The invention relates to a friction brake having a friction brake lining and an actuating device, which serves to press the friction brake lining against a brake body, having the features of the preamble of claim 1. The friction brake is, in particular, a vehicle brake, for example a disk brake or also a drum brake. In the case of a disk brake the brake body is a brake disk, in the case of drum brake it is a brake drum.
Electromechanical friction brakes, which are frequently embodied as disk brakes, are known in the form of wheel brakes for motor vehicles. Such known friction brakes comprise an electromechanical actuating device having an electric motor and a spindle drive for converting a rotational movement of the electric motor into a translational movement for pressing a friction brake lining against a brake body, that is to say in the case of a disk brake against a brake disk.
Self-energizing forms of such disk brakes are also known. In these brakes the friction brake lining is moveable in a direction of rotation of the brake body, there being no compelling reason for the brake body to be capable of movement on a circular orbit around the axis of rotation of the brake disk. The brake body may also move in the direction of a chord to the brake disk, for example. The friction brake lining is braced against a wedge incline to the brake disk. If the friction brake lining is pressed against the brake disk when the brake is actuated by the actuating device, the rotating brake disk exerts a friction force on the friction brake lining, which impels this in the direction of a narrowing wedge gap between the wedge incline and the brake disk. Due to the wedge principle, the wedge incline exerts a bracing force on the friction brake lining, which has a component perpendicular to the brake disk. This component of the bracing force perpendicular to the brake disk increases an application force with which the friction brake lining is pressed against the brake disk, that is to say a brake force is increased. The wedge incline and an associated wedge on a rear side of the friction brake lining remote from the brake disk can be understood as a wedge mechanism and as a self-energizing device.
In the friction brake according to the invention having the features of the preamble of claim 1, the friction brake lining is again moveable in the direction of rotation of a brake body. A force-voltage transducer braces the friction brake lining to prevent it moving together with the rotating brake body. The force-voltage transducer converts a support force, with which the friction brake lining is braced against it, into an electrical voltage, the term electrical voltage also being taken to mean an electrical current. The electrical voltage of the force-voltage transducer can be fed to the actuating device, in order to increase the application force, that is to say the force with which the friction brake lining is pressed against the brake body. Brake force boosting or self-energization is thereby possible. One additional advantage is that the force-voltage transducer can also be used as a brake force sensor: by measuring the electrical voltage of the force-voltage transducer it is possible to determine the support force with which the friction brake lining is braced against it, and hence the brake force of the friction brake. There is no need for an additional sensor for measuring the brake force. From the brake force and the application force exerted on the friction brake lining it is moreover possible to determine the coefficient of friction between the friction brake lining and the brake body. The friction brake lining is preferably braced in both directions of rotation of the brake body against one or various force-voltage transducers, in order to allow self-energization in both directions of rotation of the brake body.
Advantageous embodiments and developments of the invention specified in claim 1 form the subject matter of the dependent claims.
Claim 3 proposes that the actuating device comprise a voltage-force transducer, which converts an electrical voltage or an electrical current into a force, with which the friction brake lining is pressed against the brake body. The voltage-force transducer makes it easy to couple in the electrical voltage generated by the force-voltage transducer when the friction brake lining is braced against it, with the friction brake actuated and the brake body rotating. This embodiment of the invention facilitates self-energization. A further advantage is a high dynamic of the brake actuation.
Inductive transducers having a solenoid coil, for example, or capacitive transducers having a moving capacitor plate, for example, are feasible. The force-voltage transducer and/or the voltage-force transducer preferably comprise one (or more) piezo-electric elements. A piezo-electric element can be used both as a force-voltage transducer, because is generates an electrical voltage when subjected to a force, and as a voltage-force transducer, because it is deformed when an electrical voltage is applied, thereby generating a force. Piezo-electric elements are compact, robust and virtually free from wear; their electric power consumption is low.
Claim 5 proposes an electronic control unit, which is interconnected between the force-voltage transducer and the voltage-force transducer. The electronic control unit allows regulation of the electrical voltage, which is transmitted by the force-voltage transducer, against which the friction brake lining is braced, to the voltage-force transducer, which presses the friction brake lining against the brake body. In this way it is possible to regulate the self-energization of the friction brake according to the invention. Since the coefficient of friction between the friction brake lining and the brake body can be determined from the voltage generated by the force-voltage transducer, and the force with which the friction brake lining is pressed against the brake body, it is possible, by means of the electronic control unit, to regulate the self-energization of the friction brake according to the invention as a function of the coefficient of friction. At the same time the electronic control unit is capable of regulating the brake force of the friction brake and the application force, with which the friction brake lining is pressed against the brake body. The term “regulation” is here intended to include control.
The invention is explained in more detail below on the basis of exemplary embodiments represented in the drawing. The figures show three embodiments of friction brakes according to the invention. The figures are to be interpreted as schematic and simplified representations as an aid to understanding and explaining the invention.
The friction brake 1 according to the invention represented in
As actuating device 10, or at any rate as an integral part of an actuating device 10, the friction brake 1 comprises a further piezo-electric element 11, which is arranged in the brake caliper 5 on a rear side of the lining carrier 6 remote from the brake disk 4. To enable the lining carrier 6 with the friction brake lining 3 to move in the circumferential direction of the brake disk 4, it is moveable in its direction of movement relative to the piezo-electric element 11. The drawing shows a rolling bearing 13 for moveable bracing of the lining carrier 6 on the piezo-electric element 11; a slide bearing, a sliding guide etc. is also feasible. This piezo-electric element 11 forms a voltage-force transducer 12.
