DE4017869A1 - Friction gear with intersecting axes - incorporates hollow bevel wheel set on driven output shaft - Google Patents

Abstract

The friction gear has rotation bodies wherein the rotation body seated on the output shaft (14) is a hollow bevel wheel (3) and the bevel wheel (1) seated on the drive shaft rolls without an intermediate member on both hollow bevel wheel faces (7,8) of which one is formed on a hollow bevel wheel flange (9) attached rotationally secured on the driven shaft (14) and the other is formed on a hollow bevel wheel flange seated as a loose flange (18) on the driven shaft (14). This hollow bevel wheel flange serves as an input of a reduction gear (26) whose output wheel (28) is attached rotationally secured on the driven shaft (14). The axes of the bevel wheels intersect at right angles.

Description

The invention relates to a friction gear according to the preamble of claim 1.

The transmission according to the invention belongs to that Group of friction gear drives, the peripheral forces transmitted by smooth wheels through rolling friction. The contact surfaces of the engine power over load-bearing bodies of revolution are conical or conical frustum-shaped.

The known friction gear of this type are uniformly translating friction gears. At These gears intersect the axes of the Engine power transmitting bevel gears under one acute angle. This property is for many people uses disadvantageous. It is often required for different reasons Open the angle of the rotational body axes further. In these cases, bevel gears can no longer be used use. Are the rotational body axes lower? right to each other, a cylindrical wheel must have a disc work together. Because the rolling surfaces such wheels or disks even with larger ones Diameters are relatively small and there the rolling surfaces of the smooth micro-sliding wheels movements occur that cause a slip  The consequence is the efficiency of such gears unsatisfactory. Even if bevel gears are used that can be, are the achievable effects just not satisfactory.

The invention is based on the object Friction gear of the type described above create which given benefits better over can wear and a more favorable position of the axes the body of rotation transferred to the motor power allows.

The invention solves this problem with the features of claim 1. Further features of the invention are the subject of the subclaims.

The fact that according to the invention on the output shaft-sitting rotating body as a hollow bevel gear and the one attached to the drive shaft in a rotationally fixed manner Rotational body is designed as a bevel gear, close the axes that transfer the engine power rotating body an enlarged angle a. That is e.g. B. for thermally loaded drives of considerable advantage because the against heat effect easy to protect, e.g. B. with water cooling output shaft in the radiation area of the Heat source can be arranged, but the against Heat-sensitive engine on the side of it may have moved away. Since also according to the invention the bevel gear is on both conical surfaces of the hollow rolling the bevel gear, the rolling slip is reduced considerable, which gives significant benefits at ge given diameters of the rotating body can be and the efficiency of the new Gearbox much better than known ones Friction gear driven. To make this possible, who  the opposite directions of rotation of the two hollow bevel gear flanges with the additional gear takes into account that driven by the loose flange and in turn acts on the output shaft, which is why the loose flange of the hollow bevel gear on the Drive shaft rotates counter to their direction of rotation.

This friction gear can therefore also be high Speed, the z. B. from a high-speed Elek tromotor, such as a three-phase asynchronous motor is produced in an economic way in a rela Actually translate high output speed. That is e.g. B. in degassing plants of molten aluminum especially because such melts with a ver equally degased impeller who the one using the invention Gearbox arranged on the output shaft in a rotationally fixed manner can be and then, for example, at about 500 rpm circulates. Among others in such applications is the property of the new transmission from before part that the intersection of the rotation can enlarge axes, the characteristics of the An Proposition 2 find appropriate application.

Another advantage of the invention is that it is the new construction of the new friction wheel gearbox enables it to be used in a simple manner infinitely adjustable rolling gear train. It can even be turned on and off during operation adjust. That is with the characteristics of the claim ches 3 reached without an intermediate link between drive and driven bevel gear switched on needs to be. The performance of the bevel gear is transmitted over both hollow bevel gear flanges, so that the power flow runs over two friction points. The Contact pressure is generated by spring force, whereby  at the same time slipping through the gearbox and to enable overload protection. The axial adjustability of the motor changes the Drilling position of the bevel gear in the ring gear and change changes the speed. Depending on the direction of rotation of the The bevel gear of the drive shaft becomes the motor and the drive shaft is also deflected, but what over short distances and storage tech nich is irrelevant, but the axially different practice-free storage of the loose flange permitted, without the power flow over this friction surface is prevented.

A particularly simple and effective countershaft leadership is the subject of claim 4. Here the toothed belt drive ensures exact halving tion of the specified speed and enables also because of the arrangement of his gear the hub of the loose flange for a compact overall arrangement.

The details, other features and other advantages parts of the invention result from the following ing description of an embodiment based on the drawings; show it:

Fig. 1 with the omission of all individual not necessary for the understanding of the invention, friction gear units according to the invention in plan view and partly in section, are shown terminated at where the continuation of the output shaft and the motor,

Fig. 2 is a view in the direction of arrow II of FIGS. 1 and

Fig. 3 is a plan view of the parts designated by arrow III of Fig. 1.

