FR2936477A1 - Coupling for connecting braking amplifier of hybrid motor vehicle to depression source, has cover cooperating with pressure sensor such that positioning of sensor in end of bore forces cover into opening position of bore - Google Patents

Abstract

The coupling (5) has a body comprising an inner chamber (53) and a bore (54) whose one end opens in the inner chamber and another end receives a pressure sensor. The bore receives an obturation unit i.e. cover (20), moving between a closing position of the bore and an opening position of the bore. The cover cooperates with the sensor such that the positioning of the sensor in the latter end of bore forces the cover into the opening position of the bore. The obturation unit has an annular sealing joint (24) i.e. toric joint, permitting closing position of the bore to be in hermetic condition.

Description

Fitting for mounting a sensor and brake amplifier having such a coupling

The present invention relates to a connector for mounting a pressure sensor to a low pressure chamber of a braking amplifier. According to the state of the art, a pneumatic brake booster amplifier comprises a low pressure chamber connected to a vacuum source, and a working chamber selectively powered either by the vacuum source or directly to the vacuum source. atmospheric pressure. These two rooms are separated from each other by a movable partition. The displacement of this movable partition, under the action of the pressure difference, which is created when the working chamber is fed at atmospheric pressure, assists the braking action of the driver on the brake pedal. On vehicles having as sole means of propulsion a heat engine, the vacuum source is generated either by a vacuum pump, usually a vane pump driven directly by the engine, or by the depression which is created at the intake of the engine. thermal motor. When using the vehicle, the combustion engine continuously rotates, continuously generating a constant low pressure in the low pressure chamber, thus ensuring permanent braking assistance. On vehicles comprising several propulsion means, for example for hybrid vehicles using for propulsion a thermal engine and an electric motor, the vacuum source, generated either by a vacuum pump, driven directly by the heat engine, or by the depression created at the intake of the engine is no longer ensured when the engine is stopped and the vehicle uses the electric propulsion mode to advance. In order to overcome this deficiency, one solution generally consists of replacing or assisting the vacuum source generated by the heat engine by an electric vacuum pump. Another solution is to restart the heat engine at regular intervals, ensuring that the pressure in the low pressure chamber is well below a threshold making the action of the braking assistance sufficient. Of course, in order to optimize the energy expenditure, it is important to limit the operating time of the electric vacuum pump or to limit the restart frequency of the heat engine. This optimization of the energy expenditure is possible only by knowing precisely the pressure present in the low pressure chamber. Such a pressure sensor is for example present in PCT application WO 2007/082932. In this application, the wall of the braking amplifier has two openings, a first opening for mounting a connection connecting the low pressure chamber to the vacuum source and a second opening for mounting a pressure sensor. The fitting of a coupling and, by similarity, the mounting of a pressure sensor is on the wall of a brake amplifier requires the establishment beforehand, because of the small thickness of the wall of the amplifier braking, a sleeve ensuring the holding in time and tightness of the assembly. Such an assembly is described in application FR-A-2864501. The method of mounting this assembly begins with the introduction of the sleeve on the wall, into which the fitting end of the fitting or the pressure sensor is fitted. The notches present along the connection piece, in particular the first notch with an external diameter greater than the other notches, ensure that the connection piece is held in position in the sleeve, but requires the application of a 25 significant strength, imposing a process of automation with specialized tools. If mounting of the coupling can not be avoided, mounting a second element, in this case a pressure sensor, on the wall of the brake amplifier is not desirable. Another problem arises in terms of diversity. If in a family of vehicles, part of this family has a mode of operation that does not require the use of a pressure sensor, while the rest of this family has a mode of operation requiring the use of a sensor pressure, it will necessarily use two references of braking amplifiers with or without a second opening. The present invention is intended in particular to avoid the disadvantages of the prior art and to allow, by avoiding the mounting of a second element on the wall of the brake amplifier, to simplify the method of mounting a possible sensor pressure and facilitate the management of diversity. For this purpose, the invention relates to a connection for connecting a braking amplifier to a source of depression. The coupling is composed of a body having an inner chamber. This body has a bore, a first end of which opens into the inner chamber and a second end of which is capable of receiving a sensor, said bore receiving a closure means movable between a first position closing the bore and a second position opening bore. This closure means is adapted to cooperate with said sensor so that the positioning of said sensor in the second end of the bore forces the closure means in the second position opening said bore. This sealing means has a sealing means making the first position, closing the bore by the sealing means, hermetically. This sealing means can be an O-ring. In addition, this closure means, in the absence of the pressure sensor placed in position in the second end of the bore, is maintained in said first position between a first retaining means and between a second retaining means. According to a first embodiment, the first retaining means is a spring and the second retaining means is constituted by the surface of the inner chamber at the periphery of the first end of the bore. According to a second and a third embodiment, with the inner chamber of the body having a duct positioned on the face opposite to the bore, the duct and the bore having the same axis of revolution, the first retaining means is either consists of frangible tabs or, as for the first embodiment, consists of a spring, and the second retaining means is constituted by a rod, fixed on the closure means, passing through the inner chamber and bearing on the means of a transverse element, against a shoulder positioned along the inner wall of a conduit.

