WO2017121937A1

WO2017121937A1 - Movement transmission and filtering device

Info

Publication number: WO2017121937A1
Application number: PCT/FR2016/053549
Authority: WO
Inventors: Damien Piranda; Benoit GASTALDIN
Original assignee: Peugeot Citroen Automobiles Sa
Priority date: 2016-01-14
Filing date: 2016-12-19
Publication date: 2017-07-20
Also published as: FR3046823B1; CN108463648A; CN108463648B; EP3403001A1; FR3046823A1

Abstract

The invention relates to a device (4) for transmitting rotational movement and filtering vibrations, this device comprising a first rotary element (6) and a second rotary element (37) coupled to the first rotary element, the coupling being achieved by means of primary damping elements (33) defining a first filtering stage able to filter vibrations, in which the coupling is also performed by secondary damping elements (36) defining a second filtering stage. The coupling is arranged in such a way that rotation of the first rotary element causes rotation of the primary damping elements which drive the rotation of the secondary damping elements which in turn drive the rotation of the second rotary element, and in that the static stiffness of the first filtering stage is lower than the static stiffness of the second filtering stage by at least ten percent.

Description

MOVEMENT TRANSMISSION DEVICE

AND FILTERING

The invention relates to the field of automobiles, and more particularly to motion transmission and filtering devices.

[0002] Motion transmission devices are widely present on motor vehicles. This type of device is found in gearboxes. They are used, for example, to obtain an output rotation speed different from an input rotation speed.

[0003] Motion transmission can generate jolts and vibrations, reducing the longevity of the mechanical parts of the motor vehicle. The user can also feel these vibratory and sound nuisances.

In order to avoid the aforementioned drawbacks, the German document published under the number DE 102009000014 describes a device for transmitting and filtering vibrations. This device comprises a first rotary element and a second rotary element which is coupled to the first rotary element. Coupling is achieved by means of a series of damping elements. These damping elements are three in number, and are inserted in housings in the first rotary element. The second rotary member comprises pins, housed in cavities formed inside the damping elements. The rotation of the first rotary member causes the rotation of the damping elements, which in turn causes the second rotary element to rotate.

This type of device has disadvantages. Indeed, these devices filter in practice vibrations over a frequency range located approximately above 140 Hz. It is possible to use such devices to filter below this value, but the devices then have significant dimensions at look at the volume available in motor vehicles.

In the case of air conditioning compressors, a technique for filtering vibrations consists, in addition to the motion transmission device and filtering, to install a flyweight at the end of the compressor shaft. This increases the inertia and decreases the vibrations. In return, such a technique has many disadvantages, among which a pronounced fatigue of the elements of the compressor, to the detriment of the longevity of this organ.

A first objective is to provide a device that is able to filter the vibrations over a wide range of frequencies, especially less than 140 Hz, while remaining compact and low weight.

A second objective is to overcome the use of specific elements designed to create inertia to reduce vibrations.

For this purpose, it is proposed, in the first place, a device for transmitting rotational movement and vibration filtering, this device comprising a first rotary element and a second rotary element coupled to the first rotary element, the coupling being made by primary damping elements, defining a first filter stage capable of filtering vibrations, the coupling being furthermore produced by secondary damping elements defining a second filtering stage, this coupling being arranged in such a way that the rotation of the first rotary member causes rotation of the primary damping elements, which cause rotation of the secondary damping elements, in turn causing the rotation of the second rotary member, the static stiffness of the first filter stage being less than the stiffness static filter second stage of at least ten percent.

Preferably, the static stiffness of the first filter stage is less than the static stiffness of the second filter stage of at most 40%.

More preferably, the static stiffness of the first filter stage is less than the static stiffness of the second filter stage of at least 15 or 20%, especially about 15%.

These differences in stiffness values thus selected are particularly advantageous: below 10%, mode coincidences may be problematic, and beyond 40% can be observed a decrease in endurance of the device. A difference of 15 to 20% is very advantageous for preserving endurance performance while obtaining the desired technical effect.