The piezo-electric elements 7, which brace the moveable friction brake lining 3 by way of its lining carrier 6 in the brake caliper 5 to prevent it rotating together with the brake disk 4, are electrically connected to an electronic control unit 14, to which the piezo-electric element 11, which forms the voltage-force transducer 12 and at the same time the actuating device 10, is also connected. The electronic control unit 14 is connected to a vehicle electrical system 15 of a motor vehicle, in which the friction brake 1 is used as wheel brake.
The electronic control unit 14 regulates an actuating force or application force or the braking force of the friction brake 1. For brake actuation, an electrical voltage is applied to the piezo-electric element 11, which forms the voltage-force transducer 12. The voltage applied causes the piezo-electric element 11 to increase in thickness and via the lining carrier 6 it presses the moveable friction brake lining 3 against the brake disk 4. Pressing the moveable friction brake lining 3 against the brake disk 4 displaces the brake caliper 5, which is embodied as a floating caliper, transversely to the brake disk 4 and presses the fixed friction brake lining 2 against the other side of the brake disk 4, which is thereby braked.
When the brake disk 4 rotates, it exerts a friction force on the two friction brake linings 2, 3 in their circumferential direction. The moveable friction brake lining 3 is braced by way of its lining carrier 6 against the piezo-electric elements 7, which form the force-voltage transducer 8, preventing it from rotating together with the brake disk 4, so that the piezo-electric element 7, which in the direction of rotation of the brake disk 4 is situated away from the lining carrier 6, is subjected to the friction force, which the rotating brake disk 4 exerts on the moveable friction brake lining 3 pressed against it when the friction brake 1 is actuated. By way of the lining carrier 6, the piezo-electric element 7 braces the friction brake lining 3 with a support force, which is equal to the friction force between the brake disk 4 and the friction brake lining 3 and which is opposed to the friction force. The friction force transmitted to the piezo-electric element 7 forming the force-voltage transducer 8 deforms the piezo-electric element 7 and generates an electrical voltage on the piezo-electric element 7, which is fed to the electronic control unit 14. The electronic control unit 14, which is interconnected between the piezo-electric elements 7, 11, couples in the electrical voltage of the piezo-electric element 7 bracing the friction brake lining 3 in the circumferential direction and transmits it to the piezo-electric element 11, which forms the actuating unit 10. The electrical voltage applied to the latter piezo-electric element 11 and hence the application force, with which it presses the friction brake lining 3 against the brake disk 4, is thereby increased. The friction brake 11 has a piezo-electric self-energization. The level of the self-energization can be regulated by the level of the electrical voltage, which the electronic control unit 14 couples in.
The voltage generated by bracing the friction brake lining 3, via its lining carrier 6, against the piezo-electric element 7 forming the force-voltage-transducer 8 is a measure of the brake force, which the friction brake 1 exerts on the brake disk 4. For this reason the piezo-electric elements 7, which form the force-voltage transducer 8, at the same time also form brake force sensors 9. From the brake force and the application force, with which the friction brake lining 3 is pressed against the brake disk 4, and which results from the electrical voltage which the electronic control unit 14 applies to the piezo-electric element of the actuating device 10, it is possible to calculate a coefficient of friction μ, which prevails between the moveable friction brake lining 3 and the brake disk 4. This affords an easy way of regulating the level of self-energization of the friction brake 1 as a function, among other things, of the coefficient of friction μ.
Apart from a high dynamic, the piezo-electric element 11, which forms the voltage-force transducer 12, has a low electrical power consumption, because it is deformed by the application of an electrical voltage with only a slight or virtually no current consumption. The electrical power consumption and hence the load on the vehicle electrical system 15 by the friction brake according to the invention is therefore low. A further advantage is that the piezo-electric elements 7, 11 are virtually wear-free and that the friction brake 1 has very few moving parts and is thereby virtually wear-free and unsusceptible to fouling. Apart from changing the friction brake linings 2, 3, the friction brake 1 is virtually maintenance-free.
In the following explanation of
At its center the bending element 15 is braced by one of the two piezo-electric elements 11 against the brake caliper 5. The ends or edges of the bending element 16 bear on an intermediate piece 17, which is displaceably guided in the brake caliper 5 transversely to the brake disk 4 in the manner of a piston. By way of a rolling bearing 13, slide bearing, sliding guide etc the intermediate piece 17 bears on the rear side of the lining carrier 6 of the moveable friction brake lining 3. The bending element 16 can be bent and its curvature increased by the application of an electrical voltage to the two piezo-electric elements 11 of the bending element 16. By way of the intermediate piece 17, the bending element 16 thereby presses the moveable friction brake lining 1 against the brake disk 4, thereby actuating the friction brake 1. The bending element 16 with its two piezo-electric elements 11 are an integral part of the actuating device 10 of the friction brake 1 in
Otherwise the friction brake 1 in
The actuating device 10 of the friction brake 1 according to the invention in
In order to compensate for lining wear of the friction brake linings 2, 3, a reservoir 22 with hydraulic fluid is connected to the cylinder 20 by way of a non-return valve 23, through which a flow can pass in the direction of the cylinder 20. The connection of the reservoir 23 to the cylinder 20 is also feasible using a so-called snifting bore, which when the piston 19 moves is closed, as is familiar from brake master cylinders of vehicle hydraulic brake systems, by a central valve, which hydraulically separates the reservoir 23 from the cylinder 20 when one of the pistons 18, 19 moves, as is likewise known from brake master cylinders, or by a solenoid valve, which is controlled by the electronic control unit 20 (not shown).
Otherwise the friction brake 1 in
The piezo-electric actuating devices 10 may also be realized independently of the piezo-electric elements 7, which form the force-voltage transducer 8, on friction brakes without self-energization or having other forms of self-energization.
Number | Date | Country | Kind |
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102010064042.5 | Dec 2010 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2011/072522 | 12/13/2011 | WO | 00 | 9/9/2013 |