FR2812832A1 - Oleo-pneumatic spring compressor for motor vehicle suspension struts has telescopic compressor mounted between spring collars - Google Patents

Abstract

The oleo-pneumatic vehicle suspension spring compressor has a tubular housing (1) attachable to one spring collar and a tubular rod sliding in the housing and attachable to a second collar. A rod (15) in the tubular rod has one end connected to a piston (16) in a hydraulic chamber (17). The rod has a central passage (24) connected to a pump (50) outlet and having a plunger piston (56) fed with hydraulic fluid by the chamber.

Description

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The invention relates to a spring compressor. In the field of mounting and dismounting the springs of shock absorbers of motor vehicles, motor mechanisms are used in the form of a jack which separate or bring together two jaws or cups placed one opposite the other and between which a few turns of the spring are engaged.

In most cases, the cylinder used is of the screw type, and the body can be in two telescopic parts. The part of larger diameter carries in its center a screw immobilized in translation relative to it while the part of smaller diameter carries a nut, locked in rotation relative to this part, itself locked in rotation relative to l 'other party. By manipulating the screw by the end of the body of the jack, we therefore control the extension or retraction of this body, therefore the distance or the approximation of the cups which are fixed to it.

There are also pressurized fluid cylinders, single or double acting, which ensure the relative movement of the cups. Compressors operating with compressed air are known (for example in US-A-4,034,960). However, the low value of the air pressure in usual workshop installations means that the working sections must be largely dimensioned in order to develop the forces required for the compression of the springs. Pneumatic spring compressors are often bulky.

Also known are hydraulic compressors operating with a fluid subjected to a pressure of the order of several hundred bars (for example in FR-A-2,749,364), which makes it possible to design compressors with a small footprint, much more handy in a workshop and under an automobile. However, not all workshops are equipped with such a hydraulic source.

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 An external oleopneumatic converter is then used, comprising a pump driven by compressed air, sucking oil from a reservoir to inject it under pressure into the compressor. The implementation of this converter requires various manipulations and connections which make its use impractical in the context of a workshop. It is for example necessary to drain the device after disconnecting the converter, or at least to drain it frequently, the connections / disconnections introducing air into the hydraulic circuit.

The invention aims to provide a spring compressor having the compactness of hydraulic compressors, but not requiring the use of an external converter.

To this end, there is provided a spring compressor comprising a tubular body provided with means for attaching a first cup, a tubular rod mounted to slide without rotation in the body, carrying at the outer end to the body means of attachment d '' a second cup, and a counter-rod internal to the rod secured to the body by one of its ends while its other end is shaped as a terminal piston on the periphery of which the rod slides in leaktight fashion, the end of the rod inside the body bearing a sealed slide on the counter rod so as to define between the rod, the counter rod and the terminal piston a chamber with variable volume, in permanent communication with a central channel formed in the counter rod. According to the invention, the central channel is connected to the outlet of a pump fixed to the body and comprising a plunger movable in the axis of the central channel of the counter rod, supplying the variable volume chamber with hydraulic fluid by l 'through a neutralized unidirectional valve located in the axis of the plunger.

Thus, we obtain an autonomous compressor whose

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 compressor compressor fluid is pressurized oil, which gives this compressor compact dimensions. The oil is in a closed circuit in the compressor, which facilitates its handling, and avoids the emptying of the compressor after use, and the purges at each start-up. In addition, to adjust the stroke of the rod in the body and therefore the approximation of the cups, it suffices to operate the pump several times, the oil accumulating in the chamber of variable volume, prevented from leaving it by the one-way valve.

Several drive motors for the plunger pump are possible. In a first embodiment, the plunger is formed by the rod of a single-acting pneumatic cylinder whose body is attached to one end of the compressor body. Thus, the compressor is actuated by compressed air, available in most workshops.

According to a second embodiment, the plunger is integral with the core of an electromagnet.

Thus, an electrical outlet is sufficient to operate the compressor. The compressor advantageously comprises a needle coaxial with the rod of the plunger, the position of which along its axis is adjustable relative to the unidirectional valve between an inactive position and a neutralization position of the latter.

