Abstract: A pneumatic brake booster for providing braking assistance. The brake booster has an envelope (10) with an axis of symmetry (X-X') separated sealingly by at least one movable partition (12) to define at least a first chamber (14) connected permanently to a source of low pressure and at least a second chamber (16). The second chamber (16) being selectively connected to the first chamber (14) or a source of high pressure through a three way valve structure actuated by a control rod (30). The control rod (30) being capable of bearing, through the intermediary of a front face of a plunger (28) and a reaction disc (50) with a rear face of a thrust rod (48). The plunger (28) sliding in a bore (26) in the movable partition (12).

Abstract: A brake-control device having a vacuum booster (1), a master cylinder (2) and an electro-hydraulic module (3) for controlling brake pressure. The booster (1) has a front shell (10) and a rear shell (11) having a cylindro-frustroconcal shape with first (R10) and second (R11) outsider radii. The master cylinder (2) and module (3) being secured to the front shell (10) at least three fixing points (71, 72, 73). The fixing points defining a peripheral ring (100) on the front shell which is delimited by an inside radius (Ri) that is equal to half of the outside radius (R10) of the front shell (10).

Abstract: A braking device having a stator (10) fixed to a vehicle by at least one fixing arm (5), a rotor (6) which comprises a first disc (13) and a second disc (16) and brake applying member (40,50). The first disc (13) and second disc (16) rotate with a wheel of the vehicle are fixed with respect to each other with the first disc (13) being located closer to the fixing arm (5). The braking applying member (40,50) has a fixed caliper (40) which is dedicated to braking the second disc (16) and a sliding caliper (50) which is dedicated to braking the first disc (13) to effecg a brake application.

Abstract: A boosted braking device having a master cylinder and a pneumatic booster wherein the force for actuating the master cylinder is derived from a combination of an input force and a boost force of the booster. A main hydraulic piston of the master cylinder has a holler cylinder for receiving the input force. A secondary hydraulic piston located within the holler cylinder of the main hydraulic piston receives a hydraulic reaction force to impart an increasing braking force corresponding to an input force applied over an entire travel of a brake pedal.

Abstract: A master cylinder comprising a cylindrical body (1) which points along a main axis (X). The cylindrical body (1) has a free end (11) and an attached end (12) with a piston rod (2) extending axially from the attached end (12). An impact deflector (3) removably mounted on the cylindrical body (1) covers the free end (11). The impact deflector (3) has at least one deflecting surface (D) which is inclined obliquely to the main axis (X).

Abstract: A disk brake for a motor vehicle having a caliper (1), a carrier (2) which fixed to the vehicle and a pad (41) located between a tip (10) on the caliper (1) and a disk (D). The pad (41) being fitted with a spring (5) which holds the pad against the tip (10) of the caliper (1). The spring (5) bears elastically on inclined surfaces of the tip (10) of the caliper (1) and is subjected to a torque (C--C) which urges the spring (5) to rotate about an axis (X) and to continually urge the spring (5) against the carrier (2).

Abstract: The brake booster has an envelope (10) with an axis of symmetry (X-X') separated sealingly by at least one movable partition (12) to define at least a first chamber (14) connected permanently to a source of low pressure and at least a second chamber (16). The second chamber (16) being selectively connected to the first chamber (14) or a source of high pressure through a three way valve structure actuated by a control rod (30,130). The three way valve structure has a plunger (28,128) which slides in a bore (26,126) of a piston (20,90) is connected to a control rod (30,130). The position of the plunger (28,128) in bore (26,126) selectively controls the communication between the first chamber (14) and the second chamber (16) or communication between the second chamber (16) and the source of high pressure.

Abstract: A pneumatic brake booster having a casing (10) with an axis of symmetry (X-X') and divided in leaktight fashion by a movable wall structure (12,20) into a front chamber (14) and a rear chamber (16). The front chamber (12,20) is permanently connected to a source of partial vacuum while the rear chamber (16) is connected selectively to the front chamber (14) or to the outside atmosphere by a three-way valve (36). The three-way valve is actuated by a plunger (28) which slides in a bore (26) of the movable wall (12, 20) in response ton an input applied to an axial control rod (30). The three-way valve (36) is located in a rear tubular part (22) of the movable wall structure (12, 20) which projects outside of the casing (10) and including a valve element (36). Valve element (36) interacts via a first annular surface (A) with a first valve seat (28a) formed on the plunger (28) and via a second annular surface (B) with a second valve seat (20a) formed on the movable wall (20).

