EP1180222A1 - Continuously variable gear - Google Patents

Abstract

The invention relates to a gear comprising a continuously variable gear ratio, whereby at least one drive wheel, one following gear and optionally an endless power transmission element are provided as links in a transmission chain, in order to prevent slip and thus improve the transmission of power. To achieve this, the links of the transmission chain have elements whose shape is adapted to one another and which are designed to intermesh in a positive-fit.

Description

 Continuously variable transmission

description

The present invention relates to a transmission with a continuously variable transmission ratio, at least one drive wheel and one driven wheel and optionally an endless power transmission element being provided as links in a transmission chain.

Infinitely variable transmissions are known, for example, from Dubbel: Taschenbuch für den Maschinenbau, 18th edition, pp. G 109 ff. Such gears can be set continuously for a uniform transmission of rotary movements in their translation l within a range between ι _mιn and ι _max . They are also called continuously variable transmissions or variable speed transmissions. A distinction must be made between manual transmissions, the translation of which can only be switched in m stages. The adjustment gears are mostly used in connection with simple electric motors of constant speed to drive such machines and devices, the drive speed of which should be infinitely adjustable, but also to keep a speed constant by fine adjustment in the event of fluctuating speeds of the drive machine. The translation is set manually or automatically by a controller.

The disadvantage of continuously variable transmissions is that the force transmission by rolling friction takes place under a certain contact pressure. Slippage occurs at the force transmission interface. The power-to-weight ratio is much higher than that of gearwheels, despite the higher efficiency.

BESTÄTfGUNGSKOPIE The object of the present invention is therefore to avoid slippage in the generic object and thus to achieve better power transmission.

This object is achieved in the generic subject matter in that the links of the transmission chain have negative and positive form elements which are matched to one another and are designed to be intermeshing in a form-fitting manner. In the case of continuously variable transmissions, friction inevitably creates a slippage, which has a disadvantageous effect on the power transmission. In the present invention, the

Power transmission boundary areas avoided the slip occurring during friction. The drive wheel and the driven gear either mesh directly with toothed wheels, or the force between the drive wheel and driven gear becomes one

Power transmission link, for example a chain, a toothed belt or a gear, preferably a ring gear.

In an advantageous embodiment of the invention, it is provided that one link of the transmission chain has a fixed division of the formula duck and the division of the form elements of the other link that comes with it is designed to be adjustable. To adjust the transmission ratio, the effective radius must be one

Flight circle, which describes the path of the form elements of the drive or driven wheel, are changed. However, a change in the radius is associated with a change in the division of the shaped elements, that is to say the distance between two shaped elements which are in engagement. In the present invention, one of the interlocking links of the transmission chain is provided with a constant division of the form elements, the division of the form elements of the other link being variable in the division. In a further advantageous embodiment of the invention, it is provided that the link with adjustable division has shaped elements which are designed as clamping members in a groove. The force is transmitted in one direction, namely the drive direction, between the drive wheel and the driven wheel by the clamping members, the pitch of the form-locking members in the opposite direction of the radius being able to adapt to one another. The adjustable form elements are arranged on the outer circumference of a wheel and engage in strip-shaped formula elements on the end face of another wheel.

In a further advantageous embodiment of the invention it is provided that the link with adjustable division of the shaped elements has those which are arranged on an axis of rotation with a freewheel. These can be the teeth of a pinion mounted on a freewheel, for example. Through the freewheeling, the force of the tooth is transmitted in one direction, namely the drive direction, between the drive wheel and the driven wheel, the division of the shaped elements, i.e. the meshing tooth of two successive pinions, in the opposite direction to a changed radius of the path of movement of the pinions, i.e. in the case of a changed flight circle, can adapt to the fixed division of the other link.

In a further advantageous embodiment of the invention it is provided that the link with an adjustable division is designed as a wheel with an adjustable diameter of the flight circle of the shaped elements. This embodiment of the invention is simply by adjusting the radius of the freewheel axis of the pinion, the teeth of which serve as formulas, from the axis of rotation of the wheel

_Gear ratio between drive wheel and driven wheel in a range ι _mιn to ι _max set. In a further advantageous embodiment of the invention it is provided that the diameter of the flight circle is adjustable by means of a motor. As a result, the transmission ratio m can be changed as a function of any parameters, such as engine load, pedal pressure, speed or power consumption, for example by an electric motor.

In a further advantageous embodiment of the invention it is provided that two substantially identical wheels as drive wheel and driven wheel are provided with an adjustable division, which are coupled to one another by means of an endless power transmission link, in particular a chain, with a fixed division of the shaped elements. Because the drive wheel and the driven wheel are constructed identically, manufacturing costs can be reduced.

