EP3859128A1 - Device for phase shifting a rotation angle of a driving section relative to a driven section - Google Patents

Abstract

Device for phase shifting an angle of rotation of a drive part (2) to an output part (4), with a double gear (25) which has an externally toothed, first gear (24) and an externally toothed, second gear (26), the two gears (24 , 26) are non-rotatably connected to one another, an internally toothed, first ring gear (22) which is non-rotatably connected to the drive part (2) and is operatively connected to the externally toothed, first gear (24), an internally toothed, second ring gear (28), which is rotatably connected to the output part (4) and is operatively connected to the externally toothed, second gear (26), and an eccentric (32) on which the double gear (25) are rotatably mounted via a bearing element (48), with radially between the Double gear (25) and the eccentric (32) at least one elastomer element (60, 62) is arranged, the eccentric (32) or the double gear (25) having a groove (72, 74), wherein in the groove (72, 74 ) the minde at least one elastomer element (60, 62) is arranged.

Description

The invention relates to a device for phase shifting an angle of rotation of a drive part to an output part, with a double gear, which has an externally toothed, first gear and an externally toothed, second gear, the two gears are non-rotatably connected to one another, an internally toothed, first ring gear, which with the drive part is rotatably connected and is operatively connected to the externally toothed, first gear, an internally toothed, second ring gear, which is rotatably connected to the output part and is operatively connected to the externally toothed, second gear, and an eccentric on which the double gear rotates via a bearing element is mounted, wherein at least one elastomer element is arranged radially between the double gear and the eccentric.

Such devices are known in particular for phase shifting between a crankshaft and a camshaft. The phase shift is used to control the opening and closing times of the intake and exhaust valves of an internal combustion engine, which improves the gas exchange process. For the phase shift between the crankshaft and camshaft, eccentric gears are often used, which are usually designed with an eccentric. Two externally toothed gears that are firmly connected to one another are mounted on an eccentric, a first externally toothed gear with a drive ring gear and a second, externally toothed gear with a Output ring gear are in engagement. In addition, the eccentric is driven by an actuator, the magnitude of the phase shift and the direction of the phase shift being set by the rotational speed of the eccentric.

A device for phase shifting an angle of rotation of a drive part with respect to an output part is disclosed, for example, in US Pat JP 2012-092720 . The device has a driven drive part, a driven part and an eccentric gear. The eccentric gear includes an eccentric, on the outer surface of which a double gear with two different external gears is rotatably mounted. A first external toothing is operatively connected to a first, internally toothed ring gear and a second external toothing is operatively connected to a second, internally toothed ring gear. The first ring gear is connected to the drive part and the second ring gear is firmly connected to the driven part.

To radially pretension the double gear against the ring gears, an elastomer element is provided radially between the eccentric and the double gear. The elastomer element is deformed and preloaded during the assembly process, so that the elastomer element radially preloads the double gearwheel in the assembled state. The elastomer element has a hollow cylindrical shape and is held in its mounted position radially and axially by pressing between a bearing element and the eccentric or the double gear wheel.

A disadvantage of such a configuration of the device for phase shifting is that the elastomer element can move axially during operation of the device, since the compression of the elastomer element does not result in an axial displacement of the elastomer element can reliably prevent. If the elastomer element is displaced, there is a risk that the elastomer element and the entire device will be damaged. The double gear wheel can tilt due to the axial displacement of the elastomer element and thereby cause the gear wheels to jam. Furthermore, due to the axial displacement of the elastomer element, the predefined radial tension between the external toothing of the double gear and the internal toothing of the ring gears cannot be guaranteed.

The invention is therefore based on the object of providing a device for phase shifting an angle of rotation of a drive part with respect to an output part, in which proper operation can be ensured over the entire service life and damage to the device can be reliably prevented.

This object is achieved by a device with the features of the main claim.

