WO2013171006A1 - Electromechanical assembly for a vehicle closing system and method for determining an actuation of a switching device - Google Patents

Abstract

The invention relates to an electromechanical assembly (100) for a vehicle closing system, comprising a switching device (120) and an evaluation device (130). Said switching device (120) is designed to emit a switch signal (515) when the switching device (120) is actuated. Said assembly is characterized in that the evaluation device (130) is designed to determine the number of actuations of said switching device (120) from the switch signal (515) and to provide actuation information (525) which represents a number of actuations of the switching device (120) during a predefined time window.

Description

 Electromechanical assembly for a vehicle locking system and method of determining actuation of a shifting device

The present invention relates to an electromechanical assembly for a locking system for a vehicle and a method for determining an operation of a switching device according to the main claims.

In locking systems of motor vehicles, a lock consists essentially of two assemblies, the mechanical part of the lock, which is responsible for the actual locking of the door or hood and the Aktuatorik- assembly consisting of electric motors and transmission mechanics (plastic gear). The motors are controlled by a control unit and bring the lock via the actuator in defined positions. These actuator elements are monitored by microswitches in their positions. Depending on the functionality of a lock, between one and five switches are required for position inquiry. These are positioned in the prior art on a so-called electrical component carrier (ECT) and bundled by means of stamped grid in the Elektrokomponententräger- assembly to a connector output.

The utility model DE 20319459U1 discloses a rotary switch for motor vehicles.

In automotive engineering, longevity and reliability of components are a priority with high cost pressure.

Against this background, the present invention provides an improved electromechanical assembly for a locking system, a method for determining an operation of a shifting device for a vehicle, and a computer program according to the main claims. Advantageous embodiments will become apparent from the dependent claims and the description below.

In accordance with embodiments of the present invention, the spatial position of a component or assembly, referred to herein as an actuator, may be related to a closing device, in particular to a switching device arranged in the closing device. The actuator can assume a plurality of defined positions. By connecting a (single) switching device, which may be designed as a microswitch, with a Auswer- te device several switching states can be queried. The operation of the switch is done with the actuator, which is moved by a pre-defined path. A number of actuations of the switching device corresponds to the distance traveled by the actuator, so that an actuating information can be determined in an evaluation device from the switching signal generated in the switching device. The operation information may thus include information about the position of the actuator after the operation of the switching device.

Advantageously, according to embodiments of the present invention, the number of microswitches can be reduced as compared with the prior art, for example, since the operation information can be provided only by using a single switching device. Not only a reduction of the necessary space and weight can be achieved, but this can also contribute to a significant cost reduction.

The present invention provides an electromechanical assembly for a locking system for a vehicle, comprising a switching device and an evaluation device, wherein the switching device is designed to output a switching signal upon actuation of the switching device, characterized in that the evaluation device is formed, to determine the number of operations of the switching device from the switching signal and output an operation information representing a number of operations of the switching device in a predefined time window.

The electromechanical assembly may be a locking system or a component of a locking system. The locking system can have different states, for example, for unlocked / locked and / or theft-proof and / or childproof. The electromechanical assembly may comprise a switching device, wherein the switching device is a separate can act switch, which is formed as a micro-switch, miniature or subminiaturschalter. The switching device may be formed as a sliding contact switch. An evaluation device may be an electrical device that processes sensor or data signals and outputs control or other data signals in response thereto. The evaluation device may have one or more suitable interfaces, which may be formed in hardware and / or software. In the case of a hardware-based configuration, the interfaces can be part of an integrated circuit, for example, in which functions of the evaluation device are implemented. The interfaces may also be their own integrated circuits or at least partially consist of discrete components. In a software training, the interfaces may be software modules that are present, for example, on a microcontroller in addition to other software modules. The vehicle may be a motor vehicle, such as a passenger car or truck. A switching signal may be understood to mean a signal having predetermined characteristics in the waveform at each actuation of the switching device. The switching signal may be an electrical signal representing an actuation of the switching device. The signal may be a digital signal and have signal pulses. In the switching signal and resistance changes can be detected, which give an indication of changes in the switching state in the switching device. An open switch can be interpreted as infinitely large resistance, with a closed switch, the (low) line resistance and the resistance of other components are detectable, which are much lower compared to the open switch.

Furthermore, the switching device can be designed to generate at least one signal pulse in the switching signal each time the switching device is actuated. This offers the advantage that signal pulses can be easily evaluated.

