Already known are scavenger systems, which generate energy due to the rotation and vibration of the tyre. In these systems the tyre vibration accelerates a mass in combination with a spring. The moving mass can for instance be a magnet inside a coil, which generates a voltage due to the magnet movement. Another way is to apply piezo-type (PZT) material in the spring, which generates a voltage when stressed (See U.S. Pat. No. 7,467,034 B2 and US 2008/0047363 A1). Also a possibility is a system, which uses a stationary magnet in combination with a coil in the tyre. These systems will not generate sufficient power at low rotation speeds and are possibly rather bulky.
The proposed system can generate sufficient power at lower rotation speeds. Also it can be very small and be placed in remote locations.
The invention describes a system where a sensor system inside a tyre needs to be provided with electrical power. The sensors measure for instance acceleration, temperature, pressure and strain. The measured data are transmitted via an RF-link. The power for the system needs to be supplied without any galvanic connections. Poor solutions are scavengers which use the rotation and vibrations in the wheel. A better solution with more constant power is inductive power transfer.
With a special arrangement of coils and a special operating mode a reliable power transfer system can be built, which generates power up very low wheel (tyre) speeds.
Location send and receiver coil is shown in
Space limitations in a car system are shown in
The essential features of the system are:
Feature 1: Special send coil construction and orientation as shown in the
The send coil is placed perpendicular to the tyre and as close as possible to the tyre. This generates a better field inside the tyre and therefore a better coupling factor to the receive coil in the tyre. When coils are facing each other the flux paths are very long, due to the presence of a steel belt in the tyre and the metallic wheel rim.
Coils are supported with a partial ferrite core. This reinforces the magnetic field generation. It also makes the coil properties less dependent on the environment. Metallic objects in the neighborhood of the coil can influence the inductance of the coil. The ferrite core partly functions as a shield and keeps this inductance more constant.
Feature 2: Special receive coil construction and orientation
The receive coil is placed perpendicular to the tyre as shown in
A perpendicular oriented coil will best pick up these flux lines as shown in the
Feature 3: Special operation mode
Another way is to use the inductive path in 2 modes, one mode for sending energy and the other mode for a returning signal that power is generated at a sufficient level. This is schematically shown in
The operation mode of the system could look as following. The sender sends a small test burst to investigate if power is received at a certain. In case of feedback of a sufficient power receive signal the next cycle the sender will generate a full period burst. The full period bursts will stop as soon as no sufficient power receive signal is generated. This is schematically shown in
Number | Date | Country | Kind |
---|---|---|---|
09159920.9 | May 2009 | EP | regional |
09168230.2 | Aug 2009 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/IB2010/051963 | 5/5/2010 | WO | 00 | 11/8/2011 |