Because the eccentric or the double gear wheel have a groove, the at least one elastomer element being arranged in the groove, the elastomer element is securely and reliably held in a predefined, axial position and tilting of the double gear wheel due to undesired displacement of the elastomer element is reliably prevented. As a result of the arrangement of the elastomer element in the groove, the elastomer element is axially fixed in a form-fitting manner on the eccentric or the double gear wheel, the elastomer element being pressed radially into the groove in its assembled state. In this way, the elastomer element is reliably prevented from sliding out of the groove. This ensures the preload between the double gear and the ring gears reliably over the entire service life and reliably prevents damage to the device due to displacement of the elastomer element.

The elastomer element is preferably arranged radially between the bearing element and the double gear, the groove being provided on an inner circumferential surface of the double gear facing the eccentric. Alternatively, the elastomer element is arranged radially between the eccentric and the bearing element, the groove being provided on an outer circumferential surface of the eccentric facing the double gearwheel. In this way, the elastomer element can be installed easily and reliably, with the elastomer element being preassembled together with the position element and the eccentric or the double gear to form a preassembly assembly during the assembly process of the device and then finally assembled with the other components of the device.

In a preferred embodiment, the eccentric has a sleeve which is arranged on the outer circumferential surface, the elastomer element being arranged radially between the outer circumferential surface and the sleeve. In this way, the elastomer element can be positioned and fixed on the eccentric even before the final assembly of the device. The outer circumferential surface of the sleeve also serves as the inner race of the bearing element designed as a roller bearing. As a result, the radial installation space of the device can be reduced.

Preferably, the elastomer element is made of a fluorine rubber or a hydrogenated acrylonitrile butadiene rubber, the hydrogenated acrylonitrile butadiene rubber having a relatively high heat resistance, good mechanical properties and good aging resistance.

In a preferred embodiment, the elastomer element is an O-ring, whereby the assembly of the elastomer element can be simplified.

The elastomer element preferably has a first surface facing the double gearwheel and a second surface facing the eccentric, at least one of the two surfaces being embodied in a wave-like manner. In a preferred embodiment, both surfaces are designed to be wave-like. In the assembled state, the elastomer element rests with the deformed tips of the wave-like surface on the double gearwheel and / or the eccentric. In this way, the double gear wheel is evenly pretensioned over the circumference and overloading of the elastomer element is reliably prevented.

Two elastomer elements are preferably provided, which are arranged axially spaced from one another. As a result, the relatively wide double gear can be radially evenly pretensioned and tilting of the double gear can be reliably prevented. Furthermore, a rotation of the double gear about a vertical axis is reduced, the rotation resulting from the fact that different loads resulting from the toothing act on the first externally toothed gear and the second externally toothed gear.

In a preferred embodiment, the two elastomer elements can be made in one piece, the two elastomer elements being axially coupled to one another via a connecting element made in one piece with the elastomer elements.

In a preferred embodiment, the two elastomer elements are each arranged in a separate groove, whereby both elastomer elements can be held safely and reliably in a predefined, axial position.

A sheet-metal spring element is preferably arranged radially between the eccentric and the double gear wheel, the sheet-metal spring element loading the double gear wheel radially. The sheet-metal spring element loads the double gear wheel radially in the same direction as the elastomer element and thus supports the elastomer element when the double gear wheel is radially pretensioned. The section arranged axially between the two grooves preferably serves as a radial stop, the stop limiting compression of the elastomer elements and thereby reliably preventing overloading of the elastomer elements.

The sheet-metal spring element and the elastomer element together form a spring system for the radial preloading of the double gear wheel, the sheet-metal spring element having a spring characteristic such that the spring force of the sheet-metal spring element increases from a predefined spring travel, thereby preventing damage to the elastomer element.

In a preferred embodiment, the bearing element is a needle bearing, as a result of which the radial installation space of the device can be reduced.

The double gear is preferably made in one piece, the externally toothed first gear being made in one piece with the externally toothed second gear. As a result, the assembly effort of the device can be reduced.

