DE102012219215A1 - Spur gear for use in automotive manufacture application, has coupling planet whose tip cylinder diameter is adjusted such that coaxial cladding circle of circulation axles of head circles of planet is smaller than tip circle of ring wheel - Google Patents

Abstract

The spur gear has a set of round planets (P1) and another set of round planets (P2) comprising respective axles (XP1, XP2), which are arranged on respective axle circles, where diameter of one circle is smaller than diameter of another circle. Diameter difference between the circles and tip cylinder diameter of a coupling planet (PK2) are adjusted such that coaxial cladding circle (HC) of circulation axles (X) of head circles of the coupling planet is smaller than tip circle (K1) of a ring wheel (1a) of a ring gear (1).

Description

Field of the invention

The invention relates to a differential gear having a power input and a first and a second power output, wherein the drive power applied to the power input can be branched to the first and the second power output by this differential gear.

Background of the invention

Differential gears are generally designed as epicyclic gearbox and serve mainly the branching of a fed via a power input input power to two waves. Differential gearboxes are most commonly used as so-called distribution, branching or axle differential gears in the automotive industry. Here, the drive power provided by a drive motor is distributed via the differential gear on trailing axles, or the wheel drive shafts of driven wheels. The two leading to the wheels wheel drive shafts are in this case each with the same torque. balanced driven. When driving straight ahead, both wheels rotate at the same speed. When cornering, the speeds of the wheels differ from each other. The axle differential allows this speed difference. The speeds can be set freely, only the average of the two speeds is unchanged. In the past, these differentials were made in wide width as so-called bevel gear differentials. In addition to this design differential gears are also in the form of so-called. Spurraddifferentiale executed. In these spur gear differentials, the output wheels acting as power output are coupled via two intermeshing planetary gears which are typically designed as spur gears. Designs of this differential gear are described in the following references.

Out DE 0 27 423 A1 For example, a spur gear is known, which has a circulation carrier, in which a plurality of spur gear pairs on a pitch circle are added. Each pair of spur gears consists of a first and a second spur gear. Both spur gears are engaged with each other via an engaging portion and are axially offset from one another such that each spur gear forms a projection portion which projects beyond a front end of the respective other spur gear. On the protrusion portions of the first spur gear, a first ring gear is placed and on the protrusion portions of the second spur gear, a second ring gear is mounted. Both ring gears are arranged coaxially to the axis of rotation of the circulation carrier and are located on opposite sides of the same.

Out FR 2 798 178 is also known a spur gear, which has a total of four spur gears, wherein two spur gears each with a first and a second ring gear are engaged. These spur gears are composed so that each of the spur gears meshing with the first ring gear is engaged with both spur gears which mesh with the second ring gear.

Out DE 10 2007 040 479 A1 a bevel gear differential for a motor vehicle is known, which has an integrally formed with a spur gear recirculating carrier. The circulation carrier is designed as a disc body and provided with openings in which the axle bolts of the bevel gears are used such that the axle bolts extend perpendicular to the axis of rotation of the circulation carrier.

Object of the invention

The invention has for its object to provide a differential gear, which is characterized by a robust construction and also is inexpensive to produce.

Inventive solution

• – einem zum Umlauf um eine Umlaufachse vorgesehenen Träger,
• – einem ersten Hohlrad das achsgleich zur Umlauflachse angeordnet ist und eine erste Hohlradinnenverzahnung bildet,
• – einem zweiten Hohlrad das ebenfalls achsgleich zur Umlauflachse angeordnet ist und eine zweite Hohlradinnenverzahnung bildet,
• – einem ersten Satz erster Umlaufplaneten die mit der ersten Hohlradinnenverzahnung des ersten Hohlrades in Eingriff stehen, und
• – einem zweiten Satz zweiter Umlaufplaneten die mit der zweiten Hohlradinnenverzahnung des zweiten Hohlrads in Eingriff stehen,
• – wobei die ersten und zweiten Umlaufplanenten miteinander gegensinnig drehbar getrieblich gekoppelt sind,
• – jene getriebliche Koppelung durch Koppelplaneten erfolgt, die mit den Umlaufplaneten des ersten Satzes in Eingriff stehen und hierbei gleichachsig zu den Umlaufplaneten des zweiten Satzes angeordnet sind,
• – die Umlaufplaneten des ersten Satzes und die Koppelplaneten gleiche Zähnezahlen aufweisen,
• – die Achsen der Umlaufplaneten des ersten Satzes auf einem ersten Achskreis und die Achsen der Umlaufplaneten des zweiten Satzes auf einem zweiten Achskreis angeordnet sind dessen Durchmesser kleiner ist als der Durchmesser des ersten Achskreises, und
• – die Durchmesserdifferenz zwischen dem ersten Achskreis und dem zweiten Achskreis derart abgestimmt ist, dass der zur Umlaufachse koaxiale Hüllkreis der Koppelplaneten kleiner ist als der innere Kopfkreis der ersten Hohlradinnenverzahnung.

