NO168090B - POWER SUPPLY FOR TRACTOR - Google Patents

Description

The present invention relates to a power take-off device

ning for a tractor as appears from the preamble to the subsequent independent claim.

Generally, the previously known tractors are adapted

for work implements, accessories or the like that can be connected to the tractors, with one or more power take-off or PTO axles and through which the necessary power is transferred to the implement or equipment attached to the tractor. The PTO shaft, or shafts, can be connected to the gearbox via a suitable reduction gear so that the PTO shaft can rotate at an appropriate speed, or in an appropriate speed range, which may be independent of the rotation speed of the tractor's drive wheels or dependent on them. One of the conventional PTO axle designs is the type where the tractor is equipped with one PTO axle which can be connected via a reduction gear to rotate at a given rotational speed which is dependent on the engine speed.

It is easy to arrange with such a PTO shaft by means of suitable coupling elements, an operation in which the PTO shaft can be rotated at a speed which is dependent on the rotational speed of the tractor's drive wheels. The PTO shaft is in this case optionally connectable to rotate either at a speed independent of the rotation speed of the drive wheels or at a speed dependent on them. Another conventional PTO arrangement is where the tractor is equipped with two PTO axles which are connectable to rotate at speeds which are independent of the rotation speed of the drive wheels, but different from each other.

One of the PTO shafts can thus be connected to rotate in it

low speed range, and the other in the higher

. speed range. The axle journals of said PTO axles,

from which the power is transferred to the work tools or the like, are then designed to be different,

e.g. in the way that the diameters of the shaft pins are different and/or that the shaft pins are equipped with different sliding wedge grooves. With such arrangements, an obstacle is achieved that a work tool intended to be maneuvered from the low-speed axle pin is connected to the high-speed axle pin.

Another previously known PTO construction is the one where the tractor is equipped with a PTO shaft that can be connected to rotate in two different speed ranges. For each speed range, an axle pin must be connected to the PTO shaft where the axle pin's diameter and/or sliding wedge track arrangement differs from that of the axle pin intended for a different speed range. The PTO shaft is part of a PTO gear transmission arranged with a gear shift mechanism by means of which the PTO shaft can be engaged to rotate either in the low or the high speed range. This shift mechanism is connected to a selector lever which is operated from the driver's cabin in the tractor. Meanwhile, a noticeable disadvantage with such an arrangement is that the tractor driver can, if he wishes, connect the axle pin for the low-speed range to rotate at a speed that is in the high-speed range. If in such a case a work tool has been connected to the axle pin which is only intended to be driven within the low-speed area, there is a possibility that the tool will be damaged due to it being driven at too high a rotational speed.

The purpose of the present invention is to provide a power take-off device for a tractor where the disadvantages associated with the known constructions are avoided, and where a remarkable

considerable improvement is achieved over the previously known constructions.

This is achieved according to the invention with a power take-off device of the type mentioned at the outset which is characterized by the features that appear from the characteristics in the following independent claim.

A further feature of the invention is reproduced in the independent claim.

The significant advantage of the construction according to the invention over previously known constructions is that when the axle pin for the low speed range is attached to the PTO shaft, the PTO shaft cannot be connected to rotate within the high speed range. This avoids possible damage to the implements that are connected to the PTO shaft. Another significant advantage is that one and the same PTO shaft can be connected to rotate either at a speed independent of the rotation speed of the drive wheels or at a speed dependent on them.

In what follows, the invention is described in more detail through an exemplified embodiment of the invention with reference to the figure in the attached drawing.

In the figure, the power take-off shaft is indicated with the reference number 1. The PTO shaft 1 is arranged inside a gearbox, the housing of a reduction gear transmission or the like, in which it is rotatably supported in bearings 30 and 31. On the PTO shaft, in the embodiment shown, three gears 4,5,25 which are freely rotatable, where these gears are arranged to be alternately connected to the PTO shaft 1. Of the gears, the first and second gears 4 and 5 are arranged to operate within speed ranges which are independent of the rotational speed of the tractor drive wheel and are mutually different, while the third gear 25 is arranged to rotate at a speed which is dependent on the rotational speed of the tractor's drive wheel. In the embodiment shown in the figure, the first gear 4 is that for the high-speed range, and the second gear 5 is the gear for the low-speed range.

