EP2118525A1

EP2118525A1 - Transmission having a rotational speed detecting device

Info

Publication number: EP2118525A1
Application number: EP08717311A
Authority: EP
Inventors: Kim Führer
Original assignee: ZF Friedrichshafen AG
Current assignee: ZF Friedrichshafen AG
Priority date: 2007-03-13
Filing date: 2008-03-03
Publication date: 2009-11-18
Also published as: WO2008110472A1; DE102007011897A1

Abstract

The present invention relates to a transmission (1) having a transmission housing (7) and a rotational speed detecting device, which comprises a rotational speed transmitter (8) that is non-rotatably connected to a transmission shaft (11) and a stationary rotational speed sensor (4), which is disposed in a sensor arm (2) and by means of which the rotational speed of the transmission shaft (11) can be detected on the rotational speed transmitter (8). The sensor arm (2) comprising the rotational speed sensor (4) can be attached to the transmission housing (7) on at least two attachment points (5, 6).

Description

Transmission with a Drehzahlabqriffseinrichtunqunq

The present invention relates to a transmission, in particular for a motor vehicle, with a Drehzahlabgriffseinrichtung according to the closer defined in the preamble of claim 1 Art.

Transmissions are known from the prior art, the Drehzahlabgriffseinrichtungen to generate a speed signal for example, a motor vehicle. These Drehzahlabgriffseinrichtungen essentially comprise a non-rotatably connected to a corresponding transmission shaft signal or speed sensor, which is associated with a fixed speed sensor to tap the speed at the speed sensor.

DE 103 47 494 A1 describes a device in which the torque is to be determined on transmission shafts. The device comprises for this purpose a transmission shaft to which a tachometer gear is rotatably mounted, wherein the tachometer gear in turn is associated with a fixed speed sensor. The teeth of the tachometer gear generate when passing the speed sensor electrical impulses, which are fed to a corresponding evaluation unit.

The non-prepublished application of the applicant with the file reference 10 2006 034 946 discloses a sensor module in an automated switching system in which various sensors are arranged. The sensor module is designed such that it can be attached via suitable fastening elements to suitable fastening points in the automated switching system. Among other things, the sensor module has rotational speed sensors, via which the rotational speeds of a sliding sleeve, which is rotationally fixedly and axially displaceably arranged on a transmission main shaft, and of a transmission can be detected. The speed sensors are positioned here by means of a long sensor arm directly on the sliding sleeve or the encoder wheel.

A disadvantage here is that a long freely hanging sensor arm is needed to position the speed sensors. The longer such a sensor arm is formed, the greater the risk that it begins to oscillate itself at an external vibration excitation. This vibration can cause a faulty speed signal. Also, depending on the magnitude of the vibrations, the sensor arm could collide with other transmission components and be damaged, or it must be provided in the design of the transmission so much space that this can not be done.

In the not previously published application of the applicant with the file number 10 2006 023 554 an arrangement for determining the rotational speed of a transmission shaft is disclosed. The arrangement has a rotatably connected to the transmission shaft speed sensor and a fixed speed sensor, by means of which the speed can be tapped at the speed sensor. The speed sensor is provided on the circumference of an axially displaceable and non-rotatably mounted on the transmission shaft sliding sleeve and the speed sensor is arranged on a sensor arm such that the rotational speed can be tapped in the radial direction of the tachometer. Further, a Radsatzdrehzahlsensor is provided on the sensor arm, by means of which the speed of a loose gear can be tapped from the same at the teeth. The speed sensors are arranged here on a long sensor arm and are positioned directly on the speed sensors.

Thus, there is also the disadvantage here that the sensor arm begins to oscillate itself with external vibration excitation and by these vibrations, a faulty speed signal can arise. To avoid collisions during a shift, the sensor arm must be placed in a shift fork open- dipping, wherein the shift fork arms of the shift fork must be designed asymmetrically and the shift fork can not be massively manufactured. Another disadvantage is that the transmission must be switched to a specific gear, so that the sensor arm can be mounted or dismounted. Furthermore, here the wheelset speed is tapped by a gear which is mounted with great play on a drive shaft. Tumbling movements of the shaft or of the toothed wheel can falsify the measuring signal of the wheelset speed sensor. Thus, an intelligent sensor must be used here, which outputs a correct signal despite the wobbling movements. However, such a sensor is much more expensive than a conventional speed sensor without additional evaluation.