In the three embodiments, the inner chamber has an internal diameter close to the outer diameter of the closure means and has at least one channel extending, when the closure means is in its second position, on both sides. other of the shutter means. The connector may be provided with a sensor disposed at the second end of the bore, said sensor having a probe extending into the bore to cooperate with the closure means to open said bore. Moreover, in the case where this probe comprises an internal channel which opens into the axis of the probe, the closure means comprises at least one duct cooperating with the internal channel to connect the internal channel with the inner chamber of the body. The subject of the invention is also a braking amplifier comprising such a coupling, such a braking amplifier being intended to be mounted on a motor vehicle.

Other advantages and technical features of the present invention will become more apparent in light of the following description with reference to the figures of the accompanying drawings in which:

FIG. 1 is a partial sectional view of a braking amplifier comprising a coupling according to the invention; FIG. 2 shows a sectional view of a coupling, according to a first embodiment of the invention, and of its sealing sleeve, fixed on the wall, partially shown in section, of a braking amplifier; ; - Figures 3 to 5 show partial sectional views of the connector 30 according to the first embodiment; - Figures 6 to 8 show partial sectional views of the connection according to a second embodiment; and - Figures 9 and 10 show partial sectional views of the connection according to a third embodiment.

FIG. 1 represents a partial sectional view of a braking amplifier 1. The braking amplifier 1 consists of two shells 4 and 4 'forming an internal volume separated into two compartments 2 and 2' by a movable partition 3. A connection 5, intended to supply the compartment 2 with low pressure fluid, is fixed on the wall 4 of the braking amplifier 1. A sleeve 6 is interposed between the wall 4, made of pressed sheet metal, of the braking amplifier. 1 and the connector 5. The presence of this sleeve 6 ensures tightness and durability of the assembly. FIG. 2 represents a sectional view of the coupling 5, according to a first embodiment, and of its sealing sleeve 6, fixed on the wall 4, partially shown in section, of a brake amplifier 1. The coupling 15 5 has a substantially cylindrical body having a first connecting end 51, projecting. This first connection piece 51 is fitted into the sleeve 6 which encloses the wall 4 of the braking amplifier. The first connection piece 51 has a serrated outer profile 512 facilitating its fitting into the sleeve 6 and making it difficult to extract it. The connector 5 also has a second connection piece 52, projecting, for connecting the connector 5, with a flexible hose (not shown) to a source of depression. The inner conduits 511 and 521, respectively, of the first and second connection nozzles 51 and 52, connect the chamber 2 of the braking amplifier, to the source of depression, passing through an inner chamber 53, positioned in the connection 5. The chamber 53 has a cylindrical shape, the axis of symmetry X coincides with the axis of the first connecting piece 51. The inner conduit 511 of the first connecting piece 51 opens in the center of the bottom wall 531 of the chamber 53. The inner conduit 521 of the second coupling end 52 of the connector 5 opens onto the side wall 532 of the chamber 53. A bore 54 opens into the center of the upper wall 533 of the chamber 53. The bore 54 is hermetically sealed 20. The cap 20 has a first portion 21, cylindrical, positioned in the bore 54. The first portion 21 of the cap 20 occupies almost entirely the height of the conduit of the bore 54 , flush with respect to the outer surface of the body of the connector 5. The cap 20 has a second portion 22, cylindrical, concentric with the first portion 21, positioned in the chamber 53. The second portion 22 of the cap 20 has a close outer diameter the internal diameter of the chamber 53, greater than the internal diameter of the bore 54. A spring 30, of a diameter smaller than the external diameter of the second portion 22 of the cap 20 and of a diameter greater than the internal diameter of the duct internal 511 of the first connecting piece 51, is positioned between the second portion 22 of the cap 20 and the bottom wall 531 of the chamber 53, keeping the cap 20 pressed against the upper wall 533 of the chamber 53. An annular seal 24 is positioned on the surface of the second portion 22 of the cap 15 facing the upper surface 533 of the chamber 53, at the periphery of the bore 54. The cap 20 has a three part 23, cylindrical, extending coaxially, penetrating the chamber 53, the second portion 22 of the cap 20. The outer diameter of the third portion 23 of the cap 20 is close to the diameter of the spring 30, allowing the spring 30 to come 20 move around this third portion 23 of the cap 20, maintaining the upper portion of the spring 30 in position against the second portion 22 of the cap 20. The inner conduit 511 of the first connecting piece 51 extends into the chamber 53 by a border 513. The lower portion of the spring 30 is engaged around this cylindrical rim 513 of the inner pipe 511 of the first connection piece 51. The spring 30 must exert on the cap 20 a sufficient pressure to oppose the low pressures present in the chamber 53, from the source of depression. To allow mounting of the spring 30 and the cap 20 in the chamber 53, the connector 5 is divided into