Thus the control of the one-way valve is obtained by a simple movement of the needle. Advantageously, the needle is integral with an operating member from its position accessible from outside the cooperating body by screwing and unscrewing with the latter in the direction of its axis.

Preferably, the pump is provided in an autonomous module which can be separated from the body. It is then expected that a bottom will fit on the body in place of the pump, rete-

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 the counter rod and providing a passage for oil to the central channel of the counter rod.

Thus, it is also possible to use an external pump supplying oil under pressure.

Other characteristics and advantages of the invention will appear more clearly in the light of the following description of a particular non-limiting embodiment of the invention, with reference to the drawings and the figures among which - FIG. 1 is a sectional view of a spring compressor, not equipped with a pump; - Figure 2 is an enlarged partial view of a compressor similar to that shown in Figure 1, equipped with a pump according to the invention; - Figure 3 is a partial sectional view of a compressor according to the invention equipped with an oil tank.

In FIG. 1, a spring compressor of generally cylindrical shape along the axis X is shown in the minimum extension position, and comprises a body 1 composed of a tubular casing 2 in which a concentric sleeve 3 is slidably mounted. The rotation of the sleeve 3 with respect to the casing 2 is prevented by the cooperation of a key 4 integral with the casing extending in internal projection, cooperating with the sides of a longitudinal groove S produced on the external surface of the sleeve 3. The casing 2 is closed at one end by a bottom 6 screwed onto the casing 2 by means of a thread 20, and carries at its other end a means of attachment 7 for a non-cup shown here, consisting of a support ring and a clamping ring.

A tubular rod 8 is slidably mounted in the body 1, more precisely in the sleeve 3, opposite which its rotation is prevented by a key device 9 and groove 10 similar to the previous one.

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 The role of the sleeve 3 is to provide axial guidance of the rod 8 on the body 1 in the event of large extension of the compressor, in order to prevent the rod 8 from jamming in the body 1 by bracing. Indeed, the eccentricity of the cups relative to the axis of the compressor causes the appearance of a bending moment induced by the force of the spring resisting its compression. This bending moment can generate jamming of the rod 8 in the body 1 if its guidance is not well ensured. The sleeve 3 is in a way a telescopic extension of the envelope 2.

This rod carries at one end a tip 11 with a vent 11a closing the rod, itself carrying an attachment means 12 of a second cup, also not shown. The cooperation of this end piece 11 with the end face 13 of the casing 1 defines an axial abutment of the rod 8 with the casing 1. The other end of the rod 8 carries an annular piston 14, mounted with sealed sliding on a tubular, concentric counter-rod 15, extending inside the rod 8, and passing through the annular piston 14. This counter-rod is attached to the bottom 6 of the casing 1, while its end carries a piston terminal 16 covering the counter-rod 15 and on which the internal surface of the rod 8 is mounted with sealed sliding. A chamber 17, of variable volume with the sliding of the rod 8, is thus defined between the internal surface of the rod 8, the external surface of the counter-rod 15, the annular piston 14 and the terminal piston 16. This chamber 17 is permanently connected with an interior of the counter-rod 15 forming the central supply channel 24 of the chamber by an orifice 18 passing through the wall of the counter-rod 15.

A nozzle 19 secured to the bottom 6 makes it possible to connect the central channel 24, therefore the chamber 17, to a source of pressurized oil. Pressure oil intake

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 in the chamber 17 has the effect of moving the piston 14 away from the bottom 16, therefore bringing the rod 8 into the body 1, the sleeve 3 being pushed inside the envelope by the end piece 11 in the case or it would have partially come out of envelope 2.

An orifice 21 pierced in the bottom 6 and forming a vent allows the chamber between the body 1, the counter-rod 15, the annular piston 14 of the rod 8 and the bottom 6 to be brought to the open air.

A concentric cylindrical cavity 22 is formed at the end of the counter-rod 15 closest to the bottom 6, in which an insert 23 secured to the bottom 6 carrying the end piece 19 is threaded in leaktight manner to put this end piece 19 with the central channel 24.

In FIG. 2, a spring compressor according to the invention is presented, equipped with a pump in place of the bottom 6.

On this compressor, a pump according to the invention is composed of a module 50 adapting to the body 1, as well as a cartridge 51 fitting into the cylindrical cavity 22 of the counter rod.