The present invention has for its object to present a transmission with a Drehzahlabgriffseinrichtung, through which a safe speed detection is made possible and by which the disadvantages of the prior art are eliminated.

The object underlying the invention is achieved by a, including the characterizing features of the main claim exhibiting, generic transmission with a Drehzahlabgriffseinrichtung.

The transmission according to the invention, which can be used for example in a motor vehicle, has a transmission housing and a speed tap device. The Drehzahlabgriffseinrichtung comprises at least one rotatably connected to a transmission shaft speed sensor and at least one fixed speed sensor, which is arranged on a sensor arm and by means of which the speed of the transmission shaft can be tapped at the speed sensor. The sensor arm is attached to the transmission housing and extends through a Stellerraum. Under the Steller space is here to understand that space within the gear housing in which the adjusting means of the transmission circuit are, such as shift rails, Shifters and sliding sleeves of a dog clutch. The speed sensor may be, for example, a Hall effect sensor or an induction sensor, and the transmission shaft may be a drive shaft, a countershaft, a main shaft or an output shaft of the transmission. The speed sensor is provided for example on the circumference of a sliding sleeve, which is arranged axially displaceable and rotationally fixed to the transmission shaft. By means of the sliding sleeve, spur gears can be connected to their shafts via corresponding claw-type short teeth, which are located, for example, laterally on the spur gears. For facilitating switch such coupling devices can be supplemented with synchronizing and Sperrsynchronisiereinrichtungen.

In a preferred embodiment of the transmission according to the invention, the sensor arm having the speed sensor and the gear housing are designed such that the sensor arm can be fastened to at least two fastening points on the gear housing. For example, the two ends of the sensor arm can be firmly connected to the transmission housing. Thus, the sensor arm is no longer freely suspended in the transmission housing, whereby the sensor arm in the transmission housing can not swing freely. The speed sensor can securely tap the speed at the speed sensor and a collision between the sensor arm and existing transmission elements caused by an external vibration excitation can be safely avoided.

In a particularly preferred embodiment of the transmission according to the invention, the first fastening point is formed by a fixedly arranged on the gear housing device and connectable to the device end of the sensor arm has a corresponding to this device shape. This ensures that the connection of the sensor arm with the first attachment point is easy and safe to produce. During assembly of the sensor arm, the end of the sensor linkable with the device is arms so brought to the device that this is connected to the device and thus fixed to the gear housing. For example, the end of the sensor arm which can be connected to the device can be fork-shaped and the device can have a corresponding contour. The device receiving the end of the sensor arm may, for example, be formed in one piece from the transmission housing.

In an advantageous embodiment of the transmission according to the invention, the second attachment point can be realized by a fixed connection of the sensor arm and the gear housing, wherein this connection is preferably made only when the connectable to the first attachment point end of the sensor arm is fixed to the transmission housing. The second attachment point can be realized for example by a screw connection. It is also conceivable that the sensor arm is firmly connected to the transmission housing via at least one fastening clip.

In a further preferred embodiment of the transmission according to the invention, the end of the sensor arm, which has the shape corresponding to the first attachment point, and arranged in or on the sensor arm speed sensor for detecting the rotational speed of the transmission shaft are arranged close to each other. The thus small distance between the first attachment point and the speed sensor ensures that the speed sensor undergoes no natural vibration at an external vibration excitation and the speed is thus tapped off safely on the speed sensor. The risk of error signal generation by swinging back and forth of the sensor arm is thus eliminated.

According to a further embodiment of the transmission according to the invention, the sensor arm is designed in such a way and the speed sensor in or on the sensor arm arranged such that the speed of the transmission shaft can be tapped in the radial direction of the speed sensor. In a preferred embodiment of the transmission according to the invention, the speed sensor is formed by an external toothing of a rotatably connected to the transmission shaft sliding sleeve, which can be brought in the axial direction of the transmission shaft in a neutral position, a first coupling position and a second coupling position. The rotational speed sensor is arranged such that the rotational speed in the neutral position, the first clutch position and the second clutch position of the sliding sleeve on the external toothing can be reliably tapped off. In this way, the external teeth of the sliding sleeve can be used in unmodified form as a speed sensor.

In a further preferred embodiment of the transmission according to the invention, the sensor arm and existing switching elements of the transmission are designed such that a collision-free assembly or disassembly process of the sensor arm is ensured. During assembly or disassembly, the sensor arm can be guided past a shift fork for actuating the sliding sleeve and can be meshed into the first attachment point on the transmission housing. The switching elements and the sensor arm are preferably designed such that the sensor arm can be assembled or disassembled in each switching state of the transmission. For example, the shift fork for this purpose may be slightly symmetrical. The mechanical properties of the asymmetrically formed shift fork, such as the stability or rigidity, can be influenced by a massive design of the shift fork accordingly.