two parts. The assembly of these two parts can be done by an annular clip 534, by gluing or by any other means of assembly. In the case of a mounting by clipping, an annular seal 535 seals the assembly of these two parts of the connector 5. Figure 3 shows a partial sectional view of the connector 5 according to the first embodiment. In this figure is also partially shown a pressure sensor 7, the probe 71 is introduced into the bore 54 of the connector 5. The sensor 71 of the pressure sensor 7 has on its outer periphery, facing the inner surface of the bore 54 of the connector 5, an annular seal for keeping the chamber 53 hermetically sealed vis-à-vis the external pressure. The pressure sensor 7, mounted on the outside of the connector 5, uses an internal channel 711 of the probe 71 to measure the pressure present in the chamber 53. The pressure sensor 7 is mounted abutting against the external surface of the fitting. 5. External fastening means lock the pressure sensor 7 in position on the connector 5 (not shown). When introducing the probe 71 of the pressure sensor 7 is in the bore 54 of the connector 5, the cap 20 is pushed into the chamber 53, compressing the spring 30. Under the action of the spring 30, the first part 21 of the cap 20 remains in abutment against the probe 71, closing the internal channel 711 of the probe 71, potentially distorting the measurement of the pressure taken by the pressure sensor 7 in the chamber 53. To prevent the first part 21 of the cap 20 thus obstructs the internal pipe 711 of the pressure sensor 7, a central recess 25, which extends over the entire height of the first part 21 of the cap 20, opens out through one of the walls of the first part 21 of the cap In the chamber 53. In the case of a pressure sensor 7 having a probe 71 whose internal channel 711 opens into multiple openings distributed along the lateral surface of the probe 71 near the end in contact with the first part 21 d u cap 20, the presence of the central recess 25 of the first portion 21 of the cap 20 is no longer necessary. The chamber 53 has at the periphery of the channels 55, positioned vertically along the axis of symmetry X of the chamber 53. The channels 55 of the chamber 53 allow the passage of the air flow on either side of the cap 20 when it is positioned in the chamber 53, once the pressure sensor 7 is in position in the bore 54 of the connector 5. The channels 55 of the chamber 53 extend along the bottom 531 of the chamber 53, opening into the inner duct 511 of the first connecting piece 51, thereby passing under the cylindrical edge 513 of the inner duct 511 of the first connecting piece 51 and under the spring 30. The extension of the channels 55 under the spring 30 and under the cylindrical edge 513 internal duct 511 of connector 5 guarantees passage of air flow from inner duct 511 to chamber 53 in the case where cap 20 abuts cylindrical rim 513 of inner duct 511. FIG. 4 is a neck view partial example of the connection 5 along the axis AA 'of FIG. 3, showing an embodiment with 4 channels 55 of the chamber 53. FIG. 5 is a partial sectional view of the connection 5 along the axis BB' of FIG. 3 shows the extension of the channels 55 of the chamber 53 on the bottom 531 of the chamber 53, opening into the inner pipe 511 of the first connection end 51 passing under the cylindrical edge 513 of the inner pipe 511 of the first pipe end. connection 51 and under the spring 30. FIG. 6 shows a sectional view of the coupling 5 according to a second embodiment. As for the first embodiment, the connector 5 has a first connection piece 51 for fixing the connection 5, via a sleeve, to the wall of the braking amplifier, and a second connection piece. 52 for connecting the connector 5, by a flexible hose to a low pressure source. As for the first embodiment, a chamber 53 connects the inner duct 511 of the first connection piece 51 to the inner duct 521 of the second connection piece 52. A bore 54 opening at the center of the upper surface 533 of the chamber 53, allows the mounting of a pressure sensor. This bore 54 of the connector 5 has a cap 20 which sealingly occludes the bore 54 of the connector 5. In this embodiment, the frangible tabs 57 are positioned on the inner periphery of the bore 54 at the edge of the chamber 53. The cap 20 thus positioned in the bore 54 abuts against the frangible tabs 57. Due to the presence of the frangible tabs 57 at the base of the bore 54 of the coupling 5, the mounting of the cap 20 must take place by the upper end of the bore 54 of the connector 5. This mounting direction requires that, unlike the first embodiment, the diameter of the second portion 22 of the cap 20 must not exceed the dimension of the internal diameter of the The seal 24 is thus positioned on the side wall of the cap 20, along the bore 54 of the connector 5. After mounting the cap 20 in the bore 54 of the connector 5, a means of retained 40 immobili the cap 20 Io in contact against the frangible legs 57 of the connector 5. This retaining means 40 is composed of a rod 41, fixed by one of these ends to the cap 20, the second end of this rod 41 being in abutment, by means of a transverse rod 42, against a shoulder 513 positioned on the internal surface of the inner pipe 511 of the first connection piece 51, at the edge of the chamber 53. FIG. 7 shows a sectional view of the coupling 5 according to the second embodiment, with a partial view of the pressure sensor 7 positioned in the bore 54. Upon introduction of the probe 71 into the bore 54, the cap 20 is pushed back into the chamber 53 exerting a pressure. pressing