DE102010042389A1 - Portable remote control for use in access- and/or start system of vehicle, has pretensioning device separated from contact elements for applying battery with power such that poles of battery are pressed against contact elements - Google Patents

Abstract

The control (FB) has a holding- and contact device for a battery (BAT) with poles (PP). The device has two contact elements (KE1, KE2) for electrical contact of the poles, a pretensioning device (VSE) separated from the contact elements for applying the battery with power such that the poles of the battery are pressed against the contact elements. The contact elements are fixedly arranged with respect to the holding- and contact device. The contact elements include contact sections fixedly arranged with respect to a position of the battery in a used condition.

Description

The present invention relates to a remote control for a vehicle, in particular for use in an access and / or starting system of a vehicle, with a holding and contacting device for the electrical power supply to the electronics of the remote control.

Conventional remote controls for vehicles, also referred to as electronic vehicle keys (since they usually form together with a corresponding vehicle-side part of an electronic access and / or starting device), have a holding device for powering an electronic part of the remote control, which serves a replaceable To hold battery, especially in the form of a button cell such that the electrical poles of the battery come into contact with contact elements of the holding device, so that the electronic part or the electronic circuit of the remote control can be supplied with power. In order to provide a permanent contact between the poles of the battery and the holding device, at least one contact element of the holding device is usually formed in the form of a contact spring, which is slightly biased in the inserted state of the battery in the holding device, and thus ensure a continuous contact, even if geometric changes occur within the remote control or on the remote control, for example, when mechanical forces acting on the housing, which arise in particular when pressing a function key of the remote control.

This balancing of external geometric changes produces a relative movement at the point of contact between a pole of the battery and the contact spring. Such an occurrence of a relative movement, in particular a frequent relative movement leads to fretting corrosion (ie to an increase in the contact resistance between the contact partners Batteriepol and contact spring) which leads from an electronics of the remote control to a faulty assessment of the battery capacity, so that falsely a battery-empty warning is output, although the capacity of the battery would actually be sufficient. In extreme cases, it would also be conceivable that it could lead to a total failure of the remote key due to the resulting fretting corrosion.

Thus, the present invention has for its object to provide a way to ensure a secure and sustainable power supply to a remote control.

This object is solved by the subject matter of the independent claim. Advantageous embodiments are the subject of the dependent claims.

The core idea of the invention is to provide a holding and contacting device for a battery, in which the respective contact elements of the holding and contacting only fulfill the task of making electrical contact with the poles of the battery, so that at the contact points between the contact elements and the poles of the battery no relative movement or friction arises, and consequently no fretting corrosion can occur at these contact points. Thus, a safe and long-lasting (sustainable) electrical energy supply from the battery is possible. The mechanical compensation, especially in the case of geometric changes with respect to the holding and contacting device or a remote control with such a holding and contacting device assumes a separate from the contacts or separate biasing means, which acts on the battery with a force in such a direction that the Poles are pressed against the contact elements. Thus, no relative movement between the contact elements and the poles of the battery, it creates a rigid electrical contact of the battery is created.

In this case, a portable remote control for a vehicle with a holding and contacting device for a battery with poles for electrical contacting are provided, wherein the holding and contacting means comprises a first and a second contact element, which are designed for making electrical contact with the poles of the battery. Further, the holding and contacting means independent of the contact elements biasing means for applying the battery with a force such that the poles are pressed against the contact elements. As already mentioned, a relative movement between the first and the second contact element and the respective battery poles thus in electrical contact is thus avoided, so that fretting corrosion can not occur at the respective electrical contact points.

According to one embodiment, the first and the second contact element may be arranged stationary with respect to the holding and contacting device. In this way, a movement of the battery is prevented in the inserted state, and thus the relative movement between the first and the second contact element and the respective battery terminals in electrical contact are further avoided, so that the occurrence of fretting corrosion is further reduced.

According to a further embodiment, the first and the second contact element on respective contact portions, which in an inserted Condition of the battery can be brought into the holding and contacting in a fixed system with the poles of the battery for electrical contacting. In other words, the respective contact sections can be arranged stationarily with respect to a battery position and designed to make electrical contact with the poles of the battery. This formation of the contact elements or contact portions causes no relative movement between the contact portions and the poles of the battery takes place, so that the occurrence of fretting corrosion is further prevented.

