WO2004048132A1

WO2004048132A1 - Holding device for fixing an electronic component

Info

Publication number: WO2004048132A1
Application number: PCT/EP2003/012864
Authority: WO
Inventors: Anton Mangold; Josef Schorer
Original assignee: Iq-Mobil Gmbh
Priority date: 2002-11-26
Filing date: 2003-11-17
Publication date: 2004-06-10
Also published as: DE10255138A1; EP1565331A1; AU2003298119A1; JP2006507495A

Abstract

The invention relates to a holding device for fixing an electronic component in a wheel. The holding device comprises at least one device carrier (5) for receiving and holding electronic components (6) and also comprises at least one at least partially elastic damper foot (7) which is permanently flexibly connected to the tyre covering (1). The damper foot (7) has a dampening effect and is configured in such a way that it is elastic and tapered along the longitudinal axis thereof. The damper foot (7) can be fixed to the device carrier (5) and the tyre covering (1) by adhesion or vulcanization, for example. In other embodiments, the damper foot (7) is also produced with the device carrier and the tyre covering in a single piece made of tyre material. Preferably, the damper foot can conduct heat and energy and contains a capacitive or inductive coupling for connecting two electronic components (6) or an antenna.

Description

HOLDING DEVICE FOR FIXING AN ELECTRONIC COMPONENT

The invention relates to a holding device for fastening an electronic component in a wheel containing a tire. Such holding devices are used for fastening sensors, for example, which monitor the tire inflation pressure, the tire temperature or the tread depth, for example of vehicle or aircraft tires, or also of Transponders, which then transmit such identification variables for further evaluation on the on-board computer, are used. Holding devices are known which attach corresponding electronic components within the wheel to the tire valve or to the rim.

However, these known holding devices for fastening electronic components have the disadvantage that they do not allow a free choice of the fastening location of the electronic components. Also, with these known holding devices, the electronic component cannot be attached directly to the tire casing. As a result, it is not possible to measure parameters such as the tire temperature directly at the most stressed point, such as the tread here, directly where they arise. This inevitably leads to falsified measurement results.

Furthermore, electronic components held in this way have to be attached in an additional assembly step, for example on the rim. This leads to additional assembly costs and additional possible sources of error when attaching the electronic component to the wheel. However, faulty or incorrectly mounted holding devices, which are used, for example, to attach a sensor to the valve inside the tire interior, are a great danger. If the electronic component becomes detached due to a faulty attachment, this leads to everything Tire burst rule. Leakage of the valves or the seals between the valve and the tire can also occur by attaching these relatively heavy components to the valves.

Another disadvantage of the known holding devices is that a clear assignment of tire-specific sizes is not possible.

The invention is therefore based on the object of providing a holding device for fastening an electronic component in a wheel, which enables a more precise recording of measured values on the tire.

According to the invention, this object is achieved in that the holding device for fastening an electronic component in a wheel containing a tire casing contains at least one device carrier for receiving and holding the electronic component and at least one damper foot which is permanently elastic and at least partially elastic connected to the tire casing.

The permanently elastic connection of the holding device to the tire casing enables an almost freely selectable fastening position on the tire casing. Permanent elastic means a connection that enables a permanently secure, elastic, flexible connection over the period of use of the tire, even under the influence of strong vibrations and temperature fluctuations.

The tire casing is understood here to mean the tire parts that envelop the tire interior in the broadest sense. It can be attached to both the tread and the side wall of the tire. The attachment can be made directly to the inner surface of the tire casing or in a further inner layer of the tire casing e.g. the inner liner, a butyl layer that counteracts air diffusion through the tire.

The device carrier is used to hold and fasten the electronic components in the holding device. For example, the device carrier can be a bowl-shaped or U-shaped one Be component in which the electrical components are inserted and then fastened there. A plate on which the electronic components can be attached would also be conceivable.