The above-mentioned object is achieved according to the invention by a spur gear differential with:

• A support provided for circulation around a revolving axis,
• A first ring gear is arranged coaxially with respect to the revolving axis and forms a first ring gear internal toothing,
• A second ring gear, which is likewise arranged coaxially with respect to the revolving axis and forms a second ring gear internal toothing,
• A first set of first planetary gears meshing with the first ring gear internal teeth of the first ring gear, and
• A second set of second planetary gears which mesh with the second internal gear of the second ring gear,
• - Wherein the first and second planetary planers are rotatably coupled together in opposite directions,
• - that gear coupling takes place by coupling planets, which are in engagement with the orbital planets of the first set and are arranged here coaxially to the orbital planets of the second set,
• The circulating planets of the first set and the coupling planets have the same number of teeth,
• - the axes of the orbital planets of the first set on a first circle and the axes of the planets of the second set on one axis second axis circle are arranged whose diameter is smaller than the diameter of the first axis circle, and
• - The diameter difference between the first axis circle and the second axis circle is tuned such that the coaxial to the circumferential axis enveloping circle of the coupling planet is smaller than the inner tip circle of the first Hohlradinnenverzahnung.

This makes it possible in an advantageous manner, to provide a robust differential gear that is characterized by a relatively short axial length, and also under production and assembly technical point of view is particularly advantageous to produce.

According to a particularly preferred embodiment of the invention, the spur gear differential is formed such that the orbital planets of the first set and the coupling planets have identical tip diameter. In this case, it is possible, in particular, to design the circulation planets of the first set and the coupling planets identically.

According to a further, particular aspect of the present invention, a negative profile displacement is preferably realized on the first Hohlradinnenverzahnung so that it receives an enlarged inner tip diameter and at the same time realized on the second Hohlradinnenverzahnung a positive profile displacement so that it receives a reduced inner tip diameter. In this approach, it is possible to execute the circulation planets of the second set also as identical components to the circulation planets of the first set and the coupling planets.

It is also possible to realize a positive profile shift on the planetary planets of the second set, wherein this profile displacement can be adjusted so that the second Hohlradinnenverzahnung can be performed identical to the first Hohlradinnenverzahnung. A mixture of both variants is possible.

According to a particularly preferred embodiment of the invention is identical design of the first planetary planet and the coupling planet, the diameter difference of the two axes set so that it corresponds to at least twice the tooth height of the teeth of the first Hohlradinnenverzahnung.

The engagement of the coupling planet in the circulation planet of the first set is carried out according to the invention on the axial level of the first Hohlradinnenverzahnung. The axial length of the toothing of the coupling planet preferably corresponds relatively exactly to the axial length of the spur gear toothing of the planetary planets of the first set. The axial length of the first Hohlradinnenverzahnung in turn substantially corresponds to the axial length of the Stirnradverzahnungen the first planetary planets, and the coupling planet.

The differential gear according to the invention is preferably designed so that the first planetary planetary gear set and the second planetary planetary gear set each have two circulating planets. The respective planetary planets are diametrically opposite each other with respect to the axis of rotation of the planet carrier. In this embodiment, a symmetrical force is introduced into the respective ring gears and a possibly low radial load of the bearing structures thereof.

As an alternative to the aforementioned embodiment, it is also possible to design the differential gear according to the invention such that the first planetary planetary gear set and the second planetary planetary gear set each have three planetary planets. This variant offers even higher strength reserves and allows in the same way as the variant with only two diametrically opposed planetary planets symmetrical balance of power. An arrangement of four acting on the respective ring gear planetary orbits is possible.