Abstract: A brake actuator having a mechanical actuating member (3) with an automatic adjusting device (5) to compensate for wear associated with friction members (6a,6b). The adjusting device (5) has a variable length created by an elongated nut (7) and a screw (9) which are urged in an unscrewing direction by a force from a spring (16) which is prestressed within a retention member (17). The retention member (17) has a first end which engages a second plate (14) and a second end which engages spring (16) to define a caged structure, The spring urging the elongated nut (7) into engagement with a first plate (12) and the first plate (12) into engagement with the second plate (14). A cylindrical sleeve (18) has a radial collar (18a) which is trapped between the spring (16) and second end of the retention member (17) to slidably engage the second end (7b) of the elongated nut (7) for guiding the second end (7b) into alignment with screw (9).

Abstract: A pneumatic brake booster for providing braking assistance. The brake booster has a housing (10) with an axis of symmetry (X--X') separated sealingly by at least one movable partition (12) to define at least a first chamber (14) connected permanently to a source of low pressure and at least a second chamber (16). The second chamber (16) being selectively connected to the first chamber (14) or a source of high pressure through a three way valve structure actuated by a control rod (30,130). The three way valve structure have a valve member (36,136) which cooperates through an a first annular face (40,140) with a first annular valve seat (34,134) formed on a plunger (28,128) which slides in a bore (26,126) of a piston (20,90). The annular face (40,140) of the valve member (36,136) being urged forward in the direction of the annular valve seat (34,134) by a valve spring (42,142).

Abstract: A pneumatic brake booster having first and second sources of air pressure for developing an output force. The booster has a rigid casing (3) divided by a leaktight moving partition (4) into a first chamber 3(a) and a second chamber 3(b). The moving partition being moved by a difference in the fluid pressures prevailing between the first chamber 3(a) and the second chamber 3(b) to drive a pneumatic piston (5) which carries a valve (7). The valve (7) being actuated by an operating rod (10). The inside (50) of the piston (5) is separated from the second source of air pressure by a purification filter (14). The operating rod (10) slides in a sleeve (16) and which passes through the purification filter (14) has a widened part (100). The widened part (100) together with one end (162) of the sleeve (16) forms an additional valve allowing an additional and direct air intake into the piston (5) in the event of an abrupt application designed to effect a substantial braking force.

Abstract: The invention relates to a pneumatic brake booster using two sources of air pressure and comprising a rigid casing (3) divided by a leaktight moving partition (4) into at least two chambers (3a, 3b), it being possible for the moving partition to be urged by a difference, brought about by an actuation of the valve, between the pressures supplied to the chambers in order to drive along a pneumatic piston (5) bearing an operating valve (7), the inside (50) of this piston being separated from the second source by a purification filter (14).

Abstract: A disk brake having a caliper (1) which straddles a disk (2), a carrier (3) fixed to the vehicle, a cylinder (4) secured to the caliper and closed by a piston (5) and two friction pads (10,11). Two cylindrical and mutually parallel guide pins which slide in corresponding housings. These housings being partially formed by bores (8, 9) made in the carrier (3) for maintaining the caliper (1) with the cylinder (4). The first bore (8), over first and second contiguous sections (s1, S2) of its length, has first and second respective inside diameters (D1, D2), the second diameter (D2) of which is greater than the first diameter (D1). The smaller diameter (D1) being formed on the same side of the first housing as the opening of the bore (8) and the first housing is formed, in addition to the first bore (8), from inside (130) a ring (13) made of elastomeric material.

Abstract: A pneumatic brake booster using first and second sources of air pressure and having a rigid casing (3) divided into at least first (3a) and second (3b) chambers by a leaktight moving partition (4). The moving partition (4) being capable of being urged by a pressure difference brought about by the actuation of a valve (7). Valve (7) having a tubular shut-off member (70) which together with an internal face (510) of a piston (5) delimits a compensation volume (74) that is permanently connected to the second chamber (3b). The shut-off member (70) of valve (7) facing first (71) and second (72) seats. The shut-off member (70) having a continuous and leaktight surface while the compensation volume (74) is connected to the second chamber (3b) by an axial piercing of a portion (8) of a greater thickness of a cylindrical wall (51) on the pneumatic piston (5).