In a further advantageous embodiment of the invention it is provided that the sum of the diameters of the flight circles is constant during an adjustment. This measure makes it unnecessary to keep the length of the power transmission element, which also had to change when the effective radius was changed, under tension by means of a wheel.

In a further advantageous embodiment of the invention it is provided that the power transmission link is designed as a gear, preferably internally toothed, or as a chain. There are fewer signs of wear on a gearwheel, the positive locking is more stable and it cannot jump off the drive or driven gear.

In a further advantageous embodiment of the invention it is provided that the wheel with adjustable division has two opposing conical outer surfaces with variable spacing, between which the Power transmission element is arranged with a fixed division, the axis of rotation of the shaped elements being arranged essentially parallel to a falling line of the conical surface. With this arrangement of the object according to the invention, the change in the effective radius is effected by

Distance change between two cones facing each other reached. The positive connection with the form elements of the power transmission element takes place through m the radially integrated strips of a turnstile integrated in the outer surfaces, which is mounted on a freewheel, the axis of which is arranged parallel to the outer cone surface. The power transmission element automatically takes the form of an arc on the outer surface of the cone, which ensures uniform torque transmission.

In a further advantageous embodiment of the invention it is provided that the wheel is flat, the axis of rotation of the shaped elements, i.e. the axis of the pinion mounted on a freewheel is arranged parallel to the axis of rotation of the wheel. In this embodiment, the distance of the freewheel axis from the axis of rotation of the wheel can be adjusted, for example, by arranging the free run on a radieally adjustable backdrop.

The invention is described in a preferred embodiment with reference to a drawing, with further advantageous details being shown in the figures of the drawing. Functionally identical parts are provided with the same reference numbers.

The figures in the drawing show in detail:

FIG. 1 shows a section of an embodiment of the continuously variable transmission in a first embodiment,

FIG. 2: a top view of a further embodiment of the continuously variable transmission, FIG. 3 shows a section of the adjustable gear according to section line III-III from FIG. 2,

FIG. 4: a schematic top view of a transmission according to FIG. 2,

FIG. 5: an alternative embodiment of a transmission according to the invention in a side view,

Figure 6: a detail section of a wheel with adjustable shaped elements and

Figure 7: a plan view of a wheel with a fixed angular division.

FIG. 1 shows a drive side 1 with a drive wheel 5 on the left-hand side and an output side 2 with a driven wheel 5 'on the right-hand side. In this embodiment, the drive wheel 5 and the driven wheel 5 'are essentially identical.

On the drive wheel 5 and the driven wheel 5 ′ there are fastening means 37 for fastening motors or components to be driven on the anti-friction side or on the friction side. These are not shown here.

The drive wheel 5 and the driven wheel 5 'are rotatably mounted in a housing 28 by means of a ball bearing 29, which in turn is fastened to a machine with fastening means 36, for example.

On the drive wheel 5 or the driven wheel 5 ', m supports 20 rotatably mounted threaded rods 30 are arranged in a star shape on the drive wheel 5 or the driven wheel 5'. The threaded rods 30 lie in a plane parallel to the plane of the drive wheel 5 or the driven wheel 5 'and are arranged in a spoke-like manner as many threaded rods 30 as possible should be arranged on the wheel.

The drive wheel 5 as well as the driven wheel 5 'can each be coupled to an electric motor 4, which drives a bevel gear 9, which is connected to the electric motor 4 by a shaft. The electric motor 4 is arranged perpendicular to the drive wheel 5 or the driven wheel 5 ′ and is mounted on the drive wheel 5 or the driven wheel 6 by fastening means 35.

Since the electric motor thus rotates with the drive wheel 5 or the driven wheel 5 ′, the power supply is produced via contact pins 26 and 27 with a current source outside the housing 28.

In the bevel gear 9 turn bevel gears 8, which are rotatably mounted at the ends of the threaded rods 30. The threaded rods 30 are thus rotated by the electric motor 4 at the same speed.

On the threaded rods 30 between the brackets 20 nuts 11 of a Spmdel nut Tπebes are arranged, on which the pinion 57, the teeth of which act as shaped elements 10, are rotatably mounted in a freewheel 13, the axis of rotation 42 of the pinion perpendicular to the plane of the Drive wheel 5 and the driven wheel 5 'is arranged.

The shaped elements 10 are thus displaceably arranged on a flight circle between the inner holder 20 of the threaded rods 30 and the outer holder 20 of the threaded rods 30.