The damper foot serves to mechanically decouple the equipment carrier and the electrical components contained therein from the movements, deformations and vibrations of the tire casing. As a result, they are only transferred to the device carrier in absorbed or damped form. This leads to a significant reduction in the mechanical load on the electronic components, increases, among other things, their operational reliability and thus only enables the holding device to be fastened in the particularly strong e.g. areas of the tire that are stressed by flexing. This also results in a high degree of flexibility in the arrangement of the electrical components. This can e.g. Sensors or transponders can also be arranged in tires with emergency running properties. Arranging the holding device in the center directly under the tread of the tire could also avoid a directional constraint.

The damper foot can be elastic in some areas, e.g. as a rigid metal or plastic tube with a spring or a damper element, or else be elastic overall e.g. a tube made of rubber, caoutchouc or elastic plastic. The shape of the damper foot can be e.g. be mushroom-shaped, square, cuboid, prismatic, conical or cylindrical.

The permanent securing of electronic components, for example, which store characteristics or rewritable parameters to the tire and which can already be carried out during tire manufacture, makes it possible to individualize the tire. In this way, safety-related information about the tire can be entered into the electronic component, for example an RFID transponder. Such parameters include, for example, the loading and speed indices, the type of tire or the date of manufacture and the serial number of the tire. The rewritability is of particular interest, among other things, when retreading tires. As a result, recordings can be made, for example, of the load history of the tire, which in turn allows conclusions to be drawn about the condition of the tire as a load spectrum diagram. An advantageous development of the holding device provides that the damper foot consists of the same elastic material as the tire casing. This ensures that there are no different temperature expansions and corresponding constraints between the bracket and the tire, which negatively affect the durability of the permanently elastic connection.

A further development of the holding device includes that the damper foot is at least partially hollow. So he can e.g. be tubular or have weight-reducing and damping-increasing cavities, chambers or honeycombs. A completely hollow design is also conceivable.

In order to enable the temperature measurement by a sensor located in the device carrier, in one embodiment the damper foot can contain a heat-conducting material, at least in some areas. For example, the cavity of the very leek-shaped damper foot can be filled with such a heat-conducting mass. However, it is also expedient to design the entire damper foot from a good heat-conducting material or to manufacture the damper foot from a composite material which, e.g. Contains copper wires or copper particles or other thermally conductive materials.

In order to enable energy transmission through the damper foot, it is furthermore advantageous that the damper foot contains a flow-conducting material at least in some areas. However, it is also expedient to design the entire damper foot from a material that conducts electricity well, or to manufacture the damper foot from a composite material which, for example, Contains copper wires or copper particles or other flow-conducting materials.

Another advantageous development would be that the damper foot contains an antenna. This could be integrated in the material of the damper foot, or it could be arranged in the cavity of the damper foot.

The damper foot is preferably tapered in its transverse extent, at least in some areas. Such a taper in some areas can be a notch, for example. This taper leads to an increased mechanical decoupling of the equipment carrier from the tire casing and its movements. Another development of the invention consists in that the tire casing and the damper foot form a monolithic unit that is produced in a coherent manner. This means that the damper foot is made of the same material as the tire and is made in one piece with it. In this case, the damper foot would represent a kind of elevation of the tire casing on the inside.

In another embodiment, the holding device can be glued to the tire casing. This can e.g. by gluing with an adhesive or by a cold or hot vulcanization process. This would make it possible to retrofit the holding device according to the invention on the tire.

The equipment carrier is advantageously made of a metal. This could e.g. Be aluminum or steel. An embodiment is also conceivable and also advantageous, in which the device carrier is made of a plastic, such as PVC exists.

The device carrier can be attached to the damper foot by gluing or vulcanization. In another embodiment, the equipment carrier is attached to the damper foot. Under the latter there is flexible connection e.g. to understand about clips or snap locks. Subsequent changes can be made to the electronic component or to the device carrier in that the device carrier can then be attached and removed. This allows e.g. a mass production of tires that are all already equipped with a damper foot. Such tires would only be marginally more expensive to manufacture, but would, depending on the customer's wishes, e.g. also allow retrofitting of the tire with an electronic component. This would also allow defective electrical components to be replaced without having to replace the entire tire. This would also reduce the logistical effort in the manufacture of the tires.