against the frangible tabs 57 of the bore 54 of the coupling 5 causing them to break, allowing the cap 20 to enter the chamber 53. As in the first embodiment, the second portion 22 of the cap 20 has a diameter close to u internal diameter of the chamber 53, guiding the displacement of the cap 20, once the cap 20 positioned in the chamber 53. As for the first embodiment of the channels 55 are positioned at the periphery of the chamber 53, vertically following the axis of symmetry X of the chamber 53. Due to the absence of a return spring, which can limit the passage of the flow between the inner duct 511 of the first connection piece 51 and the inner duct 521 of the second mouthpiece connection 52 of the connector 5, the channels 55 of the chamber 53 are not extended on the bottom 531 of the chamber 53, to the inner conduit 511 of the first connecting piece 51. The third portion 23 of the cap 20 has a portion 2936477 10 apertures 26 allowing the flow of air to be able to circulate between the inner pipe 511 of the first connection piece 51 and the inner pipe 521 of the second connection piece 52 of the connection 5, in the case where the cap 20 comes in abutment against the inlet of the inner pipe 511 of the first coupling end 5 51. In this embodiment, the mounting of the cap 20 in the bore 54 must be effected by the upper part of the connection 5. Only the rod 41 of the retaining means 40 is then fixed to the cap 20. Once the cap 20 bears against the frangible tabs 57, the transverse rod 42 is then placed in position on the free end of the rod 41 of the holding means 40, in bearing against the bore 513 positioned at the edge of the chamber 53 in the conduit 511 of the connector 5. A nut 43 is screwed onto the threaded end of the rod 41 of the retaining means 40, keeping the transverse rod 42 in position. In this embodiment, the presence of the holding means 40, makes the fitting of the connector 5 a little more complex. This embodiment also has the disadvantage of a destructive assembly once the pressure sensor 7 is in position, because of the presence of the frangible tabs 57 as a means of retaining the cap 20. FIG. 8 represents a sectional view along the axis CC 'of Figure 7. Figures 9 and 10 show sectional views of the connector 5, according to a third embodiment. As for the second embodiment the cap 20 is positioned in the bore 54 of the connector 5. The sealing means are positioned along the side walls of the cap 20 facing the side walls of the bore 54 of the coupling 5 A spring 30 bears between the second portion 22 of the cap 20 and the bottom wall 531 of the chamber 53, opposing the low pressures present in the chamber 53. As in the second embodiment, a retaining means 40 is fixed on the cap 20, bearing against a shoulder 513 positioned at the inner periphery of the duct 511 of the first connection piece 51, at the edge of the chamber 53. The spring 30 and the retaining means 40 hold the cap 20 in position in the bore 54 of the connector 5. As in the previous embodiments, the second portion 22 of the cap 20 has an outside diameter close to the internal diameter of the chamber 53, making it possible to better guide the cap 20 during its intrusion into the chamber 53 once the pressure sensor 7 set in position. Channels 55 positioned at the periphery of the chamber 53 allow the passage of the air flow along the cap 20, once the pressure sensor 7 is in position in the bore 54 of the connector 5, between the inner conduit 511 of the first connection piece 51 and the internal duct 521 of the second connection piece 52. As for the first embodiment, the spring 30, when positioning the pressure sensor 7, is put in compression, decreasing the spacing between the turns allowing the passage of the air flow. In the first embodiment, in Figure 2, channels 55 are extended under the spring 30 leading directly into the inner conduit 511 of the first connecting piece 51, allowing the flow of air. Another solution is to lengthen the third portion 23 of the cap 20, limiting the intrusion of the tip 71 of the pressure sensor 7 and, consequently, the compression of the spring, leaving a spacing between the turns still sufficient to allow the passage of the air flow. In this embodiment the mounting of the cap 20 in the bore 54 must be effected by the upper part of the coupling 5, after the introduction of the spring 30. Only the rod 41 of the holding means 40 is then fixed to the cap 20. The spring 30 is pressurized by introducing the cap 20 into the chamber 53, allowing the end of the rod 41 of the cap 20 to be no longer positioned in the conduit 511 of the second end 51 of the connector 5, allowing the mounting of a clip 44 holding the transverse rod 42 at the end of the rod 41 of the retaining means 40. Once the transverse rod 42 is fixed to the rod 41 by the clip 44, the cap 20 is released, starting in position in the bore 54, with the transverse rod 42 bearing against the shoulder 513 of the connector 5. Obviously, the invention is not limited to the embodiments described, particularly with regard to the number of channels 55 present in room 53. Similarly, method of attachment of the pressure sensor 7 to the connector 5, can be achieved in different ways, according to known means of fixing a pressure sensor 7 on a support, such as, for example, by the use of a step of screws on the inner lateral surface of the bore 54 and on the external lateral surface of the probe 71 of the pressure sensor 7, at the same time ensuring the fixing and the sealing of the mounting of the pressure sensor 7 on the connection 5.5