A device is thus created which reliably ensures the preload between the double gear and the ring gears over the entire service life in a simple and inexpensive manner, in that an undesired displacement of the elastomer element is reliably prevented by arranging the elastomer element in a groove.

An embodiment of a device according to the invention is shown in the figure and described below.

the Figure 1 shows an embodiment according to the invention of a device for phase shifting a driven part to a drive part in a sectional view, and

the Figure 2 shows an elastomer element of the device according to the invention from Figure 1 .

The one in the Figure 1 The device shown comprises a drive part 2 and a driven part 4. The driven part 4 is connected in a rotationally fixed manner to a camshaft 6 via a screw 5, a screw shaft of the screw 5 extending through an opening 7 provided on the driven part 4 and being screwed into the camshaft 6 . The drive part 2 has a sprocket 8 on an outer surface, which is produced in one piece with the drive part 2. A chain drive (not shown) engages the chain wheel 8, which connects the chain wheel 8 to a crankshaft (also not shown) and transmits a rotational movement of the crankshaft to the drive part 2.

An eccentric gear 16 is arranged on the side of the drive part 2 radially facing away from the sprocket 8. The eccentric gear 16 has a first gear pair 18 and a second gear pair 20. The first gear pair 18 comprises an internally toothed, first ring gear 22 and an externally toothed, first gear 24. The internally toothed, first ring gear 22 is on the side of the drive part facing away from the sprocket 8 2 and is made in one piece with the drive part 2. The externally toothed first gear 24 forms, together with an externally toothed second gear 26, a double gear 25, the two externally toothed gears 24, 26 being non-rotatably connected to one another and rotating with one another. The externally toothed, second gear 26 meshes with an internally toothed, second ring gear 28 which is connected to the output part 4 in a rotationally fixed manner and, together with the externally toothed second gear 26, forms the second gear pair 20.

The double gear 25 is designed in such a way that the externally toothed, first gear 24 has an axially extending stub 27 on which the externally toothed, second gear 26 is pushed. The non-rotatable connection between the first and second externally toothed gear 24, 26 can be established, for example, via a toothing or a press fit.

The double gear 25 is rotatably mounted on an eccentric 32 driven by a drive unit. The eccentric 32 is a one-piece internal eccentric which is rotatably mounted via a needle bearing 40 on an outer circumferential surface of a bearing stub 42 formed on the driven part 4. The inner running surface 44 of the needle bearing 40 is formed by the outer circumferential surface of the bearing stub 42. The outer running surface 46 of the needle bearing 40 forms the inner circumferential surface of the eccentric 32.

The rotatable mounting of the double gear 25 on the eccentric 32 takes place via a needle bearing 48 arranged radially between the double gear 25 and the eccentric 32, the outer running surface 50 being formed by the inner circumferential surface of the double gear 25. The inner running surface 52 of the needle bearing 48 forms an outer circumferential surface a sleeve 54 which is arranged on an outer circumferential surface of the eccentric 32. Two elastomer elements 60, 62 and a sheet-metal spring element 64 are provided radially between the sleeve 54 and the outer circumferential surface, the elastomer elements 60, 62 and the sheet-metal spring element 64 loading the double gear 25 radially. The play between the two externally toothed gears 24, 26 and the corresponding internally toothed ring gears 22, 28 can be compensated for by the radial load. In addition, the double gear 25 is damped radially by the elastomer elements 60, 62.

The sheet metal spring element 64 has a wave-like cross section and is arranged in a recess 66 provided on the outer circumferential surface of the eccentric 32.

The two elastomer elements 60, 62 are shown in FIG Figure 2 shown and are designed as O-rings. The elastomer elements 60, 62 each have a surface 70 facing the eccentric 32 and a surface 68 facing the double gear 25. Both surfaces 68, 70 have a wave-like shape. Due to the wave-like shape of the surfaces 68, 70, the elastomer elements 60, 62 in the final assembled state rest with the corresponding tips of the wave-like surfaces 68, 70 on the sleeve 54 and the eccentric 32.