The module 50 is composed of a cylindrical casing 52 adapting coaxially to the same thread 20 of the body 1 as the bottom 6, the casing 52 acting as the bottom for the body 1. This casing 52 has a cavity 53 open on the side opposite to the body 1, and closed in leaktight manner by a bottom 54 screwed onto the casing 51.

In the cavity 53 is mounted with sealed sliding a plunger piston 56, a part of large section 57 defines with the cavity 53 a chamber 58 of variable volume supplied with compressed air by means of the nozzle 59 secured to the bottom 54, as well as a chamber 60 vented through the orifice 61 passing through the wall of the casing 52, housing a spring 62 for returning the plunger piston 56 towards a stop 63 of the casing 52. A small section portion 64 of the piston

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 plunger 56 sealingly passes through the casing 52 to enter a cylindrical cavity 65 coaxial with the cartridge 51, defining in the cavity 65 a chamber 74 of variable volume.

This chamber is capable of sucking oil from a reservoir, by means of a one-way valve formed by a ball 68 supported on a seat 69 formed in the cylindrical wall of the cartridge 51, putting the chamber with a longitudinal groove 67 formed on the outside of the cartridge 51, itself connected to a thread 66 for connection of a hydraulic nozzle by a conduit 70. The ball 68 can take off from its seat 69, but is forced to do not move away from it by a needle 55 slidably housed in the piston 56 in order to be able to come into contact with the bottom 54. It extends to a one-way valve formed by a ball 71 supported on a seat 72 formed at the end of the cartridge 51 at the outlet of the chamber 65 in the central channel 24 of the counter rod. The ball 71 can take off from its seat 72, but is constrained not to move away from it by a grid or pin 73 at the end of the cartridge 51. In an embodiment not shown, the retaining function of the ball 71 can be ensured by a secondary needle freely housed in channel 24 of the counter rod. This solution simplifies sealing issues.

The operation of the device is as follows: compressed air is admitted into the chamber 58, forcing the piston to slide against the spring, and increasing the pressure in the chamber 74 filled with oil. Under pressure, the ball 68 is. pressed on the seat 69 preventing the oil from pumping back into the tank. This oil pushes the ball 71 and enters the counter rod 15, then into the chamber 17. The oil pressure is deduced from the compressed air pressure by multiplying it by the ratio of the large section 56 to the small section 64 of the plunger

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 56. When the admission of compressed air is stopped, for example if the piston is at the end of its travel by simultaneously placing the chamber 58 in the exhaust, the ball 71 rests on its seat 72 to isolate the chambers 74 and 17. The piston is returned to the stop 63 by the return spring 62, increasing the volume of the chamber 74 and decreasing the pressure prevailing in this chamber until the ball 68 takes off from its seat 69 to admit the oil from the reservoir and gradually filling the chamber 74. Then we start again, until we have obtained the compression of the desired spring.

To release the compressor, that is to say bring the rod 8 out of the body 1, it suffices to take off the ball 71 from its seat 72, so that the oil contained in the chamber 17 can spill into the chamber 74 d 'first, under the effect of the force of the compressed spring between the cups or under the effect of a manual operation of the extension of the compressor in the absence of spring between the cups, then in the tank then by means a bypass orifice 75 formed in the cylindrical wall of the cartridge 51, bypassing the non-return valve formed by the ball 68 and its seat 69. To do this, the bottom 54 is screwed forming the axial operating plunger of the needle 55, until the end of the needle 55 slightly pushes the ball 71, causing it to take off from its seat 72. The thread allows fine adjustment of this separation, in order to control the speed of compressor extension by adjustment. This neutralizes the one-way valve.

Advantageously, provision is made for the oil tank to be integrated into the compressor, for example in a handle adaptable to the compressor, as illustrated in FIG. 3.