For this purpose, the contact elements may be formed as rigid or dimensionally stable elements. This means that, as a result of the contact elements not deforming, a battery position for the battery in the inserted state (at least partially) can be determined by it, the contact sections then being stationary relative to the battery position. Alternatively or additionally, a battery position may also be provided by a special receptacle for the battery to be used on the holding and contacting device. This receptacle can be designed, for example, as a depression (the bottom portion of which lies essentially in a plane) into which the battery can be inserted in a form-fitting manner. While the battery is then movable in the direction of insertion into the depression, the positive connection causes it to be, for example, not movable or only to a limited extent in a direction parallel to the plane of the bottom of the depression. In this way it is not necessary to form the respective contact elements in a particularly stable manner, since the receptacle already has the effect of holding a battery in its position.

According to one embodiment, the holding and contacting further comprises a supporting structure, in particular in the form of a printed circuit board, to which the contact elements may be rigid or stationary. For example, while the first and the second contact element can be fixedly attached to the circuit board. In the event that the battery to be contacted is in the form of a button cell, a first contact element for the negative pole of the button cell may be formed as a flat contact surface, which is aligned substantially parallel to the circuit board, while for contacting the positive pole of the button cell, for example a contact strip is provided, whose contact surface is oriented substantially perpendicular to the printed circuit board plane or to the plane of the negative pole contact element. In particular, the second contact element may be designed to contact the positive pole in the form of a bent contact strip, wherein the curvature or curvature approximately corresponds to the curvature of the circumference of the button cell. Due to the rigid connection of the contact elements with the circuit board is made possible that a pressed by the biasing device against the contact elements battery undergoes a fixed or a fixed stop and thus a relative movement is prevented at the contact points between the contact elements and battery poles.

According to a further embodiment, the holding and contacting further comprise a cover for at least partially covering the battery, wherein in the covered state of the battery, the biasing means is arranged between the cover and the battery that the cover represents the reference point, from which the Force by the biasing device on the battery is exercisable. In other words, the cover, which may also be referred to as a battery cover, forms a kind of fixed point of the holding and contacting device, from which the biasing device in the direction of the battery can exert a force, so that the battery or its poles against the contact elements for a battery Polkontaktierung be pressed.

It is also conceivable that the remote control has a housing for receiving the holding and contacting device, wherein the cover (battery cover) and the housing have respective mechanical coupling elements, so that a rigid connection, d. H. a connection without a relative movement of the components against each other, in a covered state of the battery between the cover and the housing can be produced. This means, by appropriate mechanical coupling elements, such as latching hooks on the cover and corresponding openings or locking edges on the housing, a rigid connection between the cover and the housing can be made. It is conceivable that this rigid connection by the provision of corresponding lever elements for releasing the locking connection is releasable again, so that the cover can be separated from the housing. Such a separation may be necessary, for example, when replacing the battery from the holding and contacting. However, the battery is in the holding and contacting the cover member is placed over the battery and placed in a rigid connection (without relative movement) with the housing, so that the biasing means, starting from the arranged above the battery element, a force in the direction of Battery can exercise. Thus, an efficient and device technology optimized design is achieved, since the cover is integrated in addition to the function of covering in the function of the battery contacting with.

According to one embodiment, the biasing means comprises a biasing member which biases the battery with a force Contact elements acted upon. It is also conceivable that the biasing means comprises a biasing element, which acts on the battery with a force in the direction of the first contact element and has a further biasing element, which acts on the battery with a force in the direction of the second contact element. In this case, the biasing element may comprise an elastic element for applying the force to the battery. In particular, the elastic element may be formed as a spring element, for example in the form of a spiral spring, which is biased upon compression of the spring, and thus providing this spring in the prestressed state between the cover and the battery, a force on the battery in the direction of or which can exert contact elements. It is also conceivable that the biasing element has a fluid-filled bag or a fluid-filled cushion, so that on the one hand by the pressure in the fluid pressure of the biasing member in the direction of the battery is exercised, but by the deformability of the bag or pad a balance can be created against geometric changes.

It is also conceivable in this regard to integrate the biasing element in the cover, or integrally formed with this, so that components can be saved and the device complexity can be minimized.

It is also conceivable that the biasing element comprises a screw which can be guided in a threaded portion of the holding and contacting and rotated by rotating along an axis. Accordingly, by turning the screw element, it is possible to displace it in the direction of the battery in such a way that the battery is thereby pressed in the direction of the contact element (s) in order to produce reliable electrical contact without relative movement.

In the following, exemplary embodiments of the present invention will now be explained in more detail with reference to the accompanying drawings.

Show it

1 a schematic representation of a remote control for a vehicle, which is designed for wireless communication with a vehicle;

2 a schematic representation of a remote control for a vehicle according to an embodiment of the invention in an exploded view.