According to a further embodiment of the present invention, the switching device is designed to generate a change in resistance in the switching signal with each actuation of the switching device. This allows to use alternative switching devices with specific advantages. Further, the electromechanical assembly may include an actuator for actuating the switching device, wherein the actuator is configured to actuate the switching device multiple times during a linear movement. An actuator can be understood as meaning a mechanical element which, for example, is designed as a shift gate. A linear motion actuator may be an elongated body, rod, or cuboid having lobes, such as nubs, for depressing and actuating a switch device with longitudinal displacement of each lug. The position and number of lobes on a shift gate may directly affect the position resolution of a device according to an embodiment of the invention.

According to another embodiment of the present invention, the electromechanical assembly may include an actuator for actuating the switching device, wherein the actuator is configured to repeatedly actuate the switching device in a rotational movement. An actuator can also be understood in this embodiment to mean a mechanical element which is designed as a shift gate. An actuator for a rotational movement may be a circular (basic) body or a (fundamental) body that represents at least one circular segment. On the edge of the (basic) body can be formed nose-shaped knobs, which can actuate the switching device in a rotational movement of the actuator.

Advantageously, in one embodiment of the present invention, the electromechanical assembly may be disposed on an electrical component carrier. By integrating the individual components of the electromechanical assembly in an electrical component carrier, in particular integration of the switching device, evaluation and a connector to allow connection to a higher level system, a simplified assembly of the assembly can be realized, as well as a wiring of the components can already be integrated in the electrical component carrier. Under an electric component carrier (ECT) can be a receptacle for the power supply of the various lock functions and a support for switches and sensors, electric motors so- how parts of the lock mechanism and plug are understood. Thus, an electronic component carrier can combine essential lock functions. A leadframe housing can serve for receiving SMD components, contacting the actuators, microswitches or non-contact Hall-effect sensors based on SMD, and a plug connection for connecting sensors / actuators to a control unit. During manufacture, the leadframe can be punched (strip material), followed by SMD placement, the first encapsulation of the leadframe, followed by a free punching and bending process step. Finally, a second encapsulation with integrated plug in the housing can be done.

The present invention further provides a method for determining an actuation of a switching device of an electromechanical assembly for a locking system for a vehicle, wherein the actuation of the switching device takes place in a predefined time window and results in a switching signal, characterized by a step of reading the switching signal and a Step of evaluating the switching signal, wherein the switching signal is evaluated in response to a number of operations of the switching device and the number of operations of the switching device is provided in an actuating information. Here, the switching device by means of an actuator, also referred to as a shift gate, are switched, wherein the shift gate has a pattern of nose-shaped projections to actuate the switching device multiple times. By carrying out the invention as a method, an electromechanical assembly described above can advantageously be supplemented by an evaluation of the operation of the switching device. By evaluating a sound signal generated upon actuation of the switching device, the operation information is output.

Further, in the step of reading in, a switching signal provided in response to movement of an actuator to the switching device from the switching device can be read, and in the step of evaluating, the actuating information is encoded as position information of the actuator after the switching device is operated. An encoding of the position information of the actuator may, for example, be understood to mean a value (as a numerical value) which is a Number of operations of the switching device reflects. As a result, the position of the actuator can be technically very easily coded and read out again.

Also of advantage is a computer program with program code which can be stored on a machine-readable carrier such as a semiconductor memory, a hard disk memory or an optical memory and is used to carry out the method according to one of the embodiments described above, when the program is on a computer or a device , as for example the above-described evaluation device is executed.

The invention will be described by way of example with reference to the accompanying drawings. Show it:

1 shows an electromechanical assembly with a switching device according to an embodiment of the present invention in a first position of the actuator.

 Fig. 2 shows a switching device and an actuator according to an embodiment of the present invention in a movement of the actuator from a first position to a second position;

 Fig. 3 shows a switching device and an actuator according to another

 Embodiment of the present invention in a linear movement of the actuator;

 4 shows a switching device and an actuator in rotational movement according to a further embodiment of the present invention; and

 5 is a flowchart of a method according to an embodiment of the present invention.

In the following description of preferred embodiments of the present invention, the same or similar reference numerals are used for the elements shown in the various figures and similarly acting, wherein a repeated description of these elements is omitted. 1 shows an electromechanical assembly with a switching device according to an embodiment of the present invention. The electromechanical assembly 100 has an electrical component carrier 110, a switching device 120, an evaluation device 130 and a plug 140. In addition to the electromechanical assembly 100, an actuator 150 is arranged. An arrow symbolizes the direction of movement of the actuator 150, which runs, for example, in Fig. 1 from top to bottom. The actuator 150 is configured and arranged to actuate the switching device 120 in a linear motion. The switching device 120 is connected to an input of the evaluation device 130.