In a particularly preferred embodiment of the transmission according to the invention, the sensor arm has a second speed sensor, for example a wheelset speed sensor, by means of which the speed of a further transmission element can be tapped off. Thus, only one sensor arm is needed to measure the speeds of the sliding sleeve and the wheelset. The Speed sensors can be arranged or injected on or in the sensor arm.

In a further preferred embodiment of the transmission according to the invention, the further gear element is a fixed gear on a second gear, which serves as a speed sensor, wherein the rotational speed of the gear and thus the rotational speed of the second gear shaft can be tapped by the Radsatzdrehzahlsensor on the toothing of the gear. The wheelset speed sensor may in this case be arranged such that the rotational speed of the wheelset can be tapped off in the radial direction of the gearwheel fixedly arranged on the second transmission shaft. Likewise, the sensor arm and the Radsatzdrehzahlsensor can be designed and arranged such that the rotational speed of the wheelset can be tapped in the axial direction of the teeth of the gear fixed to the second gear shaft. Preferably, the second transmission shaft is a very well mounted in the transmission housing shaft. Thus tumbling movements of the shaft and the speed sensor for the Radsatzdrehzahlsensor be avoided, which can be used for detecting the Radsatzdrehzahl a cost-effective speed sensor without additional evaluation.

In a preferred embodiment, the sensor arm having the rotational speed sensors is part of a sensor module, wherein the end of the sensor arm remote from the first actuating point is firmly connected to the housing of the sensor module. The other end of the sensor arm in turn has a shape corresponding to the first attachment point and can thus be firmly fixed to the transmission housing. The second attachment point is in this case realized by a fixed connection between the housing of the sensor module and the transmission housing.

In a further embodiment of the transmission according to the invention, the transmission shaft is a main shaft and the second transmission shaft is a countershaft. formed wave of the transmission, wherein the main shaft can be mounted floating between two countershafts.

In the following, the basic principle of the invention, which permits several embodiments, is explained in more detail by way of example with reference to a drawing.

The single figure shows a section of a transmission 1, which can be used for example in a motor vehicle. The transmission 1 has a transmission housing 7 and a Drehzahlabgriffseinrichtung. The Drehzahlabgriffseinrichtung here includes a non-rotatably connected to a transmission shaft 11 speed sensor 8 and a fixed speed sensor 4, which is arranged on a sensor arm 2 and by means of which the speed of the gear shaft 1 1 can be tapped at the speed sensor 8. The sensor arm 2 has a second rotational speed sensor 3, which is designed here as a wheel set speed sensor, by means of which the rotational speed of a toothed wheel 13 fixedly arranged on a second gear shaft 12 is detected at the toothing 14 thereof. The gear shaft 1 1 is shown here as the main shaft and the second gear shaft 12 is shown here as a countershaft of the transmission 1. The sensor arm 2 and the Radsatzdrehzahlsensor 3 are here designed and arranged such that the speed of the wheelset can be tapped in the axial direction of the teeth 14 of the gear 13 fixedly mounted on the countershaft 12. Since the countershaft 12 is a very well mounted in the transmission housing shaft, no tumbling movements of the countershaft 12 and the gear 13 occur, which can be used for detecting the Radsatzdrehzahl a cost-effective speed sensor 3 without additional evaluation. The sensor arm 2 extends through a Stellerraum, wherein under the Stellerraum here that space is to be understood within the transmission housing 7, in which the adjusting means of the transmission circuit are, such as shift rails 17, shift forks 10 and sliding sleeves 9 a claw circuit. The speed sensor 3, 4 having sensor arm 2 is attached to two attachment points 5, 6 on the transmission housing 7. In the embodiment shown in the figure, the first attachment point 5 is formed by a fixedly arranged on the gear housing 7 device 15 and connectable to the device 15 end of the sensor arm 2 has a corresponding to this device 15 form. The connectable to the device 15 end of the sensor arm 2 is formed here fork-shaped. The second attachment point 6 is realized here by a screw 16, through which the device 15 remote from the end of the sensor arm 2 is fixedly connected to the transmission housing 7.