There is a hydraulic tip 80 screwed onto the thread 66 of the housing 52. A collar formed by a part 81 and a part 82 is mounted around the housing 52 to enclose it, the two parts being linked by bou -

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 lons 83. The part 81 of the collar has an orifice 88 in which the hydraulic end piece 80 is inserted in a sealed manner. This orifice 88 is in communication with a cylindrical cavity of axis Y substantially parallel to the axis X, receiving a hollow cylindrical reservoir 84 screwed and open on the side of the part 81, in which a piston 85 is mounted with sealed sliding, defining a variable volume tank. It is possible to provide a deformable enclosure (rubber casing) which contains the useful volume of oil under slight overpressure (oleopneumatic tank for example). A spring 86 is installed between the piston and the reservoir to exert a light pressure on the oil, sufficient to push the oil into the compressor, whatever the position of the latter. A nozzle 87 is provided in the part 81 opening into the cavity 89, for draining the compressor or filling it with oil. The cylinder can be used as a handle for handling the compressor.

The invention is not limited to the particular embodiment which has just been described, but on the contrary intends to cover any variant which, with equivalent means, reproduces its essential characteristics without departing from the scope defined by the claims.

In particular, any other method of fixing the pump to the compressor is provided, such as for example a bayonet, clamping or other connection.

The cartridge 51 may be provided integral with the housing 52. The part 81 may come in one piece from the housing 52, in which case the hydraulic nozzle 80 is no longer necessary. The reservoir 84 can be formed by an annular volume provided around the compressor body, or take any other form. Of course, the compressor still works if we use an external tank connected to the compressor by a nozzle screwed into the thread 66.

It should be noted that the supply of the pneumatic cylinder

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 that will preferably be achieved by successive pressure pulses, each controlled by the operator by means of an appropriate member (trigger, push button, etc.) so that the latter can finely control the speed and amplitude of compression .

The use of other types of pumps is envisaged, for example of the rotary type associated with a turbine driven by compressed air, or even with an electric motor. As part of the plunger pump, manual control is also contemplated.

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Claims (9)

1. Spring compressor comprising a tubular body (1) provided with attachment means (7) of a first cup, a tubular rod (8) slidably mounted without rotation in the body (1), bearing at the outer end at body of the attachment means (12) of a second cup, and a counter-rod (15) internal to the rod (8) secured to the body (1) by one of its ends while its other end is shaped in a terminal piston (16) on the periphery of which the rod (8) slides in sealed manner, the end (14) of the rod (8) inside the bearing bearing body with sealed sliding on the counter-rod (15) to be defined between the rod (8), the counter rod (15) and the terminal piston (16) a variable volume chamber (17), in permanent communication with a central channel (24) formed in the counter rod (15 ), characterized in that the central channel (24) is connected to the outlet of a pump (50) fixed to the body (1) and comprising a plunger (56) movable in the axis (X) of the central channel (24) of the counter rod (15), supplying the variable volume chamber (17) with hydraulic fluid via a valve unidirectional (71,72) neutralizable located in the axis of the plunger (56). 2. Compressor according to claim 1, characterized in that the plunger (56) is formed by the rod (64) of a pneumatic cylinder (50) single acting whose body (52) is attached to one end of the body (1) of the compressor. 3. Compressor according to claim 1, characterized in that the plunger (56) is integral with the core of an electromagnet. 4. Compressor according to claim 2 or 3, characterized in that the compressor comprises a needle (55) coaxial with the rod (64) of the plunger (56) including <Desc / Clms Page number 12>  the position along its axis is adjustable relative to the one-way valve (71,72) between an inactive position and a neutralization position of the latter. 5. Compressor according to claim 4, characterized in that the needle (55) is associated with an operating member (54) accessible from outside the body (1) cooperating by screwing and unscrewing with the latter in the direction of its axis. 6. Compressor according to one of the preceding claims, characterized in that a reservoir (84) is integral with the compressor. 7. Compressor according to one of the preceding claims, characterized in that the pump (50,51) is arranged in an autonomous module, fixed in a removable manner on the body (1). 8. Compressor according to claim 7, characterized in that a bottom (6) is provided to adapt in place of the pump (50,51), provided with a nozzle (19) to allow admission of oil under pressure from an outside circuit towards the inside of the counter rod (15). 9. Compressor according to one of the preceding claims, characterized in that the body comprises a tubular casing (2) in which a tubular sleeve (3) is slidably mounted without rotation, the rod (8) sliding without rotation in the sleeve (3).