The switching device 120 is designed as a mechanical microswitch. The actuator 150 has on its switching device facing the corner, in Fig. 1 bottom left, a chamfer in order to allow sliding over the switching device, wherein the chamfer can also be referred to as a chamfered surface.

In Fig. 1, a second actuator 152 is shown, which may alternatively be used to the actuator 150 according to another embodiment of the present invention. In the embodiment with the second actuator 152, the linear movement of the actuator 152 is at right angles to the moving direction of the actuator from right to left or in the same direction as the operating direction of the switching device 120.

The switching device 120 has on the the actuator 150; 152 opposite side, shown in Fig. 1 on the left side, three electrical connections. On the opposite side, which the actuator 150; 152, the switching device 120 has a nose-shaped projection. The nose-shaped protrusion is designed to be axially mechanically movable, a contact being closed and reopened when the protrusion moves, thereby causing a change in a signal level of the switching signal. The actuator 150 is arranged such that upon axial movement of the actuator 120 perpendicular to the direction of movement of the nose-shaped projection, the bevel of the actuator 150 contacts the nose-shaped projection and the actuator 150 during a further movement in the same direction of movement, the nose-shaped projection presses in and thereby a signal change of the switching signal is effected by the switching device 120.

Fig. 2 shows a switching device 120 and an actuator 150 according to an embodiment of the present invention. The actuator 150 is shown in two different positions 250a and 250b. The actuator 150 moves according to the embodiment shown in Fig. 2 in a linear movement from top to bottom, or perpendicular to the actuation direction of the switching device 120. The first position 250a of the actuator 150 is out of contact with the switching device 120. The second position 250b of the actuator, after a linear downward movement, is in contact with the switching device 120, that is, the switching device 120 is switched or triggered. According to the embodiment of the present invention described herein, the switching device 120 in the case that d. That is, when the actuator 150 is in position 250b, a state change in the switching signal is off.

Fig. 3 shows a switching device 120 and an actuator 150 according to another embodiment of the present invention. The actuator 150 is formed as a shift gate. The actuator 150 has an elongated shape that further includes laterally protruding nubs 360 on the side facing the switching device 120. The elevation of the dimples 360 relative to a baseline 370 corresponds to at least one necessary stroke for actuating the switching device 120. The nubs 360 have an inclined surface, then an aligned parallel to the baseline surface and again an inclined surface back to the baseline 370. In a further embodiment, not shown, also semi-circular shaped nubs 360 are possible. Upon contact of the raised against the baseline 370 nubs 360 with the switching device 120, the switching device is actuated and outputs a switching signal. An actuation can be understood as a depression of a switching contact or the nose of the switching device 120. An arrow indicates the direction of movement of the actuator 150 when it is guided past the switching device and depress a pin of the switching device via the switch 120 stroking projections or nubs. The direction of movement of the actuator 150 is perpendicular to the actuation direction of the switching device 120.

For position inquiry, a microswitch arrangement is required in the prior art, which occupies a larger space and increases the weight of the closing arrangement. In one embodiment of the present invention, as shown in FIG. 3, as an improvement to the prior art, only one microswitch is used to cover a plurality of position queries. The approach presented here makes it possible to find solutions which thus avoid the disadvantages of the prior art and reduce the number of microswitches required. The switching device 120 is embodied in FIG. 3 as a microswitch.

The exemplary embodiments presented here are based on the idea that several switching states of the actuators, often referred to as actuators, can be interrogated, for example, with a microswitch on an electronic component carrier (ECT). The switch is actuated in these embodiments by a mechanism (actuator) in which its actuator is moved by a defined path.

If a shift gate 150 (actuator system) is formed, which actuates the switching device 120 one, two, three or more times in quick succession, then various positions of the actuator system with only one microswitch 120 can be detected via the electronics 130 in the control unit , That is, the switch 120 is operated various times depending on the actuator position. The operation of the switch is linear as in Fig. 3 or rotational, as shown in Fig. 4, conceivable.

