and easy to manufacture, chemically inert, lightweight and safe to us. On the other hand, however, the problems that usually arise when a cantilever for a piezoelectric energy harvesting system should be based on polyvinylidene fluoride films can be neglected, due to the configuration of the cantilever. For example, the fragility of the cantilever based on polyvinylidene fluoride films can be reduced by placing a core layer formed of a shim material between the two layers formed of polyvinylidene fluoride.
Further, at least one tip mass can be attached to a second end of the cantilever, wherein the second end of the cantilever is opposite the first end. By adding at least one tip weight to a second, free end of the cantilever, the level of vibrations can be increased and the resonance levels controlled.
Therein, a weight of the at least on tip mass can be customized, whereby the resonance frequency of the piezoelectric energy harvesting system can be customized to the real need of the application where it should work.
Furthermore, according to one embodiment, a first tip mass is attached to a top surface of the second end of the cantilever band a second tip mass is attached to a bottom surface of the second end of the cantilever. By placing such an additional mass on a surface of the cantilever opposite to a surface of the cantilever where the first tip mass is placed, a vibration time of the cantilever can be increased. Further, based on the ratio of the weight of the first tip mass to the weight of the second tip mass, the output voltage can be increased.
Embodiments of the invention will now be described with reference to the drawings.
As shown in
Piezoelectric energy harvesting systems 1 comprise elements that cause bending, contraction, extraction, etc. in a piezoelectric layer using vibration or pressure and thus generate an alternating current voltage by a piezoelectric effect. Thus, kinetic energy is converted into electrical energy.
These piezoelectric energy harvesting systems 1 are variously applied in that they can use pressure or vibration caused by the exercise of a person, pressure or vibration caused by a vehicle such as a car, and pressure or vibration caused by a natural environment, etc.
Among possible piezoelectric materials, polyvinylidene fluoride (PVDF) films have a comparatively high piezoelectric effect and are, at the same time, cheap and easy to manufacture, chemically inert, lightweight and safe to us. However, as polyvinylidene fluoride films are usually very thin, polyvinylidene fluoride films are usually not used as a basis for piezoelectric energy harvesting systems due to their fragility and the very short response times.
According to the embodiments of
Therefore, a cantilever 2 for a piezoelectric energy harvesting system 1 is provided, which is based on polyvinylidene fluoride films. Thus, it can be taken full advantage of the use of polyvinylidene fluoride as a piezoelectric material, and, in particular, that polyvinylidene fluoride films have a comparatively high piezoelectric effect and are, at the same time, cheap and easy to manufacture, chemically inert, lightweight and safe to us. On the other hand, however, the problems that usually arise when a cantilever for a piezoelectric energy harvesting system should be based on polyvinylidene fluoride films can be neglected, due to the configuration of the cantilever. For example, the fragility of the cantilever based on polyvinylidene fluoride can be reduced by placing a core layer formed of a shim material between the two layers formed of polyvinylidene fluoride. Therefore, an improved cantilever for a piezoelectric energy harvesting system is provided.
According to the embodiments of
In the shown piezoelectric energy harvesting system 1, the level of vibrations amplitude can be increased and the resonance levels controlled by attaching at least one tip mass to a distal or second, free end 7 of the cantilever 2.
Therein, according to the embodiments of
Further, the first 8 and the second tip mass 10 are configured to be customized to the real need of the application where it should work. For example, in a known application, the first tip mass is chosen to have a weight of 12 g, and the second tip mass is chosen to have a weight of 7 g.
The shown cantilever 20 comprises two layers 21,22 formed of polyvinylidene fluoride, wherein a core layer 23 formed of a shim material is sandwiched between the two layers 21,22 formed of polyvinylidene fluoride.
Therein, the two layers 21,22 formed of polyvinylidene fluoride respectively have a predominantly β-type crystal structure. Each of the two layers 21,22 formed of polyvinylidene fluoride can, for example, be poled to change its phase from α to β by placing the layer under a high electrical field and heating it to a certain temperature, wherein the layer is kept or maintained under the high electrical field for a required amount of time.
Further, the shown cantilever 20 has the form of a rectangular plate, wherein the longitudinal sides of the rectangular plate are longer than the broadsides of the rectangular plate, and wherein the cantilever 20 is configured in such a way, that the cantilever 20 can be connected to a device which stores or uses energy via one of the longitudinal sides.
Therein, each of the layers formed of polyvinylidene fluoride can be prepared in such a way, that it has an approximate length between 60 mm and 80 mm and an approximate width between 10 mm and 20 mm. In particular, according to the embodiments of
According to the first embodiment, the core layer 23 is formed of steel. The use of steel as the material for the core layer has the advantage that the cantilever can vibrate in the greatest possible resonance frequency, wherein, at the same time, the vibration wave can be as long as possible.
Therein, the core layer 23 formed of steel has a thickness between 50 μm and 150 μm, to achieve the greatest power output.
Further, each of the two layers formed of polyvinylidene fluoride has a thickness between 20 μm and 50 μm, to convert the applied kinetic stress in a very efficient way.
As shown in
There are further shown layer electrodes 26a,26b,27a,27b which are formed on and under each of the two layers 21,22 formed of polyvinylidene fluoride. These electrodes 26a,26b,27a,27b can be formed to a thickness of several tens to hundreds of nanometers, and can, for example, be formed through a sputtering deposition method.
Further, the electrodes 26a,26b,27a,27b are formed of one of aluminum, nickel, or copper. However, that the electrodes are formed of aluminum, nickel or cooper should merely be understood as an example and other materials can be used for forming the electrodes respectively a metallization on the polyvinylidene fluoride layer, too, wherein the materials for metallization can include chromium, gold, silver, platinum, rhodium, alloys of any of the foregoing, and the like.
As shown in
The difference between the cantilever 30 according to the second embodiment shown in
Therein, the core layer 33 formed of polyethylene terephthalate has a thickness between 400 μm and 560 μm, to achieve the greatest power output.
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2020/071552 | 7/30/2020 | WO |