The differential gear according to the invention is further designed so that the planetary planetary gears of the first planetary planetary gear set and the coupling planet gears are mutually engaged with each other to form a self-contained gear rim. This results in the coupling planetary gears a special kinematic coupling of the planetary planets of the first set with each other. This kinematic coupling is due to the engagement of the planetary orbits of the first set in the first Hohlradinnenverzahnung and the coupling within the closed gear rim itself statically over-determined. The toothing of the first planet, the teeth of the first Hohlradinnenverzahnung and, the coupling planet and the bearing structures of these transmission components are geometrically coordinated so that there is a sufficiently smooth engagement of the gears. Preferably, the numbers of teeth of the ring gears and also the numbers of teeth of the planetary planets are each divisible by the number of planets per set. The difference between the diameters of the first and the second axis circle is primarily tuned so that the coupling planetary freed from the first Hohlradinnenverzahnung.

According to a particular aspect of the present invention, the coupling planet and the circulation planet of the second set are preferably coupled to each other via shaft journals, wherein The radial bearing of the coupling planet and the planetary planets in the carrier is accomplished via these shaft journals. Those shaft journals can be mounted in the carrier via a sliding or rolling bearing.

The coupling planets and the planetary planets of the second set are torsionally coupled together. This torsionally rigid coupling can be achieved by appropriate anchoring of the shaft journal in the orbital planets and the coupling planet. The shaft journal can be integral with a coupling planet or the planetary planets, so that the rotationally fixed anchoring must be realized only in the region of the junction with the other on-or-scheduled planet.

The rotationally fixed coupling of the planetary planets of the second set with the coupling planet is preferably carried out via a spline. In this variant, the shaft journals can be designed so that they have a first splined portion and a second spline portion, and a lying between these two sections bearing portion. The toothing of these spline sections and the complementary geometries provided for this purpose in the corresponding planet gears and designed for torque transmission are preferably designed such that the plug connection takes place under a pronounced press fit with a centering effect.

The differential according to the invention comprises two planetary gear sets which are mounted on a common planet carrier. The output takes place as stated via ring gears. The first planetary gear set, in conjunction with coupling planets, forms a self-contained ring gear, i. Each coupling planet is engaged with two circulating planets of the first set. The orbital planets of the first set and the coupling planets preferably have the same head and pitch circle diameter and the same number of teeth. The ring gears can be designed by profile displacement so that the standing with the planetary planets of the first set ring gear has a large inner tip diameter, while the second ring gear has a small inner tip diameter over a positive profile displacement.

The circulating planets and the coupling planets are preferably executed identically as stated. The pitch circles of the first and second pin bearings have different diameters. The pitch circles of the planetary planets of the first set and the coupling planets have the same diameter. Identical carrier plates are used. The drive wheel acts as a carrier and forms the bearings for the bolts. The prevention of the collision of the first ring gear with the coupling planet is done by reducing the Achskreisdurchmessers and possibly a negative profile shift at the first ring gear. All orbiting planets and coupling planets used can have the same number of teeth, the same module and the same profile displacement values. The ring gears have the same module and the same number of teeth, but different profile shift.

The differential according to the invention comprises in an advantageous embodiment, as stated, a carrier, those two sets of planetary planets, and two ring gears with the same number of teeth and module. The planetary carrier is located axially between the two planetary gear sets. The first set of orbiting planets is engaged with two coupling planets. Two first planetary planets of the first set are in meshing engagement with the first ring gear, which has a large inner circle diameter by a negative profile displacement. The first orbiting planets and the coupling planets are identical. The coupling planets are located on the smaller axle circle and connect the planetary planets of the first set geared with the planetary planets of the second set. They are in meshing engagement with the first planetary planets but not with the first ring gear. Each of the planetary planets of the second set is rotatably connected by the carrier with an associated coupling planet. These can be constructed identical to the first circulation planet. It follows that the second planetary gearset has only two planetary planets, which are in meshing engagement with a second ring gear with positive profile displacement. On the planet carrier of the kinematically the so-called. Bridge sits the drive wheel.

The differential gear according to the invention can be constructed so that the orbital planets of the first set and the planetary planets of the second set are ultimately identical.

The ring gears are formed according to a particularly preferred embodiment of the invention as ring elements. These ring elements can be made in particular as a punching or cutting parts of a plate material. In particular, it is also possible to manufacture these ring elements from a strip material which is bent to that ring geometry and welded at its joints. The width measured in the axial direction of the ring elements is preferably adjusted so that it corresponds to the axial length of the planetary planet attacking it from the inside. These ring elements are connected to hub plate according to a particularly preferred embodiment of the invention, these hub plates are designed as Blechumformteile. The connection of each Ring element with the hub plate can be done by press fit and possibly plastic deformation of corresponding areas of the hub plate. Thus, it is in particular possible to provide on the respective hub plate relief structures which axially penetrate easily from the side into the internal toothing of the ring element and thus support an anti-rotation. The ring element can be fixed to the hub plate by reshaping a peripheral edge region of the hub plate in such a way that it encompasses and thereby secures the ring element.

