WO2006003052A1

WO2006003052A1 - System for generating electrical energy for electrical components

Info

Publication number: WO2006003052A1
Application number: PCT/EP2005/052238
Authority: WO
Inventors: Jakob Schillinger; Joachim Hrabi; Wilfried Babutzka; Dietmar Huber; Adrian Cyllik
Original assignee: Continental Aktiengesellschaft; Lutz, Rainer
Priority date: 2004-07-01
Filing date: 2005-05-17
Publication date: 2006-01-12
Also published as: DE102004031810A1; DE102004031810B4

Abstract

The invention relates to a method for generating electrical energy for electronic components, comprising a piezoelectric element (1, 11, 110) which is located in a pneumatic vehicle tire having a tire tread (2) located on the outside. Said piezoelectric element (1, 11, 110) is located on the tire inside opposite the tire tread (2).

Description

Continental Corporation:

description

SYSTEM FOR GENERATING ELECTRICAL ENERGY FOR ELECTRICAL COMPONENTS

The invention relates to a system for generating electrical energy for electronic components with a piezoelectric element which is arranged on a pneumatic vehicle tire having a tread arranged on the outside.

Vehicle tires, in particular motor vehicle tires, are increasingly being equipped with transponders that contain or record information about the tire and send it to evaluation devices on or in the vehicle. In addition, operating parameters of vehicle tires, such as temperature or air pressure, as well as the mileage can be sent via corresponding transmitting devices from the vehicle tire to evaluation units. "

DE 440236 A1 discloses a system for determining the operating parameters of vehicle tires, in which a carrier unit, which carries a sensor unit with at least one detector and an evaluation electronic unit, is integrated in the vehicle tire. On the carrier body serving for supplying energy to the system components piezoelectric element is arranged, which also serves as a sensor for the tire revolutions. Likewise, the carrier body is provided with a data transmission unit. The system is integrated in the tire rubber, so that due to the piezoelectric effect due to the cyclic changing in the tire rubber hydrostatic compressive stress electrical energy is obtained. The object of the present invention is to provide an improved system which allows a higher energy yield. According to the invention this object is achieved by a system having the features of claim 1. Advantageous developments of the invention are set forth in the subclaims.

The electric power generation system for electronic components of the present invention having a piezoelectric element disposed on a vehicle pneumatic tire having a tread disposed on the outside provides that the piezoelectric element is attached to the piezoelectric element

Tire inside is arranged opposite the tread. It has been found that in the operation of a vehicle tire, high, sudden changes in the centripetal forces occur when the rolling of the tire, the transition to the tire footprint takes place. There are very high jumps in the course of Zentripetalbeschleunigungen both when hitting the driving surface and when leaving the driving surface. Due to the high acceleration changes, it is possible to produce a very large piezoelectric effect so that a large amount of electrical energy.

A further development of the invention provides that the piezoelectric element is designed as a bending beam, a piezo stack with stacked piezoelectric elements or as a torsion element that generates electrical energy due to the sudden change in the course of Zentripetalbeschleunigung. The rotational movement of the tire generates centrifugal and centripetal forces at the location of the piezoelectric element. These act on the piezoelectric element depending on its structure as pressure, bending, torsional and / or shear forces, which generates electrical energy. The dominant force component is determined by the selected mechanical and electrical design of the piezoelectric element.

A development of the invention provides that the piezoelectric element formed as a bending beam is mounted between two contact gaps, which in turn are connected via a rectifier circuit to a charge storage. The charge storage device can be designed, for example, as a rechargeable battery, electrolytic capacitor or capacitor, preferably a ceramic capacitor.

In a design as stacked piezoelectric elements in the form of a piezo stack this is arranged on an electrically leitfohigen layer to direct the electrical energy from there to the consumer or the electric charge storage.

Preferably, the piezoelectric elements or the piezoelectric element are mounted on a carrier which is arranged on or in the tire inner side. On this support, the rectifier circuit and other line elements or electronic components are arranged, which are supplied with electrical energy. The arrangement on a carrier has the advantage of a mechanical protection of the components arranged thereon.

Further protection of the piezoelectric element and the electronic components is afforded by a cover, which is preferably arranged on the carrier and comprises the electronic components. The cover is optionally formed as a solid housing or as a Globtop, wherein the highly elastic glob-top shell protects the piezoelectric element against a fixation by a potting compound.

A development of the invention provides that the piezoelectric element offset from each other arranged contact surfaces are assigned to the

Determination of lateral or longitudinal acceleration associated with an evaluation circuit. In this way, e.g. the direction of rotation of the tire so that the direction of movement of the vehicle tire and the vehicle are detected.

The system further provides that a transponder or a transmitting device for transmitting stored or determined data with respect to the tire with is connected to the piezoelectric element and is powered by this with energy.

To increase the piezoelectric effect, at least one seismic mass is arranged on the piezoelectric element, preferably the transponder forms this seismic mass.

An attachment of the piezoelectric element to the inside of the tire is carried out via a belt or a belt, a potting compound protects the transponder from damage.