Claims (13)

REVENDICATIONS1. Fitting, for connecting a brake booster to a source of vacuum, consisting of a body (5) having an inner chamber (53), characterized in that the body (5) has a bore (54), a first end of which opens in the inner chamber (53) and a second end of which is adapted to receive a sensor (7), said bore (54) receiving a closing means (20) movable between a first position closing the bore (54) and a second position opening the bore (54), the closing means (20) being adapted to cooperate with said sensor (7) so that the positioning of said sensor (7) in the second end of the bore (54) ) forces the sealing means (20) into the second position opening said bore (54). 2. Connection according to claim 1, characterized in that the closure means (20) has a sealing means (24) making the first position, closing the bore (54) by the closure means (20). ), hermetically clause. 3. Fitting according to claim 2, characterized in that the sealing means (24) is an O-ring. 4. Connection according to any one of the preceding claims, characterized in that the closure means (20), in the absence of the sensor (7), placed in position in the second end of the bore (54). is held in its first position between a first holding means (30; 57) and a second holding means (533; 40). 5. A coupling according to claim 4, characterized in that the first retaining means is a spring (30). 6. A coupling according to claim 5, characterized in that the second retaining means is constituted by the surface (533) of the inner chamber (53) at the periphery of the first end of the bore (54). 7. A coupling according to claim 4, characterized in that the first retaining means consists of frangible legs (57). 8. Connection according to claims 5 or 7, characterized in that the inner chamber (53) of the body (5) has a duct (511) positioned on the face opposite to the bore (54), the duct (511) and the bore (54) having the same axis of revolution, such that the second retaining means is constituted by a rod (41), fixed on the closure means (20), passing through the inner chamber (53) and taking pressing, by means of a transverse element (42) against a shoulder positioned along the inner wall of a conduit (511). 9. Connection according to any one of the preceding claims, characterized in that the inner chamber (53) has an inner diameter close to the outer diameter of the closure means (20) and has at least one channel (55) extending when the closure means (20) is in its second position, on either side of the closure means (20). 10. Connection according to any one of the preceding claims, provided with a sensor (7) disposed at the second end of the bore (54), said sensor comprising a probe (71) extending into the bore (54). ), to cooperate with the closing means (20) for opening said bore (54). 11. Fitting with the sensor according to claim 10, characterized in that the probe (71) comprises an internal channel (711) and in that the closure means (20) comprises at least one duct (25) cooperating with the internal channel (711) for connecting the inner channel (711) with the inner chamber (53) of the body (5). 12. A brake booster having a coupling as claimed in any one of the preceding claims. 13. Motor vehicle comprising a brake amplifier according to the preceding claim.