The invention relates to a brake booster and more specifically to a rapid actuation brake booster that can be applied in particular to motor vehicles.
In automotive braking systems, there is generally a perceptible dead travel at the start of braking when the brake pedal is actuated and during which the driver depresses the brake pedal without any hydraulic pressure being induced effectively in the vehicle braking circuit.
There are systems in existence that are able to reduce this dead travel. Such is the case, for example, of the system described in French Patent Application FR 2 856 363.
This system comprises, as depicted in
a casing 2, of longitudinal axis X, containing a skirt 6 mounted such that it can slide axially in a sealed manner in the casing and which delimits a low-pressure first chamber 8 known as the front chamber and a variable-pressure second chamber 10 known as the rear chamber,
The way in which a booster such as this works is as follows:
In the rest position (
At the start of a braking phase, when the driver depresses the brake pedal, the control rod 28 is moved axially forward, the valve shutter 46 then comes to press against the first valve seat 48, isolating the rear chamber from the front chamber, and lifts off the second seat 50 and allows air at atmospheric pressure to be supplied to the rear chamber. Because of the pressure difference between the front chamber and the rear chamber, the skirt 6 and the piston 12 are made to move forward. The first valve seat 48 borne by the sleeve 54 is immobile while the clearance C between the key 84 and the front end of the second slots 88 is not closed up.
The spring 58 keeps the sleeve 54 in a determined axial position relative to the casing of the booster as long as the piston 12 has not covered a determined travel C (
When the pneumatic piston 12 has covered the travel C (see
The travel C is preferably chosen such that it corresponds to the dead travel of the master cylinder, that is to say to the travel that the hydraulic piston has to cover within the master cylinder in order to begin to cause the pressure of the brake fluid to rise in the brakes. As a result, the driver feels through the pedal only the travel needed to close the equalizing valve and open the intake valve and does not perceive the dead travel of the master cylinder. Driver comfort is thus improved, because the driver has the impression of immediate braking.
Thereafter, the system enters the actual braking phase.
In a system such as this it is found that there is a peak load that has to be applied to the pedal when the key 84 has covered the travel C and comes into contact with the front end of the slots 88 of the sleeve 54. The object of the invention is to attenuate this transition which is perceivable at the brake pedal.
One subject of the invention is therefore a brake booster comprising:
a casing of longitudinal axis,
a skirt and pneumatic piston assembly mounted such that it can slide in a sealed manner in the casing along the longitudinal axis, said skirt-piston assembly dividing the interior space of the casing into a low-pressure front chamber and a variable-pressure rear chamber,
a three-way valve actuated by a control rod mounted in a longitudinal passage pierced in the pneumatic piston, said control rod being connected via a first longitudinal end to a brake pedal,
a slide valve plunger able to move, in said piston, along said longitudinal axis under the control of a second end of said control rod, said slide valve plunger allowing the force of the control rod to be applied to a hydraulic piston of a master cylinder, said skirt-piston assembly transmitting a pneumatic boost force to the hydraulic piston of the master cylinder,
a sleeve mounted such that it can slide in a sealed manner in the pneumatic piston along said longitudinal axis over a determined travel.
The three-way valve comprises a first and a second valve seat, and a valve shutter intended to be pressed against the first and/or the second valve seat. The first valve seat is borne by a first longitudinal end of the sleeve. The second valve seat is borne by a first longitudinal end of the slide valve plunger.
According to the invention, the booster also comprises:
an elastic device bearing, on the one hand, against a front face of the piston and, on the other hand, against a shoulder of the sleeve. This elastic device tends to exert a forward force on the sleeve relative to the piston,
a device for transmitting the pressure of the master cylinder to the sleeve which tends to apply a rearward force to the sleeve.
Provision will advantageously be made for the elastic device to comprise a first spring.
According to one preferred embodiment of the invention, the device for transmitting the pressure of the master cylinder comprises an auxiliary piston coaxial with the primary piston of the master cylinder. This auxiliary piston is intended to apply a force to the sleeve via the device that transmits the pressure of the master cylinder. Advantageously, this transmission device comprises a second spring.
According to this embodiment, provision may be made for the second spring to be contained between a first washer that bears against a shoulder of the auxiliary piston and a second washer that bears against a front shoulder of the sleeve.
Furthermore, according to the invention, means are provided for limiting the movement of the sleeve with respect to the pneumatic piston. In this context, the pneumatic piston may then comprise an end-stop shoulder and the sleeve may comprise a travel-limiting component intended to butt against said end-stop shoulder in order to limit the travel of the sleeve inside the piston of the booster.
Provision may also be made for the position of the travel-limiting component on the sleeve to be axially adjustable.
Furthermore, there may also be a bearing piece which bears against the casing of the booster and which has a first part that penetrates an opening in the pneumatic piston and against which this piston is intended to bear, and a second part which enters an opening in the sleeve and which is intended to limit the forward movement of the sleeve when the booster is at rest.
Advantageously, the load of the first spring is lower than the load of the second spring.
The various objects and features of the invention will become more clearly apparent in the description which will follow and in the attached figures which depict:
One exemplary embodiment of the device of the invention will therefore be described with reference to
This device applies to a brake booster like that of
The description of the device of
A pneumatic piston 12 is secured to the skirt and slides along the axis X of the booster.