Embodiments of the invention will be explained in more detail with reference to the accompanying figures. Like reference numerals in different figures indicate like components. Show it:

Fig. 1 - a schematic representation of a tire;

2 shows a course of a rotational angle-dependent ^x centrifugal acceleration over a complete tire revolution;

Fig. 3 - a first embodiment of a piezoelectric generator in a housing;

FIG. 4 shows a piezoelectric generator according to FIG. 3 with a glob top; FIG.

5 shows a variant of a piezoelectric generator with Globtop.

Fig. 6 is a piezoelectric generator according to FIG. 5 with elastic

Contact layer; Fig. 7 - a detail view of a contact layer according to

Figure 6;

8 shows a schematic view of a sensor transponder; such as

Fig. 9 - a mounted sensor transponder assembly.

1, a tire mounted on a rim 3 is shown, on the outer circumference of which a running tire 2 is arranged. On the inside of the tire, opposite the tread 2, a sensor transponder 1 with a piezoelectric element for measuring tire-specific characteristic values is fastened. Due to the wheel load rolling on a roadway 5 tire is flattened in the area of a tire contact patch 6, namely the Eindrückstrecke 4th

In FIG. 2, the angle-dependent course of a centripetal acceleration a is shown via the rotational angle β of the tire, depending on the location at which the piezoelectric element is located in the sensor transponder 1. If the piezoelectric element is arranged on the rim 3, a constant centripetal acceleration course 8 sets in at a uniform speed. In contrast to a mounting location on the rim, the sensor transponder mounted in the area of the tread only partially describes a circular path; in the area of the ground contact area, it moves on a straight line. This fact leads to acceleration changes, over which the piezoelectric effect can be exploited. Around

Tire contact patch 6 does not act Zentripetalbeschleunigung a on the piezoelectric element in a sensor transponder 1. Based on the acceleration peaks in the inlet area E and outlet area A and reducing the acceleration to zero, a tire speed detection can be performed. The arrangement of the piezoelectric element on the inner side of the tire results in a high change in the acceleration of the piezoelectric element, since the Centripetal acceleration a is greater, the farther the piezoelectric element is from the fulcrum.

Fig. 3 shows a possible structure of a piezoelectric generator on a tire inside, in which on a support 9, preferably a support plate, a piezoelectric bending beam 11 are mounted between two contact blocks 10. The contact blocks 10 are electrically conductive and connect the piezoelectric bending beam 11 with a direction detection circuit, which is shown in FIG. From there, cables move to a charge storage.

In order to ensure the freedom of movement of the bending beam 11, a housing 12 is arranged as a hood over it, while an inelastic encapsulation 13 mechanically protects the overall arrangement on the inside of the tire. The attachment of the piezoelectric generator via a belt or a belt to the inside of the tire or is glued or vulcanized to the inside of the tire.

By the acceleration forces, as shown in Figure 2, the ends of the bending beam 11 are moved in the direction of the double arrows and deform the bending beam 11. As a result, electrical energy is generated due to the piezoelectric effect. The piezoelectric bending arc of FIG. 3 and 4 can be implemented as a single layer, multilayer or as a piezo-metal composite.

Ih of Fig. 4 is a variant of the piezoelectric generator 1 is shown in the

Functioning and construction differs from that of FIG. 3 in that, instead of a rigid hood 12, a highly elastic globtop 16 protects the bending beam 11 from being blocked by a rigid potting compound 13. Due to the elasticity of the globtop sheath, it is possible that the bending beam 11 may deform due to the acceleration forces, which act on the sensor transponder 1 as a result of the assembly as it moves into and out of the area of the tire footprint 6. An alternative embodiment of the piezoelectric element is shown in FIG. 5, in which, instead of a bending beam 11 according to FIGS. 3 and 4, a multilayer axial sensor 110 designed as a piezo element is mounted on the carrier 9 via an electrically conductive layer 14. The assembly can over

Gluing, soldering or lending press done. In addition, a seismic mass 15 is applied to the axial sensor 110 formed as a piezoelectric element in order to increase the piezoelectric effect. Surrounding the sensor transponder 1 is again from a Globtop 16, which causes a separation of a solid potting compound 13 and allows movement of the piezoelectric element.

An alternative embodiment of the piezoelectric generator 1 is shown in FIG. 6, in which the elastic contact layer 14, as shown in FIG. 7, is designed as a facet-shaped contact layer which serves to detect the direction. In this case, wiring-side contacting surfaces 111, 112, 113 of the

Piezoelementes 110 executed in facet form, whereby it is possible to additionally detect the transverse and longitudinal accelerations by forming differences on the pad voltages. It can also be seen that three of the contact surfaces 111, 112, 113, 114 are connected to a differentiating circuit.