According to FIG. 1 of the rotation body is the drive wheel to a bevel gear (1), whose conical surface (2) is arranged in the interior of a driven wheel (3). The drive bevel gear ( 1 ) sits on the drive shaft ( 5 ) led out from a motor ( 4 ) and is supported by a ball bearing ( 6 ) on a motor bracket ( 4 a). The drive bevel gear ( 1 ) rolls without an intermediate member on the two cone surfaces ( 7 , 8 ) of the rotary body ( 3 ), which is designed as a hollow bevel gear. The ( 8 ) designated conical surface sits on a hollow bevel gear flange ( 9 ), which is axially movably supported at ( 10 and 11 ) on a bushing ( 12 ), which is keyed to the output shaft ( 14 ) and is therefore non-rotatably connected to it . The output shaft (14) is a hollow shaft in which a further shaft (15) inserted and thereby rotationally fixed to the drive shaft From (14) is connected. For example, the shaft of an impeller is used to degas an aluminum melt.

The socket ( 12 ) holds with its flange ( 12 a) the plate ( 16 ) of coil springs ( 17 ) which are arranged on a pitch circle around the output shaft ( 14 ) at regular intervals from each other. In general, twelve plates with associated springs are used, which are supported on the back of the rotatable hollow bevel gear flange ( 9 ).

The helical springs ( 17 ) tension the hollow bevel gear flange ( 9 ) in the direction of the other hollow bevel gear flange ( 18 ), on the inside of which the conical surface ( 7 ) is formed. This flange rotates on a needle bearing ( 19 ) as a loose flange around the output shaft ( 14 ). On its hub ( 20 ) a gear ( 22 ) is arranged in a rotationally fixed manner, which drives the input shaft ( 25 ) of a countershaft ( 26 ) via a toothed belt ( 23 ) and a pinion ( 24 ). A spur gear ( 27 ) sits on the input shaft ( 25 ), which meshes with a spur gear ( 28 ) which is arranged on the output shaft ( 14 ) in a rotationally fixed manner.

In the transmission described, the power flow runs over both hollow bevel gear flanges ( 9 and 18 ) into the output shaft ( 14 ). The reduction gear ( 26 ) ensures the necessary reversal of direction, since the hollow bevel gear flanges ( 9 and 18 ) rotate in opposite directions. The countershaft is housed in a small gear housing ( 29 ), which is arranged behind the loose flange ( 18 ), the toothed belt drive ( 30 ) being arranged outside the gear housing ( 29 ).

The motor console ( 4 a) or the gear housing ( 29 ) with a spindle ( 30 ) via a handwheel ( 31 ) axially adjustable to the drive shaft ( 5 ), so that the drilling position of the drive bevel gear ( 1 ) in the hollow bevel gear ( 3 ) changes , ie can be set. This results in a change in speed of the output shaft ( 14 ) as soon as the bracket-fixed running nut ( 32 ) on the external thread ( 33 ) of the spindle-fixed threaded bush ( 34 ) is moved.

According to the exemplary embodiment and FIG. 3, the parts form a geared motor ( 35 ) which is articulated to a stationary support ( 38 ) via a mounting arm ( 36 ) fixed to the housing ( 29 ) and a clamping device ( 37 ).

Claims (6)

1. friction gear with intersecting axes of the motor power transmitted rotary body, which are designed as bevel gears, characterized in that the rotating body sitting on the output shaft ( 14 ) is a hollow bevel gear ( 3 ) and the bevel gear ( 1 ) sitting on the drive shaft wheel surfaces without an intermediate link ( 7 , 8 ), one of which is mounted on a non-rotatable on the output shaft ( 14 ), a hollow bevel gear flange ( 9 ) and the other on a loose flange ( 18 ) on the output shaft ( 14 ) Hollow bevel gear flange is formed, which serves as the input of a countershaft ( 26 ), the driven gear ( 28 ) of which is attached to the driven shaft ( 14 ) in a rotationally fixed manner. 2. friction gear according to claim 1, characterized in that the axes of the bevel gears ( 9 , 18 ) intersect at a right angle. 3. Friction gear according to one of claims 1 or 2, characterized in that the non-rotatable hollow bevel gear flange is biased axially in the direction of the loose flange ( 18 ) of the hollow bevel gear ( 3 ) and the motor and the bevel gear ( 2 ) receiving drive shaft ( 5th ) are axially adjustable together. 4. Friction gear according to claim 1 and one of claims 2 or 3, characterized in that the countershaft with a toothed belt drive ( 30 ) via a hub ( 20 ) of the hollow bevel gear flange ( 18 ) is driven and via an external spur gear ( 27 ) a rotatably on the output shaft ( 14 ) attached spur gear ( 28 ) drives. 5. Friction gear according to claim 1 and one of claims 2 to 4, characterized in that the bevel gear ( 2 ) on the output shaft ( 5 ) of a motor ( 4 ) rotatably and on the motor housing ( 4 a) is mounted. 6. friction gear according to claim 1 and one of claims 2 to 5, characterized in that the toothed spur gears ( 27 , 28 ) of the countershaft ( 26 ) are housed in a gear housing ( 29 ), the hollow bevel gear flange ( 18 ) and the belt drive ( 30 ) are arranged outside the gear housing ( 29 ).