DE102006007063A1 - Method for continuously determining the tensile force F in a rope of a parking brake - Google Patents

Abstract

Method for continuously determining the tensile force in a cable (1) of a parking brake comprises transferring the tensile force to a transfer element (2) connected to the cable and then to a pressure sensor (3) lying with a partially annular surface (3') on the transfer element and measuring the force from a signal voltage. The signal voltage and a supply voltage are transferred between the pressure sensor and an emitting/receiving unit (6). Preferred Features: The tensile force is transferred to the pressure sensor via the completely annular surface of the sensor.

Description

The invention relates to a method for the continuous determination of the tensile force F in a rope of a parking brake. Methods for continuously determining the tensile force in ropes of parking brakes are known. In the DE 10 2004 025 361 A1 An electromechanically actuated parking brake for motor vehicles is described. According to the method described therein for determining the tensile force in the rope, it is provided that at least part of the force-measuring device is integrated in at least one brake cable such that the transmission of the tensile force takes place via the part. It is disadvantageous that the rope must be divided into several sections between which force measuring devices are then located.

Of the The invention is therefore based on the object, a method for continuous Determining the traction in a rope of a parking brake, where the rope does not have to be interrupted. On the arrangement Force measuring devices directly in the rope should be completely dispensed with become. Furthermore, the arrangement of several connecting cables largely dispensed with.

The The object underlying the invention is achieved by a method for continuously determining the tensile force F in a rope of a Parking brake released, in which the tensile force F transmitted to a transmission element which is associated with the rope, and then one Transfer pressure sensor is, which rests with an at least partially annular surface on the transmission element and whose signal voltage depends on the magnitude of the tensile force F, and the tensile force F then determined from the respective signal voltage is, where the transfer the signal voltage and the supply voltage between the pressure sensor and the transmitting / receiving unit is wireless. At the transmission element For example, it could be an attack directly connected to the rope. However, it is also possible, the transmission element indirectly, via intermediate parts, to connect with the rope. The pressure sensor is, for example around a ceramic body, in which a coil is arranged, which is energized in the usual way. This lies with an at least partially annular surface on the transmission element, wherein for example, several partial ring-shaped surfaces can be arranged. The determination of the tensile force F from the respective signal voltage done by means of a computer unit. The wireless transmission the signal voltage and the supply voltage are made by induction. It has become more surprising Way shown that a continuous determination of the traction F can be carried out particularly advantageous in this way, being ensured is that no force measuring devices arranged directly in the rope Need to become. On interruptions of the rope can also advantageously be waived. By wireless transmission of the signal voltage and the supply voltage between the pressure sensor and the transceiver unit Advantageously, an arrangement of multiple cables is avoided.

A preferred embodiment of the invention is that the tensile force F on as a transmission element arranged mother transferred becomes. It is advantageous that the transmission element constructive simply designed and in housing structures can be arranged relatively easily.

According to one Another preferred embodiment of the invention, the transfer takes place the tensile force F on the pressure sensor via a arranged as at least partially annular surface full annular surface of the Pressure sensor. It is advantageous that the transmission of the tensile force F on the pressure sensor over the full ring surface equally distributed can take place, which favors a high accuracy of the method.

To a further preferred embodiment of the invention is provided that the transmission the signal voltage and the supply voltage between the pressure sensor and the transmitting / receiving unit via a single coil takes place in the pressure sensor. This favors in Advantageously, a simple structural design of the pressure sensor with simultaneous optimal transmission the signal voltage and the supply voltage from the pressure sensor the transmitting / receiving unit.

According to one Another embodiment of the invention provides that the transmission via a only coil takes place, which faces away from the transmission element Side of the pressure sensor is arranged. This favors a favorable high measuring accuracy of the process over longer operating times.

The Invention will become apparent from the drawing (Fig.) Closer and exemplified.

FIG. shows the arrangement of the transmission element, of the pressure sensor and the transmitting / receiving unit in a simplified Shape in cross section.