Abstract: A master cylinder (12) and pneumatic brake booster (10) assembly for use in a motor vehicle. The pneumatic brake booster (10) has a casing (15) fastened to a wall (16) which separates a cabin (H) from a front compartment (C) of the motor vehicle. The pneumatic brake booster (10) is actuated by control rod (18) having a rear end which is connected to a brake pedal located in the cabin (H). The master cylinder (12) has a body (20) formed with at least one flange (22) for fastening the master cylinder (12) onto the front wall of the casing (15). An aggressive element (26) extends from the body (20) and engages the casing (15) on rotation of the master cylinder (12) in response to a torque being applied to the master cylinder (12). Engagement of the aggressive element (26) with the casing (15) will attenuate the communication of the torque into the control (18).

Abstract: A pneumatic brake booster (1) having a piston (5) which is responsive to first and second sources of air pressure. The booster (1) has a rigid casing (3) which is divided by a leaktight movable partition (4) into first (3a) and second (3b) chambers. The partition (4) including a pneumatic piston (5) which carries a control valve (7). A difference in pressure established between the first (3a) and second (3b) chambers causes the piston (5) to move within the casing (3). The inside (50) of the piston (5) is separated from the second source of air pressure by an impurities filter (14). A closing-off means (15,17) is located between an opening to the inside (50) of the piston (5) and the second source of air pressure to control an air inlet path which bypasses the impurities filter (14).

Abstract: A pneumatic booster (1) having casing (3) divided by a movable partition (3) into first (3a) and a second (3b) working chambers. The movable partition (4) being urged by a pressure differential derived from a first fluid pressure in the first working chamber (3a) and a second fluid pressure in the second working chamber (3b). The second fluid pressure is communicated to the second working chamber (3b) through the actuation of a shutter (70) by means of a plunger (8). The shutter (70) has freedom of movement with respect to the plunger (8) while being elastically urges against the plunger (8). The shutter (70) is connected to a mass (15) which is set in motion by a movement of the plunger (8). The mass (15) thereafter acts on and moves the shutter (70) away from the plunger (8) to increase the flow of the second fluid pressure to the second chamber (3b).

Abstract: A pressure-regulating solenoid valve (100) for a hydraulic circuit for a braking system of a motor vehicle having wheel antilock structure. The hydraulic circuit has at least one pressurized fluid generator (300) connected to a pressure receiver (200) and to a reservoir (400) for retaining fluid at a low pressure. The solenoid valve (100) has an electrical coil (10) which interacts with two pole pieces (12,14), a sleeve structure (28,30) forming a magnetic body (26) which moves under the effect of an actuation force (O) generated by a magnetic field created by the electrical coil (10) and a distributor element (34). The distributor element (34) interacts with the sleeve structure (28,30) in order to command communication between a duct (98) connected to the pressure receiver (200) and a duct (94) connected to the reservoir (400) or a duct (96) connected to the pressure receiver (200).

Abstract: A pneumatic brake booster for a motor vehicle having a rigid casing (1) with a first shell (10) which points toward the front of the vehicle and a second shell (11) which points toward the rear of the vehicle. At least one through bolt (5) fastened to the front shell (10) and rear shell (11) by respective cohesive forces which joins the front shell (10) to the rear shell (11) in an axial direction by a compressive force which tends to pull the front shell (10) toward the rear shell (11). The cohesive force between the through bolt (5) and the front shell (10) wholly consists of an elastic force exerted by the rigid casing (1) on the through bolt (5) in reaction to the compressive force exerted on the front shell (10) and rear shell (11) by the through bolt (5). The through bolt (5) has a threaded end (50) which passes through the front shell (10).

Abstract: An automatic adjustment strut for a drum brake which is mounted in the vicinity of actuating member and located between a first end of first and second shoes. The first and second shoes are lined with friction pads. The strut has a body with first and second ends which bear on the first and second shoes and extension arrangement for automatically extending the body as a function of ear of the friction pads. The extension arrangement is formed by a screw-nut system and controlled by a pawl which urges toothing secured to a member of a screw-nut system. The pawl is carried by an elastic strip secured to the body of the strut. The elastic strip is separated from the body of the strut when the drum brake is in the position of rest. A lever mechanism tilts to allow the elastic strip and the body of the strut to move toward each other when the shoes are urged apart through actuating member. The lever mechanism has a first arm and a second arm with the first arm bearing on a nut in the screw-nut system.