On the PTO shaft 1, a non-rotatable sleeve 10 is arranged on which an axially movable shift sleeve 12 is arranged. The sleeve 10 is arranged with coupling teeth 11, and the shift sleeve 12 is likewise arranged with shift sleeve coupling teeth 13, where the sets of teeth 11 and 13 allow axial movement of the shift sleeve 12, but prevents the shift sleeve 12 from rotating relative to the sleeve 10. The gears 4,5 and 25 are each provided with coupling teeth so that the shift sleeve 12 is alternately connectable either to cooperate with the coupling teeth 6 of the first gear, with the coupling teeth 17 to the second gear or with the coupling teeth of the third gear.

Two axle studs can be rigidly attached to the PTO shaft 1; the first axle pin 2 for the high-speed range, or the second axle pin 3 for the low-speed range. The first and second axle pins 2 and 3 differ both with respect to their sliding keyway and/or, as shown in the figure, with respect to their diameter. An axial bore 14 is arranged in the PTO shaft 1, where an axially displaceable rod 15 is arranged in this bore, loaded with a spring 16 against the axle pins 2 and 3 respectively. In the first axle pin 2, an axial recess 8 is arranged, where the rod 15 is arranged under the action of the spring 16 to enter this recess when the first axle pin 2 is attached to the PTO shaft 1. In the second axle pin 3 there is no such recess ; when the second shaft pin 3 is attached to the PTO shaft 1, the rod 15 will rest, pressed by the spring 16, against the end surface 9 of the attachment flange of the second shaft pin 3. In the PTO shaft 1, there is arranged at least one radially displaceable, and radially continuous pin 18, which in the illustrated situation extends through the sleeve 10 so that it is in contact at one end with the rod 15 and at the opposite end with the shift sleeve 12. In the shift sleeve 12, an axial groove 22 is designed for the pin 18 which enables the shift sleeve to be axially displaced in the situation depicted in the figure. Furthermore, a radially inwardly directed guide edge 23 is formed in the groove 22.

In the situation depicted in the figure, the PTO shaft 1 is attached to the second axle pin 3 which is intended for the low-speed range. The rod 15 must be pressed by the spring 16 against the end face 9 of the fastening flange. In the situation depicted in the figure, the shift sleeve 12 is further in the disengaged position, in which none of the gears 4,5,25 is connected to the PTO shaft 1. It is possible, in the situation depicted in the figure, to move the shift sleeve 12 from the left against the third gear wheel 25, which rotates at a speed dependent on the rotational speed of the tractor's drive wheel. Thus, the shift sleeve can be moved to be engaged with the coupling teeth 26 on the third gear, whereby the PTO shaft 1 and the second shaft pin 3 attached to it will rotate at a speed dependent on the speed of the drive wheels.

On the other hand, it is possible to move the shift sleeve 12 from the disengaged position according to the figure to the right, towards the first and second gears 4 and 5. As already observed, the first gear 4 is intended for the high-speed area and the second gear 5 for the low speed area. When the shift sleeve 12 is moved to the right from the situation according to the figure, the coupling teeth 13 on the shift sleeve will first engage with the coupling teeth 7 of the second gear 5, causing the PTO shaft 1 and the second axle pin 3 attached to it to rotate at the speed determined by the second gear 5. From Engagement with the coupling teeth 7 to the second gear 5, the shift sleeve 12 can be moved further towards the right 1 figure, towards the first and second gears 4 and 5; thereby the shift sleeve is moved to a disengaged position 1 in which it is not engaged with any of the gears 4,5,25.

It can be observed in the figure that there is an axial opening between the coupling teeth 6 of the first gear and the coupling teeth 7 of the second gear, into which the coupling teeth 13 of the shift sleeve can move in the disengaged position just described. From this disengaged position, the shift sleeve 12 cannot be moved further towards the first and second gears, in order to engage with the coupling teeth 16 of the first gear, because in said disengaged position the radial pin 18 lies against the guide edge 23 of the track 22, whereby this rim prevents any movement of the shift sleeve into engagement with the coupling teeth 16 of the first gear. It should thus be understood that the PTO shaft cannot be connected to rotate within the high-speed range when the second shaft pin 3 is attached to the PTO shaft 1 for the low-speed range.

A recess or a notch 17, or a reduced portion, is arranged on the rod 15, as can be observed in the figure. When the first shaft pin 2 is attached to the PTO shaft 1, this shaft pin being intended for the high-speed area, the rod 15 is pushed by the action of the spring 16 into the axial recess 8 arranged in the first shaft pin 2. When the rod 15 is pushed in 1 mentioned axial recess 8, the notch 17 arranged on the rod has moved into the position in line with the radial pin 18. The shift sleeve 12 can now be moved in order to be connected either with the coupling teeth 7 to the second gear 5 or with the coupling teeth 26 to the third gear 25 , as already observed in the foregoing. It should thus be understood that the PTO shaft 1 can be connected to rotate either at a speed dependent on the rotational speed of the drive wheels or at a low speed independent of these.