A sleeve 54 slides axially inside the piston 12.
A slide valve plunger 32 slides axially inside the sleeve under the control of a control rod 28 controlled by a brake pedal, not depicted.
Furthermore, a three-way valve situated inside the piston 12 could be used either to place the first chamber 8 and the rear chamber 10 in communication, or to place the rear chamber at atmospheric pressure, or to isolate the rear chamber. To do that, as is best visible in
According to the invention, the sleeve 54 is normally pushed forward (to the left in
The spring 70 bears, at one end, against the rear face of a shoulder 71 situated at the front of the sleeve 54 and, at another end, against the front face 72 of a shoulder of the piston 12. The spring 70 therefore tends to push the sleeve 54 forward (to the left in the figures) so that the valve seat 48 tends to move away from the valve shutter 46.
Moreover, the auxiliary piston 126 is capable of exerting a rearward force on the sleeve 54. This force is applied via an elastic device comprising, for example, a spring 128a contained between the pistons 122 and 126.
In addition, a stop piece 90 presses against the internal wall of the casing of the booster. It allows the piston to prevent the sleeve from moving forward.
The way in which the device of
When the braking system is at rest (that is to say when the driver is not depressing the brake pedal), the system is as depicted in
The spring 133 pushes the pneumatic piston 12 back to the rear (to the right in
Moreover, the sleeve 54 is pushed forward by the spring 70 and presses the sleeve 54 against the bearing piece 90.
Because the brake pedal is at rest, the control rod 28 is pushed backward, as is known in the art, by the spring 300. The valve seat 50 pushes the valve shutter 46 backward, this valve shutter being lifted off the equalizing valve seat 48 borne by the sleeve 54. This space between the valve shutter 46 and the valve seat 48 places the front chamber 8 in communication with the rear chamber 10. The valve shutter 46 bears against the intake valve seat 50 and thus isolates the rear chamber 10 from atmospheric pressure.
At the start of a braking phase, when the driver is depressing the brake pedal, the control rod 28 is moved axially forward (to the left in the figures) and the slide valve plunger 32 moves forward. The valve seat 50 moves forward. The valve shutter 46 also moves forward and is pressed against the equalizing valve seat 48 borne by the sleeve 54. The rear chamber 10 is isolated from the front chamber 8. As the slide valve plunger moves forward, the intake valve seat 50 lifts away from the valve shutter 46, allowing air at atmospheric pressure to be supplied to the rear chamber 10.
Because of the difference in pressure between the front chamber and the rear chamber, the skirt 6 and the piston 12 are moved forward.
The piston 12 pushes the piston 122 of the master cylinder 120 forward. The pressure in the master cylinder increases. However, the pressure in the master cylinder tends to push the auxiliary piston 126 back. The piston 126 presses backward against the face 74 of the sleeve 54 via the washer 127, the spring 128 and the washer 129.
Provision will advantageously be made for the load of the spring 70 to be lower than that of the spring 128.
As the piston 12 gradually moves forward, the pressure in the master cylinder 120 increases and the rearward movement of the sleeve 54 with respect to the piston increases. The valve seat 48 moves closer to the valve shutter 46.
As the pressure in the master cylinder gradually increases, there will therefore be an increase in the decoupling of the pedal. This process continues until the face 71 of the sleeve has covered the distance C (see
The valve shutter 46 comes into contact with the intake valve seat 50 and interrupts the supply of air at atmospheric pressure to the rear chamber. The driver then has to depress the brake pedal further in order to increase the intensity of braking.
The valve shutter 46 is then in contact with the equalizing valve seat 48 of the sleeve 54 and with the intake valve seat 50, thus interrupting the supply of air at atmospheric pressure to the rear chamber.
The travel C (see
When this is achieved, not only does the driver feel through the pedal only the travel needed to close the equalizing valve and open the intake valve, without perceiving the dead travel of the master cylinder, but also, the transition between this operation and actual braking occurs progressively.
As a result, when the driver releases the brake pedal at least in part, the slide valve plunger 32 is carried backward with the control rod. The intake valve seat 50 comes into contact with the valve shutter 46 and carries the valve shutter 46 away from the equalizing seat 48, thus placing the front chamber 8 in communication with the rear chamber 10. The pressures across the skirt 6 can then equalize, so the skirt 6 returns to the rest position.
As has already been mentioned, the load of the spring 128 is preferably higher than that of the spring 70.
The travel C of the sleeve 54 in the piston has to be adjusted carefully. This is why, according to one alternative form of embodiment of the invention, a travel limiting piece 75 may be provided, this bearing the bearing face 71 for the spring 70. The position of this piece 75 is axially adjustable on the sleeve 54.
Number | Date | Country | Kind |
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07 07810 | Nov 2007 | FR | national |
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6564692 | Inoue et al. | May 2003 | B2 |
7089846 | Tsubouchi et al. | Aug 2006 | B2 |
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2782044 | Feb 2000 | FR |
Number | Date | Country | |
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20090115245 A1 | May 2009 | US |