This device significantly improves the efficiency of filtering, to the benefit of passenger comfort and longevity of mechanical parts. In addition, it eliminates the use of a flyweight to create rotational inertia.

Various additional features may be provided, alone or in combination: the device comprises a support member provided with pins, on which are mounted the primary damping elements, and arms, on which are mounted the secondary damping elements;

In this case, the primary damping elements and the secondary damping elements may preferably be identical: it is thus possible to rationalize their manufacture by obtaining the desired stiffness variations by adapting their assembly and the design of the arms and pawns. .. but retaining only one type of damping element.

the pins have, in section, a starry profile;

each arm comprises a bend, so that a longitudinal axis of the arms is substantially perpendicular to a longitudinal axis of the pins;

the first rotary element is a pulley comprising in section a rail provided with two lateral edges, the rail comprising teeth, the lateral edges being raised relative to the teeth and together forming a reception zone for a belt;

the pulley comprises a main cavity, provided with an annular notch, this annular notch being able to receive an annular belt provided with a plurality of tongs for receiving the primary damping elements;

the second rotary element has a general disc shape comprising a series of bores for accommodating the secondary damping elements;

the primary damping elements and the secondary damping elements are provided with a groove, this groove making it possible to house the primary damping elements in the clamps of the annular belt housed in the first rotary element on the one hand, and to accommodate the secondary filtering elements in the holes of the second rotary element on the other hand.

It is proposed, secondly, a motor vehicle comprising a device as previously described.

Advantageously, the whole piece and pads can be obtained by a single mold bi-material injection.

Other features and advantages of the invention will appear more clearly and concretely on reading the following description of embodiments, which is made with reference to the accompanying drawings in which: FIG. 1 is a perspective view of the front of a motor vehicle equipped with a device for transmitting motion and filtering vibrations,

FIG. 2 is an exploded perspective view of a device for transmitting motion and filtering,

FIG. 3 is a sectional view along the plane of section III-III of a first rotary element of the device of FIG. 2,

FIG. 4 is a perspective view of the device of FIG. 2; FIG. 5 is a perspective view of a second rotary element of the device;

FIG. 6 is a perspective view of a support element of the device,

FIG. 7 is a sectional view along the section plane VII-VII of a pin of the support element of FIG. 6,

FIG. 8 is a perspective view of the support element of FIG. 7 provided with damping elements,

Figure 9 is a perspective view of the support member inserted in the first rotatable member.

In Figure 1 is shown a front portion of a vehicle 1 automobile. This vehicle 1 comprises a powertrain 2 provided with a compressor 3 air conditioning. The air conditioning compressor 3 comprises a shaft (not shown) on which is mounted a device 4 for transmitting motion and filtering. The device 4 is driven by a belt 5.

One defines with respect to the vehicle 1 an orthogonal reference XYZ comprising three axes perpendicular two by two, namely:

an axis X defining a longitudinal, horizontal direction coinciding with the general direction of movement of the vehicle 1,

a Y axis, defining a transverse, horizontal direction which, with the X axis, defines a horizontal XY plane;

an axis Z, defining a vertical direction perpendicular to the horizontal XY plane.

In the following, the device 4 will be detailed. With reference to FIG. 2, the device 4 comprises a first rotary element, hereinafter called a pulley 6. The pulley 6 has a generally circular shape.

As illustrated in Figure 3, the pulley 6 comprises in section a rail 7. The rail 7 is provided with two lateral edges 8. Between the two edges 8 side, the rail 7 is provided with teeth 9. The lateral edges 8 are raised relative to the teeth 9, so as to form a reception area for the belt 5. The teeth 9 allow the belt 5 to adhere to the rail 7.

The pulley 6 comprises a main cavity 10 and a secondary cavity 11. The secondary cavity 11 is formed in the main cavity 10 by a disc 12 which extends one of the lateral edges 8. The disk 12 extends substantially in the XZ plane and has a hole 13 at its center.

An annular belt 17 comprises a series of clamps 18. Each clamp 18 comprises two hooks 19 defining a housing 20. In the embodiment shown in the figures, the annular belt 17 comprises six clamps 18. The annular belt 17 is advantageously obtained by injection with the pulley 6. Other embodiments of the annular belt 17 may nevertheless be used.