A chain 58 meshes with the form elements 10 with a fixed division of the form elements as a power transmission element 3, in a form-fitting manner. When the position of the pinions 57 with their shaped elements 10 on the threaded rods 30 changes, the pitch of the shaped elements 10 changes. By rotating the pinions 57 m in the direction of their freewheeling, the pitch fits upon intervention automatically on the fixed division of the power transmission element 3. This adaptation is therefore carried out by the freewheel 13 of the shaped elements 10.

The torque of the drive is thus via the fastening means 37 to the drive wheel 5 from

Drive wheel 5 to the threaded rods 30 mounted thereon, from the threaded rods 30 in turn to the nuts 11 mounted thereon, the pinions 57mιt transfer the teeth acting as positive mold elements 10. The shaped elements 10 are in form-locking contact with the power transmission element 3, which is positively connected to the shaped elements 10 of the driven wheel 5 'in the same way. On the driven wheel 5 ', the power flow goes in the opposite direction up to the fastening means 37 of the driven wheel 5'.

In Figure 2, the drive side 1 is shown on the right side and the output side 2 on the left side, each with two cone outer surfaces 15 of the drive wheel 5 and the drive wheel 5 '. The axes of rotation 12 of the drive wheel 5 and the driven wheel 5 'are each in the center of the drive wheel 5 and the driven wheel 5', which rotate in the same direction about the axes 12.

The shaped elements 10 are formed in the embodiment shown in Figure 2 as turnstiles 42, the axis 16 (Figure 3) parallel to a falling lime

Cone outer surface 15 are arranged. The turnstiles 42 with their strip-like shaped elements 10 are uniformly distributed in a star shape over the outer cone surface 5.

The positive form elements 10 are in positive engagement with the negative form elements 10 of the

Power transmission member 3 trained. The division 39 of the elements of the power transmission element 3 is constant, but that of the shaped elements 10 changes as the radius of the flight circles 43 changes. This change in the division takes place by a freewheel 13 of the shaped elements 10 on the driven side opposite to the running direction 18 and on the drive side n running direction 18 of the power transmission element 3. The shaped elements 10 can only rotate against the running direction 18, since otherwise the power transmission element 3 is not driven forward can be.

The diameter of the flight circles 43 changes by changing the distance between the opposing cones 15

Power transmission element 3 on the rail-like shaped elements 10 to the axis 12 of the drive wheel 5 or the driven wheel 5 ', the radius of the flight circle 43 of the power transmission element 3 being reduced. If the distance is reduced, this is done in the opposite way.

So if the adjustment of the drive wheel 5 and the driven wheel 5 'takes place in opposite directions at the same speed, it is not even necessary to provide a tensioning wheel or a spring for maintaining the tension of the power transmission element 3 due to the linear relationship between the radius and the circumference of the flight circles.

The cone spacing is adjusted in a known manner

Way, since various adjustment mechanisms for this arrangement are already known for adjustable gears without positive locking.

FIG. 3 shows a section along section line III-III in FIG. 2. Here, the flight circle 43 of the drive wheel 5 is shown, which in this case is smaller than the flight circle 43, not shown, of the driven wheel 5 '. As a result, a transmission ratio greater than 1 is achieved. In a reverse arrangement, a gear ratio of less than 1 results. The engagement means 11 can be formed, for example, by spherical extensions 17 be embodied in the power transmission element 3. The position of the shaped elements 10 m on the planes of the outer conical surfaces is also clearly shown in FIG. 3.

FIG. 4 shows a schematic top view of a gearbox according to FIG. 1. On the drive wheel 5 around the axles 19 on the drive side in the direction of rotation 61 there are free-running pinions 57 which block in the opposite direction 60, of which only the partial circles are indicated. The locking of the freewheel is selected on the drive side in the same direction as the direction of rotation of the wheels, and vice versa on the output side. The teeth of the pinions 57 act as positive shaped elements 10, those with correspondingly adapted negative shaped elements 10 of a chain acting as a power transmission link 3

Comb 58 or teeth 59 of a gear 46. Shaped elements 10, i.e. the links of the chain or the tooth

59 of the internally toothed gear 46 have, as usual, a fixed division 39. The meshing teeth of the pinions 57 describe a flight circle 43 with the diameters 44 and 45 when the wheels 5 and 5 'rotate. The diameters of these flight circles 44, 45 are adjustable as described above, so that the transmission ratio can be changed thereby.