The end of the sensor arm 2, which has the shape corresponding to the device 15, and arranged in or on the sensor arm 2 speed sensor 4 for detecting the rotational speed of the main shaft 1 1 are arranged close to each other, thereby ensuring that the speed sensor 4 despite an outer Vibration excitation experiences no natural vibration. The sensor arm 2 is formed in such a way and the speed sensor 4 is arranged in or on the sensor arm 2 such that the rotational speed of the main shaft 1 1 in the radial direction and laterally to the main shaft 11 at the speed sensor 8 can be tapped. The speed sensor 8 is formed here by an external toothing of a rotatably connected to the main shaft 1 1 sliding sleeve 9, which in the axial direction of the main shaft 1 1 in a neutral position, a first coupling position and a second coupling position can be brought.

The sensor arm 2 and existing switching elements 9, 10, 17 of the transmission 1 are designed such that a collision-free assembly and disassembly process of the sensor arm 2 is ensured and switching operations are collision-free feasible. The sensor arm 2 is guided past the shift fork 10, which serves to actuate the sliding sleeve 9, and is inserted into the first attachment point 5 or the device 15 on the transmission housing 7 and then secured by the screw connection 16 to the transmission housing 7 connected. The shift fork 10 is slightly asymmetrical in this case, so that the sensor arm 2 can be assembled or disassembled in each switching state of the transmission 1.

REFERENCE CHARACTERS

1 gearbox

2 sensor arm

3 wheelset speed sensor

4 speed sensor

5 first attachment point

6 second attachment point

7 gearbox housing

8 Measuring toothing, external toothing of the sliding sleeve

9 sliding sleeve

10 shift fork

11 gear shaft, main shaft

12 second transmission shaft, countershaft

13 gear

14 Measuring toothing, gear toothing

15 device

16 screw connection

17 shift rail

Claims

claims

1. transmission (1) having a transmission housing (7) and a Drehzahlabgriffseinrichtung having a non-rotatably connected to a transmission shaft (11) speed sensor (8) and a fixed speed sensor (4), which arranged on a sensor arm (2) and by means of the rotational speed of the gear shaft (11) can be tapped on the rotational speed sensor (8), characterized in that the sensor arm (2) having the rotational speed sensor (4) can be fastened to at least two attachment points (5, 6) on the transmission housing (7).

2. Transmission (1) according to claim 1, characterized in that the first fastening point (5) by a transmission housing (7) fixedly arranged device (15) is formed and connectable to the device (15) end of the sensor arm (2) a form corresponding to this device (15) has.

3. Transmission (1) according to claim 1, characterized in that the second attachment point (6) by a fixed connection (16) of the sensor arm (2) and the transmission housing (11) can be realized, for example by a screw connection.

4. Transmission (1) according to at least one of claims 1 to 3, characterized in that the end of the sensor arm (2) having the device (15) corresponding shape, and in or on the sensor arm (2) arranged speed sensor (4) are arranged close to each other for detecting the rotational speed of the transmission shaft (11).

5. Transmission (1) according to at least one of the preceding claims, characterized in that the sensor arm (2) is formed and the speed sensor (4) in or on the sensor arm (2) is arranged such that the speed of the transmission shaft (11) can be tapped in the radial direction on the speed sensor.

6. Transmission (1) according to at least one of the preceding claims, characterized in that the speed sensor (8) by an external toothing of the transmission shaft (11) rotatably connected sliding sleeve (9) is formed, which in the axial direction of the transmission shaft (11) in a neutral position, a first coupling position and a second coupling position can be brought, wherein the speed sensor (4) is arranged such that the speed in the neutral position, the first coupling position and the second coupling position of the sliding sleeve (9) on the outer toothing (8) can be tapped is.

7. Transmission (1) according to at least one of the preceding claims, characterized in that the sensor arm (2) and existing switching elements (10) of the transmission (1) are designed such that a collision-free assembly or disassembly process of the sensor arm (2) is guaranteed.

8. Transmission (1) according to at least one of the preceding claims, characterized in that the sensor arm (2) has a second rotational speed sensor (3), by means of which the rotational speed of a transmission element (13) can be tapped.

9. transmission (1) according to claim 8, characterized in that the transmission element (13) on a second transmission shaft (12) fixedly arranged gear, wherein the rotational speed of the gear and thus the rotational speed of the second gear shaft (12) on the toothing (14) of the same can be tapped.

10. Transmission (1) according to at least one of the preceding claims, characterized in that the transmission shaft (11) as the main shaft and the second transmission shaft (12) is designed as a countershaft of the transmission (1).