The device 4 comprises a support element 21. The support element 21, shown in detail in FIG. 6, comprises an annular base 22 defining an orifice 23. The support element 21 comprises, on an outer periphery 24 of the annular base 22, studs 25. With reference to FIG. 7, the pins 25 have, in section, a star-shaped profile defining a plurality of ripples 26. In one embodiment, the support element 21 comprises six pins 25.

The support member 21 further comprises a plurality of arms 27. A base 28 of each arm 27 extends partly on the outer periphery 24 and on a side face 29 of the annular base 22. Each arm 27 comprises a bend 30 modifying the direction of extension of the arms 27. Thus, a longitudinal axis 31 of the arms 27 is substantially perpendicular to a longitudinal axis 32 of the pins 25. This provision has advantages which will be presented later in this description.

A series of primary damping elements 33 are mounted on the pins 25, and represent in the following a first vibration filtering stage. These primary damping elements 33 comprise a passage 34, able to receive a pin 25 of the support element 21. These primary damping elements 33 also include a groove 35, the function of which will be explained later.

The contact between the primary damping element 33 and the pin 25 is discontinuous, because of the ripples 26. This improves the progressiveness of the filtering, and reduces the static stiffness of the first filter stage. A series of secondary damping elements 36 serves as a second filter stage. The secondary damping elements 36 have a geometry similar to that of the primary damping elements 33. The secondary damping elements 36 are mounted in force on the arms 27. The arms 27 have a smooth surface, which advantageously makes it possible, in conjunction with the force assembly, to increase the static stiffness of the second filtering stage.

The device 4 comprises a second rotary member hereinafter referred flange 37. The flange 37 is provided with a series of holes 38. The flange 37 has a general shape of disk extending in the plane XZ. A nozzle 39 extends perpendicular to the flange 37, and may for example be reported by screwing on the axis of the system equipped with the device, this system may be for example an air conditioning compressor for a motor vehicle (not shown here).

The assembly of the device 4 will now be described, with reference to FIG. 2.

The annular belt 17 is obtained by molding during the injection of the pulley 6. The primary damping elements 33 are mounted on the star pins 25, and the secondary damping elements 36 are mounted through the holes. 38 flange 37. These montages are in force. The support member 21 is inserted into the main cavity 10 of the pulley 6, as illustrated in FIG. 9. The insertion is made by forcing the passage of the primary damping elements 33 through the hooks 19, level of the grooves 35. The flange 37 is then reported, so that the secondary damping elements 36 are inserted into force on the arms 27 of the support member 21. The nozzle 39 of the second rotary member then extends inside the main cavity.

A rotation of the pulley 6 causes the rotation of the primary damping elements 33, which rotate the support member 21 on which are mounted the secondary damping elements 36. The secondary damping elements 36 finally rotate the flange 37 which can transmit the movement to a mechanical part of the automobile vehicle 1.

As previously mentioned, the device 4 is advantageously mounted on the shaft of the air conditioning compressor 3 of the vehicle 1. More precisely, the compressor shaft 3 is fixed to the nozzle 39. of the flange 37. Thus, a belt 5, mounted on a crankshaft engine (not shown) can drive the shaft of the compressor 3, via the device 4.

At the device 4, the vibrations can be decomposed along the three axes X, Y and Z. The provision of primary damping elements 33 and secondary damping elements 36 advantageously reduces vibrations according to these three axes. Regarding the axis of rotation of the compressor, namely Y, the vibrations are reduced by a slight movement back and forth along Y, made possible by the mounting of the secondary damping elements 36 on the arms 27. The In this way, vibrations are partly dissipated by the movement back and forth.

The provision of the primary damping elements 33 relative to the secondary damping elements 36 advantageously reduces the vibrations felt around the axis of rotation Y.

The number of damping elements on each filtering stage depends on two criteria. On the one hand, increasing the number of damping elements on each floor implies an increase in the contact area. Thus, the greater the contact area, the more vibrations will be transmitted. On the other hand, reducing the number of damping elements weakens the device 4. Each filtering stage thus advantageously comprises six damping elements, ensuring robustness and filtering of vibrations.