It is now on first 1 referenced, in which an identification transmitter or a remote control FB according to an embodiment of the invention is shown. Such a remote control in an executable by a user form has an electronic module or an electronic circuit device ES, which is connected to an antenna ANT to perform a wireless communication with a vehicle FZ can. In particular, the electronic circuit device ES comprises a transmitting / receiving device in order to exchange radio signals ES with the vehicle FZ. The remote control or remote control device FB further comprises a housing (in particular made of plastic) consisting of a housing bottom GB and an upper housing part or battery cover BD, wherein within the housing, the electronic circuit device ES, the antenna ANT and the in 2 described in detail holding contact means for a battery and a corresponding battery are housed. Furthermore, the remote control FB switching element or buttons TAS, by their operation in the electronic switching device ES, a corresponding signal is generated, which is sent via the antenna ANT to the vehicle to trigger the desired function there. In particular, when the remote control is used as a kind of electronic key, or identification transmitter in the context of an access system, an identification code or a control signal for unlocking or locking the vehicle can be triggered, for example, by pressing a button. Such an access system, which causes the doors to be unlocked or unlocked by "actively" actuating a button on a remote control, is also referred to as an active access system.

However, it is also possible that the remote control FB can be used without active key press for automatically opening or unlocking a vehicle only when approaching the vehicle. This approach can be detected by sensors on the vehicle, whereby, for example, a question-answer dialogue is initiated by the vehicle, by the code information is finally transmitted from the remote control to the vehicle. After successful replacement of a correct code, the unlocking of door locks or opening of doors is caused, for example, by a control unit on the vehicle. Such access systems, which do not require active key operation on the remote control, are also referred to as passive access systems.

The remote control device can also be part of a start system of a vehicle, in turn, by pressing an engine start switch by a user or driver, the vehicle with the remote control can perform a question-answer dialog to a to transmit corresponding code information from the remote control to the vehicle. In this case, the remote control on the one hand comprise a key bit, which is plugged into a corresponding ignition lock in the vehicle, being initiated by turning the key bit in the ignition switch the question-answer dialog. It is also conceivable that a so-called. Start stop button is provided in the vehicle, when pressed the question-answer dialog for code verification of the remote control is set in motion.

After the brief explanation of a possible use of the remote control FB according to the invention in 1 be on 2 reference is made in which the structure of the remote control FB will be explained with particular reference to a holding and contacting device for a battery for powering the remote control. As mentioned above, the remote control FB comprises an (outer) housing, which is formed by a housing bottom GB and an upper housing part or a battery cover BD. Within this (outer) housing GB and BD, a printed circuit board LP is provided as a supporting structure, on which a first electrical contact element KE1 and a second electrical contact element KE2 are mounted fixed or not movable. In particular, these contact elements can be formed dimensionally stable. For the electrical contacting of the battery poles, the contact elements may further comprise specific respective contact portions (not shown). More specifically, the first contact element KE1 is formed as a round flat surface, which is realized for making electrical contact with a negative pole of a battery BAT designed as a button cell. For contacting a positive pole of the battery, the second contact element KE2 is designed in the form of a bent contact strip whose contact surface is aligned substantially perpendicular to the contact surface of the first contact element. As a result of this design of the second contact element KE2 in the form of a bent contact strip, the position of the battery BAT in the inserted state can be at least partially determined by the second contact element KE2, in particular by a movement of the battery parallel to the printed circuit board LP in the direction of the second contact element KE2 is prevented.

For holding or fixing the battery BAT, the remote control further comprises a housing element GHE, which comprises a (round) Durchgangsaufnehmung DA, which corresponds approximately to the outer peripheral dimensions of the battery BAT. More specifically, in the assembled state (when the housing element GHE is on the printed circuit board LP) the second contact element KE2 protrude into the through-hole DA, whereby when the battery BAT is inserted, it is in contact with the second contact element KE2 protruding into the through-hole DA on the one hand Connection can come into contact, and on which the second contact element KE2 opposite wall of the passage DA DA can come into mechanical contact with this. In particular, the housing element GHE may be formed of an elastic material in order to press the battery BAT in the direction of the second contact element KE2.

If the battery BAT is inserted in through-hole DA, a biasing element VSE, for example in the form of a spiral spring, is arranged above the battery. Furthermore, the battery cover BD is arranged above the biasing element VSE and the battery BAT or the housing element GHE and rigidly and without the possibility of mechanical coupling elements, such as snap-in hooks and corresponding corresponding latching edges or openings (or other mechanical coupling elements) with the housing bottom GB a relative movement connected to each other (see the composite or covered state as in 1 is shown), the biasing element VSE is compressed and thus biased.

