The present invention relates to an electromagnetic servo brake comprising a master cylinder primary piston thrust in the direction of actuation thereof by a thrust rod, which is in turn pressed against the servo piston.
In electromagnetic servo brakes, the primary piston is thrust by a thrust rod identical to that of the vacuum servo brake, in which the thrust rod is formed by a rod so to speak connected to a base in the form of a piston pressing by way of the reaction disk against the servo piston actuated by the pneumatically operating braking force amplifier or by the electric motor driving this piston by way of a rack transmission.
In the case of the servo piston connected to the pneumatic piston, the assembly is mounted so as to float in a relative manner and has sufficient freedom so as not to impose a component of transverse force on the primary piston, but solely a longitudinal force.
In the case of the electromagnetic servo brake, the servo piston is held rigidly by the connection thereof by rack to the electromagnetic drive, such that it is not adapted and the thrust exerted onto the primary piston has a relatively significant transverse component.
Document FR 03 11 580 describes an electrical brake assist servomotor shown in
The references used in the description of the present
By way of comparison, tests have shown that under the same operating conditions, the transverse component exerted by the thrust rod of a pneumatic servo brake onto the primary piston was negligible, whereas in the case of an electromagnetic servo brake this component was significant.
The object of the invention is to develop a thrust rod or push rod for an electromagnetic servo brake exerting practically no thrust with a transverse component onto the primary piston.
Presentation and advantages of the invention
To this end, the invention relates to an electromagnetic servo brake of the type defined above, characterized in that it comprises a thrust unit connecting the servo piston to the primary piston in the direction of actuation thereof and formed of a push rod, of which the front end in the form of a spherical cap is pressed into a cup of the primary piston, the rear end comprising a ball, and formed of a bearing having a base pressed against the reaction disk and a sleeve receiving the ball of the push rod.
The servo brake according to the invention has the advantage of creating a degree of freedom for the thrust unit replacing the traditional thrust rod. This degree of freedom in the transverse direction prevents the transmission of a transverse component of the force exerted by the servo piston onto the thrust unit, which, without this degree of freedom, would transmit this force with its transverse component to the primary piston.
The thrust unit advantageously comprises a clamp in tulip form, of which the petals have fastening ends protruding outwardly and forming internally a neck resiliently delimiting the receiving cavity of the ball of the push rod. The sleeve of the bearing comprises an inner throat for serving as a support at the end of the petals of the clamp, and the clamp is placed in position on the ball of the thrust rod before this assembly is engaged and connected in the sleeve by the fastening of the end of the petals in the throat of the sleeve. This embodiment makes it possible to assemble the thrust unit in an effective manner, i.e. to combine the push rod with the bearing and to thus form an assembly securely hinged at the ball, but not disconnectable.
In accordance with a further feature, the push rod has an outer crown slightly distanced from the edge of the sleeve when the push rod is connected to the sleeve in order to limit the tilting thereof relative to the axis, before it is placed in position in the primary piston. This outer crown prevents excessive tilting of the push rod relative to the bearing, thus facilitating the placement in position of the thrust unit in the primary piston at the moment of assembly of the servo brake on the master cylinder.
In accordance with a further advantageous feature, the push rod is in two parts formed separately and assembled on the basis of the length that the push rod is to have depending on the type of servo brake.
In accordance with a further advantageous feature, the sleeve constitutes the cavity forming the cup for the ball of the push rod, the sleeve having a crimping zone in front of the cavity in order to hold the ball whilst allowing it to rotate freely.
Thus, on the whole, the invention makes it possible by simple means to prevent the transmission of a transverse component of the thrust force exerted onto the primary piston without the need for any structural modification of the master cylinder or assembly thereof on the electromagnetic servo brake.
The present invention will be described hereinafter in greater detail with the aid of embodiments of an electromagnetic servo brake shown in the accompanying drawings, in which:
In order to simplify the description, by convention, the front (AV) of the servo brake is located on the side of the tandem master cylinder and the rear (AR) is located on the side of the control rod actuated by the brake pedal as indicated in
The rear part 112 has a cylindrical receptacle 113 for forcibly press-fitting the pin 114 of the front part 111 and forming a one-piece assembly. These two parts 111, 112 are formed separately, and at least one of the parts has a length selected on the basis of the length that the push rod 110 is to have depending on the type of servo brake to be equipped.
The push rod 110 has a front end 115, which is rounded in the form of a spherical cap in order to cooperate with a receptacle 201 in the form of a ball cup formed in the body of the primary piston 200 (
The rear end of the push rod 110 is formed by a ball 116 connected by a part 117 shaped in the form of a truncated cone to the body 118 of the push rod. Beyond this part 117 shaped in the form of a truncated cone, the body 118 carries a peripheral crown 119 serving as a stop for limiting tilting, as will be seen hereinafter.
The bearing 120 receiving the ball 116 at the rear end of the push rod 100 is formed of a base 121 formed by a disk carrying a sleeve 122 directly receiving the ball 116 of the push rod (
The thrust unit 100 is fixed in translation in the direction of the axis (xx), but has a degree of freedom in the transverse direction thanks to the head 115 shaped as a cap freely pivoting with respect to the cup 201 of the body of the primary piston 200 and thanks to the ball 116 of the push rod 110 pivoting with respect to the bearing 120, which is in turn carried by the support of the servo piston 300.
The push rod 110 and the bearing 120 are assembled by the prior mounting of the clamp 130 on the ball 116 followed by the engagement of the clamp 130 thus covering the ball 116 in the sleeve 122. During this engagement, the resilient petals 132 of the clamp 130 retract against the joint 117, shaped in the form of a truncated cone, connecting the ball 116 to the body 118 of the push rod; then, once arrived in the throat 123, the petals 132 move apart from one another resiliently and lock the clamp 130 and the ball 116 to the bearing 120 in the direction of the axis xx whilst allowing the ball 116 the possibility to pivot freely in the cup 131 formed by the clamp 130.
This embodiment of the push rod 110 is shorter due to the reduction of the length of the part 117 shaped in the form of a truncated cone due to the elimination of the clamp 130. The other parts of this servo brake and in particular the primary piston 200 and the servo piston or support thereof 300 are identical to the previous embodiment.
Number | Date | Country | Kind |
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1356267 | Jun 2013 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/062830 | 6/18/2014 | WO | 00 |