According to the invention, the elastomer elements 60, 62 are each arranged in a groove 72, 74 produced on the outer circumferential surface of the eccentric 32. The two grooves 72, 74 are arranged axially spaced apart from one another and have an annular cross-section. The recess 66 and the sheet-metal spring element 64 are arranged axially between the two spaced apart grooves 72, 74. The grooves 72, 74 extend over the entire circumference of the outer peripheral surface of the eccentric 32, so that the ring-like elastomer elements 60, 62 are arranged over the entire circumference in the grooves 72, 74.

Due to the arrangement of the elastomer elements 60, 62 in the grooves 72, 74, the elastomer elements 60, 62 are reliably held axially in their predefined axial positions. This prevents undesired axial movement of the elastomer elements 60, 62.

It should be clear that other structural embodiments are also possible in comparison to the embodiment described without departing from the scope of protection of the main claim. For example, the eccentric 32 or the elastomer elements 60, 62 can be designed differently.

Claims (13)

Device for phase shifting an angle of rotation of a drive part (2) to a driven part (4), with
a double gearwheel (25) which has an externally toothed first gearwheel (24) and an externally toothed second gearwheel (26), the two gearwheels (24, 26) being non-rotatably connected to one another,
an internally toothed, first ring gear (22), which is non-rotatably connected to the drive part (2) and is operatively connected to the externally toothed, first gear (24),
an internally toothed, second ring gear (28), which is non-rotatably connected to the driven part (4) and is operatively connected to the externally toothed, second gear (26), and an eccentric (32) on which the double gear (25) via a bearing element ( 48) is rotatably mounted, with at least one elastomer element (60, 62) being arranged radially between the double gear wheel (25) and the eccentric (32),
characterized in that
the eccentric (32) or the double gear wheel (25) have a groove (72, 74), the at least one elastomer element (60, 62) being arranged in the groove (72, 74). Device according to claim 1,
characterized in that
the elastomer element (60, 62) is arranged radially between the bearing element (48) and the double gear (25), the groove (72, 74) being provided on an inner peripheral surface of the double gear (25) facing the eccentric (32). Device according to one of Claims 1 or 2,
characterized in that
the elastomer element (60, 62) is arranged radially between the eccentric (32) and the bearing element (48), the groove (72, 74) being provided on an outer peripheral surface of the eccentric (32) facing the double gear (25). Device according to claim 3,
characterized in that
the eccentric (32) has a sleeve (54) which is arranged on the outer peripheral surface, the elastomer element (60, 62) being arranged radially between that of the outer peripheral surface and the sleeve (54). Device according to one of the preceding claims,
characterized in that
the elastomer element (60, 62) is made from a fluorine rubber or from a hydrogenated acrylonitrile butadiene rubber. Device according to one of the preceding claims,
characterized in that
the elastomer element (60, 62) is an O-ring. Device according to one of the preceding claims,
characterized in that
the elastomer element (60, 62) has a first surface (68) facing the double gearwheel (25) and a second surface (70) facing the eccentric (32), at least one of the two surfaces (68, 70) being wave-like. Device according to claim 4,
characterized in that
both surfaces (68, 70) are made wave-like. Device according to one of the preceding claims,
characterized in that
two elastomer elements (60, 62) are provided, which are arranged axially spaced from one another. Device according to claim 9,
characterized in that
the two elastomer elements (60, 62) are each arranged in a separate groove (72, 74). Device according to one of the preceding claims,
characterized in that
A sheet-metal spring element (64) is arranged radially between the eccentric (32) and the double gear (25), the sheet-metal spring element (64) loading the double gear (25) radially. Device for phase shifting the angle of rotation of a drive part to a driven part according to one of the preceding claims,
characterized in that
the bearing element (48) is a needle bearing. Device for phase shifting the angle of rotation of a drive part to a driven part according to one of the preceding claims,
characterized in that
the double gear (25) is made in one piece.

Images