In addition, the shift sleeve 12 can be moved axially to

get 1 engagement with the coupling teeth 6 to the first gear. This is made possible by the feature that, after the shift sleeve 12 has first been moved into engagement with the engagement teeth 7 of the second gear 5

and then further to the right into the disengaged position, the shift sleeve can be moved from the disengaged position even further to the right because then the radial pin 18 will move inwards, positively guided by the guide edge 23

in the groove 22, radially inward and into the notch 17 arranged on the rod 15. It is thus to be understood that when the first axle pin 2, intended for the high-speed area, has been attached to the PTO axle 1, the PTO axle 1 and the first axle pin 2 can be attached to which is connected to rotate either at the speed in the high speed range determined by the first gear 4,

or at the low-speed range determined by the second gear 5, or at the speed determined by the third gear 25 and which is dependent on the speed of the drive wheels.

There is also a radial hole that passes through the PTO shaft 1 and the sleeve 10, and in this hole a radial pin 19 and a radial spring 20 are arranged,

where these elements press a ball 21 against an inner surface of the shift sleeve 12. In the shift sleeve 12, depressions are arranged for the ball 21 into which the ball 21 can enter. This construction is in itself of a conventional type, and it is only intended to keep the shift sleeve 12 in the correct position axially when it is in the disconnected position or connected to one of the tooth sets

6,7,26 to the first, second or third gear 4,5 or 25 respectively.

According to the invention, the power take-off device can also be implemented in such a way that the third gear 25 on the PTO shaft 1 is omitted. The PTO shaft can thus be connected to rotate either within the high-speed range determined by the first gear 4 or within the low-speed range determined by the second gear 5, while in an embodiment of this type the PTO shaft 1 cannot be connected to rotate at a speed depending on the rotational speed of the tractor's drive wheels. In this case, the so-called driving power take-off is missing in the PTO device.

The invention is described through an example with reference to the figure in the attached drawing. However, it is not thereby intended to limit the invention to only the presented example according to the figure; the invention can be further modified within the scope of the invention defined in the attached claims.

Claims (3)

1. Power take-off device for tractor, which power take-off device includes a power take-off shaft (1) which is arranged in a gearbox housing, reduction gear housing or similar, at which shaft freely rotating gears (4,5) are arranged which operate at different rpm ranges regardless of the rotational speed of the tractor's drive shaft wheel, of which gear the first gear (4) is a gear that operates within the high speed range and the second gear (5) is a gear that operates within the low speed range, and to which power take-off device two shaft pins (2,3 ) to alternatively be attached to the power take-off shaft (1), of which the first axle pin (2) is intended for the high rpm range and the second axle pin (3) for the low rpm range and to which power take-off device one belongs at the power take-off shaft (1) non-rotatably connected sleeve (10), above which a transfer sleeve (12) which is not rotatable in relation to the sleeve (10) and which can be shifted in the direction of the shaft is arranged, whereby a central axial bore (14) is formed at the power take-off shaft (1) , by which an axially displaceable rod (15) is arranged, which is loaded by a spring (16) against the shaft pin (2 or 3) which is fixed to the power take-off shaft (1) and whereby the rod (15), under the t that the second shaft pin (3) is fixed to the power take-off shaft (1), has moved against the spring force (16) in such a way that the transfer sleeve (12) can be connected at least to the second gear (5), but is prevented from connecting to the first gear (4) and as the first shaft pin (2) is fixed to the power take-off shaft (1), the transmission sleeve (12) can optionally be connected to at least the first or second gear (4 or 5), characterized in that at the power take-off shaft (1), a third gear (25) is also arranged which is arranged to rotate freely in relation to the power take-off shaft, and arranged to function with a rotational speed which is dependent on the rotational speed of the tractor's driving wheels. 2. Power take-off device according to claim 1, characterized in that the transmission sleeve (12) can optionally be connected to the aforementioned third gear (25) regardless of which shaft pin (2 or 3) is fixed to the power take-off shaft (1). 3. Power take-off device according to claim 1 or 2, characterized in that the third gear (25) is arranged to the power take-off shaft (1) in the axial direction in relation to the first and second gears (4,5) on opposite sides of the transmission sleeve (12).