The battery cover BD serves as a fixed point or reference point from which the biasing element VSE in the form of a spring exerts a force along the axis A in the image plane down to the battery so that it is initially pressed primarily in the direction of the first contact element KE1 and thus ensures a rigid contact point without relative movement between the negative pole of the battery BAT and the first contact element KE1. By pressing the battery BAT against the first contact element KE1 also a rigid contacting of the positive pole PP of the battery BAT is made possible with the second contact element KE2, wherein the pressing of the battery BAT against the second contact element KE2 through the housing element GHE, in particular in the form an elastic material is reinforced. The housing element GHE can thus be seen as a further biasing element.

The advantage of such in 2 shown remote control FB is now in it. For example, when pressing one of the keys TAS, in which a force in the image plane from top to bottom (parallel to axis A), also pressure or force exerted on the battery cover BD so experiences this battery cover by this force a geometric change, as it is usually deflected in a training in the form of a lightweight plastic part in the image plane down. However, this mechanical or geometric change of the battery cover BD is now compensated by the realized as a spring biasing element VSE, in which the biasing element VSE is simply compressed. Although possible relative movements at the contact point between the biasing member and the battery may lead to fretting corrosion, but this has no effect for safe operation, since the biasing element VSE is now formed as a separate component to the contact elements KE1 and KE2 and no function of fills electrical contact. By this compensation of the geometric change of the battery cover BD when pressing one of the keys TAS remains a rigid contacting the poles of the battery BAT with the contact elements KE1 and KE2 consist, so that there is no relative movement and thus at the corresponding contact points between the battery poles and the contact elements no fretting corrosion occurs. In this way, a safe and reliable operation of the remote control is guaranteed, as a continuous power supply of the remote control, in particular the electrical switching device ES of the remote control can be ensured by the battery BAT.

As already mentioned above, it is possible to implement the outer housing parts GB and BD in the form of a plastic for the realization of a weight-light remote control FB. Such housing parts can be produced in a simple manner by injection molding and are therefore also inexpensive. Depending on the electrode material, the BAT battery with a round, flat design can be designed, for example, as a silver oxide, mercury oxide, silicon cell and can have a voltage of between 1.35 and 3.6 volts.

It should be noted that it is also conceivable to use other types of batteries or battery shapes, in which case it may be necessary to provide other or differently designed contact elements in order to enable electrical contacting. The principle of using one of the contact elements separate biasing device, can thus also on other holding and contacting devices (see. 2 characterized by the components LP, KE1, KE2, GHE, VSE and BD) for other types of battery.

Claims (11)

Portable remote control (FB) for a vehicle (FZ) with a holding and contacting device for a battery (BAT) with poles (PP) for electrical contacting, wherein the holding and contacting device comprises the following features: a first (KE1) and a second (KE2) contact element for electrically contacting the poles (PP) of the battery (BAT); a to the contact elements (KE1, KE2) separate biasing means (VSE) for acting on the battery (BAT) with a force such that the poles of the battery are pressed against the contact elements. Remote control according to claim 1, wherein the first (KE1) and the second (KE2) contact element are arranged stationary with respect to the holding and contacting device. A remote control according to any one of claims 1 or 2, wherein the first and second contact members have respective contact portions fixedly disposed with respect to a position of the battery in the inserted state and formed to electrically contact the poles of the battery. Remote control according to one of claims 1 to 3, wherein the first and the second contact element are formed dimensionally stable. Remote control according to one of claims 1 to 4, wherein the holding and contacting device has a receptacle for determining a position of the battery in the inserted state. Remote control according to one of claims 1 to 5, wherein the holding and contacting further comprises a supporting structure (LP), in particular in the form of a printed circuit board, with which the contact elements (KE1, KE2) are rigidly connected. Remote control according to one of claims 1 to 6, wherein the holding and contacting further comprises a cover (BD) for at least partially covering the battery (BAT), wherein in the covered state of the battery, the biasing means (VSE) such between the cover and the Battery is arranged, that the cover (BD) represents the reference point, from which the force by the biasing means (VSE) on the battery is exercisable. A remote controller according to claim 7, further comprising a housing (GB) for receiving said holding and contacting means, said cover member (BD) and housing (GB) having respective mechanical coupling elements such that a rigid connection occurs in a covered condition of said battery the cover and the housing can be produced. Remote control according to one of claims 1 to 8, wherein the biasing means comprises a biasing element (VSE), which acts on the battery (BAT) with a force in the direction of the two contact elements. A remote control according to any one of claims 1 to 8, wherein the biasing means comprises a biasing element (VSE) which connects the battery (BAT). acted upon by a force in the direction of the first contact element, and a further biasing element, which acts on the battery with a force in the direction of the second contact element. Remote control according to one of claims 1 to 10, wherein the biasing element (VSE) comprises an elastic element, in particular a spring element, for applying the force to the battery (BAT).

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