In another development, the damper foot and the equipment carrier form a monolithic unit which is produced in a coherent manner. This means that the equipment carrier is made of the same material as the damper foot and is made in one piece with it. In this case, the device carrier would represent a kind of expansion, for example with a receiving surface or bulge of the damper foot. Another embodiment of the holding device provides that the device carrier is attached to the tire casing by at least one cross member with at least one damper foot. This makes it possible to arrange the device carrier not directly above but also, for example, laterally from the center of gravity of the damper foot, thus increasing the mechanical decoupling of the holding device, among other things. It may also be advantageous to fasten several electronic components at a distance but nevertheless with a holding device on the tire, a larger device carrier being fastened to this cross member and this being acted upon by a plurality of damper feet. A bridge-like embodiment in which the cross member connects at least two damper feet and the equipment carrier sits on the cross member is also advantageous. Such a cross member could, for example, be made of a plastic or metal rail or consist of the same material as the damper foot.

The electronic components to be held are preferably firmly connected to the device carrier. This can also be done by gluing or vulcanizing on the device carrier.

In a further embodiment, a capacitive or inductive coupling for connecting two electronic components is provided in the damper foot. As a result, the advantages of the patent application for inductive or capacitive coupling for connecting two electronic components, filed by the inventor in parallel with this invention, and those of the present invention can be combined.

The invention is explained in more detail below on the basis of exemplary embodiments shown in the drawing. They show schematically:

Figure 1 shows a section through a tire in which a holding device for attaching electronic components is attached to the tread.

Fig. 2 is an enlarged cross-sectional view of the holding device shown in Fig. 1;

3 shows the side view AA of the holding device shown in FIG. 2; Fig. 4 is a plan view of the holding device shown in Fig. 1, 2, 3;

5 shows a section through a tire in which a holding device for fastening electronic components is attached to the side wall of the tire and in which the device carrier is fastened laterally on a cross member;

Fig. 6 is an enlarged cross-sectional view of the holding device shown in Fig. 5;

Fig. 7 is a side view B-B of the holding device shown in Fig. 6;

Fig. 8 is a plan view of the holding device shown in Fig. 5, 6, 7;

9 shows a section through a tire in which a holding device for fastening electronic components is attached to the side wall of the tire and in which the device carrier is held laterally by two cross-members loaded with damper feet;

Fig. 10 is a side view of the holding device shown in Fig. 9;

FIG. 11 is a top view of the holding device shown in FIG. 10; and

12 shows the section C-C through the holding device shown in FIGS. 9, 10, 11;

In the figures, the same parts are provided with the same reference symbols.

1 shows a section through a tire 1 which has a side wall 3 and a tread 2. In the tire 1 is a first embodiment 4.1 of a holding device for fastening electronic components, such as sensors, transponders or storage media, attached to the inside of the tread 2.

As shown in FIGS. 2 and 3, the holding device 4.1 shown in FIG. 1 contains a single damper foot 7 and an equipment carrier 5. An electronic component 6 is fastened on the equipment carrier 5. The damper foot 7 is a in this embodiment rotationally symmetrical shaped and tapering along its longitudinal axis 9. In this exemplary embodiment, the damper foot 7 is permanently elastic connected to the tread 2 and the device carrier 5. In this exemplary embodiment, the device carrier 5 is U-shaped and can consist, for example, of a metal or a plastic material.