8 shows the basic structure of a sensor transponder 1 with a support plate 9, on which a piezoelectric element 110 is arranged, on which a seismic mass 15 is positioned. In order to enable mobility due to the centripetal accelerations, the arrangement of the piezoelectric element 110 and seismic mass 15 is protected by a housing 12 or globtop. A capacitor 17 serves as a charge storage, also an ECU 18 is arranged on the support plate 9, connected to a transmission device 19, for example a transmitter. In addition, pressure and temperature sensors can be mounted on the support plate 9 and polled by the ECU 18. Due to the basic structure and the arrangement of a sensor transponder 1 on a tire inside in the equatorial plane of the tire, a piezoelectric generator is provided which serves to charge an electric charge storage 17 or as an additional source of energy for battery or high frequency powered transponder systems. The power generator uses the acceleration that acts on a tire-mounted transponder module during wheel rotation. From a certain charging voltage, the measurement can be started via a sensor and subsequently the transmission via the transponder. Triggering can take place either asynchronously when a certain charge is reached or synchronously as an external request. Quartz, piezoceramics or piezo foils are suitable as piezo material, which can be used as a piezo stack 110 as pure axial force sensors in a multilayer stacking. Alternatively, the formation of the piezoelectric element is provided as a bending beam 11. It is also possible to utilize shear forces or torsional forces by means of a corresponding arrangement of the piezoelectric elements.

Especially at the transition in and out of the tire footprint, high changes in the acceleration forces act on the piezoelectric element resulting in charge shifts. The rectifier circuit connected to the piezoelectric element polarizes this charge and stores it in a charge quantity memory, such as capacitor 17. The capacitor 17, the circuit 18 and the transponder electronics 19 are protected in a rigid potting compound 13 or a mold, while a globtop elastic sheath 16 or a housing 12 protect the piezoelectric element and allow mobility.

The energy generated by the piezoelectric element can be collected via powerful capacitors. This energy is used to power the ECU 18, the RF link and the sensor electronics. Furthermore, the piezoelectric element can serve as an energy generator for operating a micropump, which compensates for diffusion losses in a tire, without additional energy needs to be supplied. The piezoelectric generator enables electronics to be saved in the wheel housing and higher transmission ranges, which leads to a reduction in the number of transmitting antennas. It is also possible to use relatively small generators with piezoelectric elements due to the high centripetal accelerations.

FIG. 9 shows a mounted sensor transponder arrangement in which a piezoelectric element 11 is arranged on a wiring carrier. In addition, there are electrical sounding 18 of the sensor transponder and possibly an additional acceleration sensor 30 on the carrier 9. The piezoelement 11 is connected to the carrier 9 via a contacting layer 25. The mechanical connection of the piezoelectric element 11 to the tire inner side 21 via an elastic coupling layer 22. This elastic coupling layer 22 allows the piezoelectric element 11 moves at a change in acceleration and generates electrical energy. The wiring carrier 9 is partially encapsulated with a molding material 13 '. The electrical connection of the wiring substrate 9 via lead frame 23, which in turn is connected to connector pins 20. In addition, a mechanical fixation of the protected by the mold material 13 'sensor transponder within the housing 12 via a potting compound 13. The housing 12 is connected via a peripheral connection point 24, for example, formed as a belt or band, connected to the tire inner side 21. The housing 12 can also be vulcanized in the tire inner side 21. The forces acting on the piezoelectric element forces may be axial, bending, shear or torsional forces. A coupling of the piezoelectric element 11 to the tire 1 via the elastic coupling layer 22, which may also be formed as a visco-elastic adhesive layer.

Claims

claims

1. System for generating electrical energy for electronic

Components with a piezoelectric element, which is arranged in a pneumatic vehicle tire having a tread arranged on the outside, characterized in that the piezoelectric element (1, 11, 110) on the tire inner side (21) of the tread (2) is arranged opposite ,

2. System according to claim 1, characterized in that the piezoelectric element (1) is designed as a bending beam (11), piezo stack (110) or as a torsion element.

3. System according to claim 1 or 2, characterized in that the bending beam (11) between contact blocks (10) is mounted.

4. System according to claim 1 or 2, characterized in that the piezoelectric stack (110) arranged on an electrically conductive layer (14)

"Is.

5. System according to one of the preceding claims, characterized in that the piezoelectric element (1, 11, 110) on a support (9) is mounted, which is arranged on or in the tire inner side (21).

6. System according to claim 5, characterized in that between the carrier (9) and the tire inner side, an elastic coupling layer (22) is arranged.

7. System according to any one of the preceding claims, characterized in that the piezoelectric element (1, 11, 110) is provided with a cover (12, 16).

8. System according to claim 7, characterized in that the cover (12, 16) is designed as a housing or Globtop.

9. System according to any one of the preceding claims, characterized in that the piezoelectric element (110) offset from one another arranged contact surfaces (111, 112, 113) are associated, which are connected to determine transverse or longitudinal acceleration with an evaluation circuit.

10. System according to any one of the preceding claims, characterized in that a transponder with the piezoelectric element (1, 11, 110) is connected.

11. System according to any one of the preceding claims, characterized in that on the piezoelectric element (1, 11, 110) at least one seismic mass (15) is arranged.

12. System according to claim 10 and 11, characterized in that the transponder forms the seismic mass (15).

13. System according to any one of the preceding claims, characterized in that the piezoelectric element (1, 11, 110) in a potting compound (13) is embedded.

14. System according to any one of the preceding claims, characterized in that the piezoelectric element (11, 110) is part of a sensor transponder (1).