In Figure 5, an alternative embodiment of the transmission is shown schematically, which dispenses with a power transmission element. The wheel 6 rotates about the axis 50. On the end face 51 it has strip-shaped engagement elements 11 arranged in a star shape. These engage in a form-fitting manner in correspondingly adapted engagement means of a wheel 5, which can be displaced on the circumference against the direction of rotation. The wheel 5 rotates about axis 52.

As shown in FIG. 6, on the outer circumference of the wheel 5, clamping bodies 54 are arranged in a T-shaped groove 53, which carry the positive shaped elements 10 and are displaceable in one direction, but in the clamp opposite direction 60. As a result, the division 40 adjusts itself automatically to the fixed angular division of the strip-shaped negative shaped elements 10. Springs 55 can be provided between the clamping bodies 54, by means of which the clamping bodies 54 abut each other.

FIG. 7 schematically shows the star-shaped arrangement of the strip-shaped shaped elements 38, which serve as engagement means. They have a fixed pitch 39. The transmission ratio can be infinitely adjusted by suitably adjusting the distance 56 between wheel 5 and axis of rotation 50. The division 40 adjusts itself depending on the distance 56.

References list

driving side

output side

Power transmission link

electric motor

Drive wheel, link

'Output gear, link

Driven gear, link

bevel gear

bevel gear

0 form element

1 mother

2 axis of rotation

3 freewheel

4 axis

5 outer cone surface

6 axis of rotation

7 spherical extensions

8 running direction

9 axis

0 bracket

6 contact pin pin

casing

ball-bearing

threaded rods

fastener

fastener

fastener

forming element

fixed division

adjustable division

clamping bodies

turnstile

circle

diameter

diameter

gear

distance

axis of rotation

inner bracket

axis

front

axis groove

Klemmkorper

feather

distance

pinion

Chain

Tooth (pitch circle)

reverse

direction of rotation

Claims

claims

1. Transmission with continuously variable transmission ratio, at least one drive wheel (5) and one driven wheel (5 ') and optionally an endless one

Power transmission element (3) are provided as links in a transmission chain, characterized in that the links (5, 5 ', 6) of the transmission chain have negative and positive shaped elements (10, 38) which are adapted to one another and are designed to be interlocking.

2. Transmission according to claim 1, characterized in that a link (3, 6) of the transmission chain has a fixed division (39) of the formula (38) and the division (40) of the shaped elements (10) of the other member (5 , 5 ') is adjustable.

3. Transmission according to claim 1 or 2, characterized in that the division of the link (5, 5 ') with adjustable shaped elements (10) is designed to adapt automatically to the fixed division (39) of the other link (3, 6).

4. Transmission according to claim 1, 2 or 3, characterized in that the link (5. 5 ') with adjustable division (40) has shaped elements (10) which are designed as a clamping body (41) in a groove (53).

5. Transmission according to claim 1, 2 or 3, characterized in that the link (5, 5 ') with adjustable division (40) of the shaped elements (10) has those which on an axis of rotation (19, 16) with a freewheel ( 13) are arranged.

6. Transmission according to one or more of the preceding claims, characterized in that the member (5, 5 ') with adjustable division (40) as a wheel with an adjustable diameter (44, 45) of the flight circle (43) of the shaped elements

(10) is formed.

7. Transmission according to one or more of the preceding claims, characterized in that the diameter (44, 45) of the flight circle (43) by means of a motor (4) is adjustable

8. Transmission according to one or more of the preceding claims, characterized in that two substantially identical wheels as drive wheel (5) and driven wheel (5 ') are provided with an adjustable division (40) by means of an endless

Power transmission link (3), in particular a chain, with fixed division (39) of the shaped elements (10) are coupled together.

9. Transmission according to one or more of the preceding claims, characterized in that the sum of the diameters (44, 45) of the flight circles (43) is constant during an adjustment.

10. Transmission according to one or more of the preceding, characterized in that the power transmission element (3) as a gear

(46), preferably internally toothed, or as a chain (58).

11. Getπeße according to one or more of the preceding claims, characterized in that the wheel (5, 5 ') with adjustable division (40) has two opposing conical outer surfaces (15) with variable spacing (47), between which the power transmission element (3, 58, 46) is arranged with a fixed pitch, the axis of rotation (16) of the shaped elements (10) being essentially parallel to a falling lime Tapered outer surface (15) is arranged.

12. Transmission according to one or more of the preceding claims, characterized in that the wheel (5, 5 ') is planar, the axis of rotation (19) of the shaped elements (10) parallel to the axis of rotation (48) of the wheel (5, 5th ') arranged