The coding of the signal pulses or changes in resistance gives an insight into the position of the actuators. The arrangement according to the embodiments presented here leads to a significant reduction in the number of micro-switches 120 and to reduce the cost of the lock. In addition, the space and the weight of such a switching device can be reduced. Fig. 4 shows a switching device and an actuator in an indicated rotational movement according to another embodiment of the present invention. The embodiment shown in Fig. 4 corresponds in the operation of the embodiment shown in Fig. 3 with the difference that the actuator 450 has a round basic shape with nubs 360 and can perform a rotational movement. A switching device 120 and an actuator 450 are arranged so that upon a rotational movement of the actuator 450, the switching device is triggered several times. The actuator 450 has on its round basic shape nubs 350, wherein the nubs get in a rotational movement of the actuator 450 in contact with the switching device.

5 shows a flowchart of a method 500 for evaluating an actuation of a switching device of an electromechanical assembly for a locking system for a vehicle according to an exemplary embodiment of the present invention. The method 500 includes a step 510 of reading in a switching signal 515, wherein an actuation of the switching device is represented in a pre-defined time window in the switching signal 515. The signal 515 read in step 510 of the read-in 510 is further processed in a step 520 of the evaluation. In step 520 of the evaluation, the switching signal 515 is evaluated to determine therefrom the number of operations of the switching device. As a result of the evaluation, an operation information 525 is provided in which a number of operations of the switching device are coded. In this case, the switching signal may be a signal from a single switch or a single switching device, so that the information about the number of actuations can also be detected by the evaluation of a single switch or a single switching device. In one embodiment of the present invention, while the number of actuations of the switching device corresponds to a position of a lock cylinder of a door lock of a vehicle, for example, positions for unlocked and locked and / or theft-proof and / or child resistant respectively correspond to a number of operations of the switching device. In other embodiments of the present invention, locks with more or less different positions and / or functions are conceivable. The embodiments described and shown in the figures are chosen only by way of example. Different embodiments may be combined together or in relation to individual features. Also, an embodiment can be supplemented by features of another embodiment.

Furthermore, method steps according to the invention can be repeated as well as carried out in a sequence other than that described.

Designation electromechanical assembly

 Electric component support

 switching device

 Evaluation device

 plug

 actuator

 second actuator

a first position of the actuator

b second position of the actuator

 burl

 baseline

 Actuator Method for evaluating an operation of a switching device Step of reading

 switching signal

 Step of the evaluation

 operation information

Claims

claims

1 . Electromechanical assembly (100) for a locking system for a vehicle, comprising a switching device (120) and an evaluation device (130), wherein the switching device (120) is designed to generate a switching signal (515) upon actuation of the switching device (120) outputting device, characterized in that the evaluation device (130) is designed to determine the number of actuations of the switching device (120) from the switching signal (515) and to output an actuation information (525) which indicates a number of actuations of the switching device (525). 120) is represented at least in a predefined time window.

2. Electromechanical assembly (100) according to claim 1, characterized in that the switching device (120) is designed to generate a signal pulse in the switching signal (515) each time the switching device (120) is actuated.

3. Electromechanical assembly (100) according to claim 1, characterized in that the switching device (120) is designed to generate a change in resistance in the switching signal (515) each time the switching device (120) is actuated.

4. Electromechanical assembly (100) according to one of the preceding claims, characterized by an actuator (150) for actuating the switching device (120), wherein the actuator (150) is adapted to actuate the switching device (120) several times during a linear movement.

5. Electromechanical assembly (100) according to any one of the preceding claims, characterized by an actuator (150) for actuating the switching device (120), wherein the actuator (150) is adapted to actuate the switching device (120) in a rotational movement multiple times.

6. Electromechanical assembly (100) according to one of the preceding claims, characterized in that the electromechanical assembly is arranged on an electrical component carrier.

7. A method of determining actuation of a switching device of an electromechanical assembly for a vehicle locking system, the actuation of the switching device in a predefined time window resulting in a switching signal characterized by a step (510) of reading the switching signal (515) and a step (520) of evaluating the switching signal (515), the switching signal (515) being evaluated in response to a number of operations of the switching device (120), and the Number of operations of the switching device (120) in an operation information (525) is provided.

8. Method (500) for determining an actuation of a switching device (120) of an electromechanical assembly (100) according to claim 7, characterized in that in the step of reading (510) a switching signal (515) is read in response to a movement of a Actuator (150) on the switching device (120) of the switching device (120) is provided, wherein in the step of evaluating (520) the actuation information (525) as position information (250a, 250b) of the actuator (150) after actuation of the switching device (120) is encoded.

9. Computer program with program code for performing the method (500) according to one of claims 7 or 8, when the program is executed on an evaluation device (130).