The static stiffness of the first filter stage is less than the static stiffness of the second filter stage of at least ten percent.

Bench tests have shown that a double filter stage having a differentiated stiffness of at least ten percent between the filter stages, advantageously allows to filter the vibrations above a threshold value of about 90 Hz. In other words, the device 4 transmits the movements while filtering the vibrations whose frequency is greater than about 90 Hz. For frequencies greater than about 90 Hz, their amplitude is damped to become negligible.

This represents a considerable advance for devices 4 of motion transmission in vehicles 1 automobiles. Filtering is indeed improved thanks to a device 4 whose dimensions are conducive to use in a small environment. Filtering under this value of about 90 Hz allows, for example, to filter the acyclisms of air conditioning compressors.

Another advantage is that it is no longer necessary to add a flyweight, in order to generate inertia on the end of the compressor shaft 3 to limit vibration.

Another advantage lies in the fact that the primary damping elements 33 and the secondary damping elements 36 are identical, only their arrangement as well as the pins 25 and arms 27 on which they are mounted being different, in order to vary the static stiffness. This greatly simplifies assembly, avoiding errors being made during assembly of the device 4.

Claims

1. Device (4) for transmitting rotational movement and vibration filtering, said device (4) comprising a first rotary element (6) and a second rotary element (37) coupled to the first element

(6) rotatable, the coupling being effected by primary damping elements (33) defining a first filter stage capable of filtering vibrations, characterized in that the coupling is additionally provided by damping elements (36). ), defining a second vibration filtering stage, said coupling being arranged in such a way that the rotation of the first rotary element (6) causes the rotation of the primary damping elements (33), which cause the rotation of the elements of secondary damping (36) which in turn causes rotation of the second rotating element (37), the static stiffness of the first filtering stage being less than the static stiffness of the second filtering stage by at least ten percent.

2. Device according to the preceding claim, characterized in that the static stiffness of the first filter stage is less than the static stiffness of the second filter stage of at most 40%.

3. Device according to one of the preceding claims, characterized in that the static stiffness of the first filter stage is less than the static stiffness of the second filter stage of at least 15 or 20%, especially about 15%.

4. Device (4) according to one of the preceding claims, characterized in that it comprises a support member (21) provided with pins (25), on which are mounted the primary damping elements (33), and arms (27), on which are mounted the secondary damping elements (36).

5. Device according to the preceding claim, characterized in that the primary damping elements (33) and the secondary damping elements (36) are identical.

6. Device (4) according to claim 4 or 5, characterized in that the pins (25) have in section, a starry profile.

7. Device (4) according to any one of claims 4 to 6, characterized in that each arm (27) comprises a bend (30), so that a longitudinal axis (31) of the arms (27) is substantially perpendicular to a longitudinal axis (32) of the pins (25).

8. Device (4) according to any one of the preceding claims, characterized in that the first element (6) rotary is a pulley comprising in section a rail (7) provided with two edges (8) side, the rail (7). ) comprising teeth (9), the lateral edges (8) being raised relative to the teeth (9) and together forming a reception area for a belt (5).

9. Device (4) according to the preceding claim, characterized in that the pulley comprises a main cavity (10) provided with an annular belt (17) having a plurality of clamps (18) for receiving the damping elements (33). ) primary.

10. Device (4) according to one of the preceding claims, characterized in that the second element (37) rotates has a generally disk shape comprising a series of holes (38) for accommodating the damping elements (36) secondary .

11. Device (4) according to the preceding claim, characterized in that the primary damping elements (33) and the secondary damping elements (36) are provided with a groove (35), this groove (35) allowing for accommodating the primary damping elements (33) in the clamps (18) of the annular belt (17) housed in the first rotary element (6) on the one hand, and for accommodating the secondary filter elements in the holes of the second element (37) rotating on the other hand.

12. Vehicle (1) automobile comprising a device (4) according to any one of the preceding claims.