In Fig., The transmission element 2 , the pressure sensor 3 and the transceiver unit 6 shown in simplified form in cross section. In the method for the continuous determination of Pulling force F in the rope 1 the parking brake is the tensile force F on the transmission element 2 transfer that with the rope 1 communicates. Here is the rope 1 at one end 4a a spindle 4 firmly connected, so that the connection of the transmission element 2 with the rope 1 indirectly in the present example. Subsequently, the tensile force F is starting from the transmission element 2 on the pressure sensor 3 transferred, with an at least partially annular surface 3 ' on the transmission element 2 is applied. The signal voltage of the pressure sensor 3 is directly dependent on the size of the tensile force F, which is then determined from the respective signal voltage, wherein one uses a computer unit. The transmission of the signal voltage and the supply voltage between the pressure sensor 3 and the transceiver unit 6 takes place wirelessly. As a transmission element 2 Alternatively, an arranged nut can be arranged. In a preferred embodiment, the transmission of the tensile force F takes place on the pressure sensor 3 via an at least partially annular surface 3 ' arranged full ring surface of the pressure sensor 3 , The transmission of the signal voltage and the supply voltage between the pressure sensor 3 and the transceiver unit 6 takes place in the present example preferably via a single coil 3 * in the pressure sensor 3 on the transmission element 2 opposite side of the pressure sensor 3 is arranged. In carrying out the process, the transmission part 8th driven, firmly with a pipe 5 is connected, which is thereby also put into a rotary motion. By a stop (not shown), the outside of the spindle 4 is positioned, the spindle becomes 4 prevented from twisting. Through the through the transmission part 8th Initiated rotational movement of the tube 5 thus becomes the spindle 4 in the interior of the pipe 5 axially displaced and thus the tensile force F in the rope 1 brought in. In the pipe 5 is perpendicular to the longitudinal axis of an elastic sheet 7 arranged in which parallel to the longitudinal axis of the tube 5 bolt 7 ' are fixed in the transmission element 2 protrude. In this way, the transmission element 2 together with the elastic sheet metal 7 that stuck to the pipe 5 is connected, subjected to the same rotational movement as the tube 5 , The transmission element 2 has an internal thread 2a on, in which the spindle 4 to be led. Now the spindle 4 axially into the tube 5 over the internal thread 2a of the transmission element 2 introduced, becomes the transmission element 2 by the applied tensile force F against the pressure sensor 3 pressed, with its at least partially annular surface 3 ' directly on the transmission element 2 is applied. The arrangement of bolts 7 ' allows in addition a slight axial play of the transmission element 2 , The signal voltage of the pressure sensor 3 , which is directly dependent on the size of the tensile force F, is about the only coil 3 * on the transmission element 2 opposite side of the pressure sensor 3 is arranged over an antenna 6a the reception part 6b the transmitting / receiving unit 6 fed and can then be converted by means of a computer unit into values for the tensile force F. Slipping out of the pressure sensor 3 out of the pipe 5 is doing by the arrangement of a stop 5a prevented. The disadvantageous arrangement of cables can be completely dispensed with. Furthermore, it is not necessary to use the rope 1 for the determination of the tensile force F to interrupt or to arrange force measuring devices directly in the rope.

Claims (5)

Method for continuously determining the tensile force F in a rope ( 1 ) a parking brake in which the tensile force F on a transmission element ( 2 ) transmitted with the rope ( 1 ) and then a pressure sensor ( 3 ) transmitted with an at least partially annular surface ( 3 ' ) on the transmission element ( 2 ) is applied and whose signal voltage is dependent on the magnitude of the tensile force F, and the tensile force F is then determined from the respective signal voltage, wherein the transmission of the signal voltage and the supply voltage between the pressure sensor ( 3 ) and the transceiver unit ( 6 ) takes place wirelessly. Method according to Claim 1, in which the tensile force F is applied to a transmission element ( 2 ) arranged mother is transmitted. Method according to Claim 1 or Claim 2, in which the transmission of the tensile force F to the pressure sensor ( 3 ) over an at least partially annular surface ( 3 ' ) arranged full annular surface of the pressure sensor ( 3 ) he follows. Method according to one of claims 1 to 3, wherein the transmission of the signal voltage and the supply voltage between the pressure sensor ( 3 ) and the transceiver unit ( 6 ) over a single coil ( 3 * ) in the pressure sensor ( 3 ) he follows. Method according to Claim 4, in which the transmission via a single coil ( 3 * ) carried out on the transfer element ( 2 ) facing away from the pressure sensor ( 3 ) is arranged.