FIG. 4 shows a top view of the holding device 4.1 shown in FIGS. 2 and 3. In this first embodiment, the damper foot 7 has a circular cylindrical cross section. The thickness of the damper foot 7 is greatest in the region of the fastening of the damper foot to the tread, smallest in the region of the center of the damper foot and increases again towards the region of fastening the device carrier 5. As a result of this design, the damper foot has as large a connection area as possible in the area of the fastening with the tire casing, here the inside of the tread 2, and the device carrier 5. As a result, the greatest possible connection force between damper foot 7 and tire 1 or device carrier 5 is obtained. The taper in the center area in turn produces a particularly good mechanical decoupling from the vibrations and movements of the tire 1.

5 shows a section through a tire 1, in which a holding device for fastening electronic components according to a second exemplary embodiment is shown. Here, the holding device 4.2 is attached to the side wall 3 of the tire 1.

FIG. 6 shows an enlarged cross-sectional view of the holding device 4.2 shown in FIG. 5. An electronic component 6 is inserted into the device carrier 5 from below. The damper foot 7 has a widened fastening surface in the area of the tire side wall 3 and tapers to the cross member 8, as can be seen in FIG. 7. The equipment carrier 5 is laterally attached to the cross member 8. The cross member 8 is in turn permanently attached to the damper foot 7. The connection between the damper foot 7 and the tire wall 3 is also permanently elastic. In this exemplary embodiment, the electronic component 6 is fastened on the side of the device carrier 5 facing the tire wall 3.

FIG. 9 shows a section through a tire 1. Here, a holding device according to a third exemplary embodiment for fastening electronic components in a tire 1 is shown. As can also be seen in FIG. 10, the device carrier 5 is held here by two laterally attached cross members 8. At the two lateral ends of the cross member 8 a damper foot 7 is attached. The damper feet 7 are in turn permanently connected to the tire side wall 3. As can be clearly seen from FIGS. 11 and 12, different electrical components 6 can be fastened in the device carrier 5.

Claims

1. Holding device for fastening an electronic component in a wheel containing a tire casing, characterized in that the holding device includes at least one device carrier for receiving and holding the electronic component and at least one, at least partially elastic damper foot connected to the tire casing in a permanently elastic manner.

2. Holding device according to claim 1, characterized in that the damper foot consists of the same elastic material as the tire casing.

3. Holding device according to claim 1 or 2, characterized in that the damper foot is at least partially hollow.

4. Holding device according to one of the preceding claims, characterized in that the damper foot at least partially contains a heat-conducting material.

5. Holding device according to one of the preceding claims, characterized in that that the damper foot contains a current-conducting material at least in some areas.

6. Holding device according to one of the preceding claims, characterized in that the damper foot includes an antenna.

7. Holding device according to one of the preceding claims, characterized in that the damper foot is at least partially tapered in its transverse extent.

8. Holding device according to one of the preceding claims, characterized in that the tire casing and the damper foot form a coherently produced monolithic unit.

9. Holding device according to one of claims 1 to 7, characterized in that the holding device is glued to the tire casing.

10. Holding device according to one of claims 1 to 7, characterized in that the holding device is vulcanized to the tire casing.

11. Holding device according to one of the preceding claims, characterized in that the device carrier consists of a metal.

12. Holding device according to one of claims 1 to 10, characterized in that the device carrier consists of a plastic.

13. Holding device according to one of the preceding claims, characterized in that the equipment carrier is glued to the damper foot.

14. Holding device according to one of the preceding claims, characterized in that the device carrier is vulcanized to the damper foot.

15. Holding device according to one of claims 1 to 12, characterized in that the device carrier is attached to the damper foot.

16. Holding device according to one of claims 1 to 12, characterized in that the damper foot and the device carrier form a coherently produced monolithic unit.

17. Holding device according to one of the preceding claims, characterized in that the device carrier is fastened to the tire casing via at least one cross member with at least one damper foot.

18. Holding device according to one of the preceding claims, characterized in that the electronic components to be held are firmly connected to the device carrier.

19. Holding device according to one of the preceding claims, characterized in that a capacitive or inductive coupling for connecting two electronic components is provided in the damper foot.