The carrier itself is, as already mentioned, preferably designed as a disk body and has an integrally formed therewith spur gear. In the spur gear according to the invention, a difference to previously known Hohlraddifferenzialen in particular is that the web formed by the disc body web of the drive wheel is used directly as a carrier and the planets are driven on this, in operative association with the planet pins.

The differential gear according to the invention, in the core of a drive wheel which serves as a carrier, a first ring gear, a second ring gear, planetary pairs consisting of planetary gears and planet pins, and output elements and housing parts, which carry the output elements and connect to the planet carrier.

To achieve the ratio of -1 both ring gears have the same number of teeth. The planetary planets and the coupling planets also have the same number of teeth and are executed as equal parts. The system has only two toothing planes. Since the coupling planet do not abut on the top circle of the first Hohlradinnenverzahnung, no collision of counter-rotating toothed elements can take place.

Brief description of the figures

Further details and features of the invention will become apparent from the following description taken in conjunction with the drawings. It shows:

1 an exploded perspective view of a differential gear according to the invention;

2 a perspective, partially broken view of the differential gear according to the invention of Figure in the assembled state;

3 an axial sectional view of the differential gear to 2 to illustrate the engagement state of the second ring gear with the planetary planets of the second set;

4 a radial sectional view to further illustrate details of the differential according to the 1 to 3 ;

5 an axial sectional view of the differential gear to 2 to illustrate the engagement state of the first ring gear with the planetary orbits of the first set;

6 a radial sectional view of the differential gear after 2 to illustrate the engagement state of the first ring gear with the planetary orbits of the first set;

7 a perspective view of the differential gear to 2 in fully assembled condition.

Detailed description of the figures

The representation after 1 shows the items of the differential gear according to the invention in the form of an exploded view. The spur gear differential according to the invention comprises a carrier provided for circulation about a revolving axis X. 3 , a first ring gear 1 is arranged coaxially with the revolving salmon X and a first Hohlradinnenverzahnung 1a forms. Furthermore, the spur gear differential comprises a second ring gear 2 which is also arranged coaxially to the revolving salmon X and a second Hohlradinnenverzahnung 2a forms.

In the first ring gear 1 engrossed gear inside area is a set of first planetary P1 with the first internal gear teeth 1a of the first ring gear 1 engage. In the second ring gear 2 encompassed gear inside area is a set of second planetary P2 with the second internal gear teeth 2a of the second ring gear 2 engage. The aforementioned first and second planetary planets P1, P2 are as will be deepened below are coupled together so that they rotate in opposite directions.

The two ring gears 1 . 2 are formed such that the Hohlradinnenverzahnung 1a of the first ring gear 1 and the internal gear teeth 2a of the second ring gear 2 have the same number of teeth. The circulation planets P1 of the first set and the circulation planets P2 of the second set also have the same number of teeth.

The circulation planets P1 of the first set and the circulation planets P2 of the second set are identical in construction in this embodiment. The orbital planets P2 of the second set are each via a journal 4 coupled to a coupling gear PK2, and the respective coupling tooth edge PK2 engages in each two planetary gears P1 of the first set. As a result, the coupling gear PK2, on the one hand, couples two adjacent planetary gears P1 and, in addition, couples the second planetary planets P2 in opposite directions to the first planetary planets P1.

The planetary planets P1, P2 are over a portion of their respective journal 4 in the circulation carrier 3 radially mounted. The engagement of that coupling gear PK2 in the corresponding planet P1 of the first set takes place at the axial level of the first Hohlradinnenverzahnung 1a , The ring gears 1 . 2 are designed as ring elements and hub plate 5 . 6 Tailed, these hubbubes 5 . 6 are designed as Blechumformteile.

The carrier 3 itself is designed as a disc body and has an integrally formed therewith spur gear 3a on. This spur gear wreath 3a forms a first and a second inner circumferential wall 3b . 3c , In this Innenumfangswandungen are housing cover 7 . 8th pressed axially. About this housing cover 7 . 8th become the circulation bearer 3 secured axially attached components and combined into a largely closed unit. The housing cover 7 . 8th are designed as Blechumformteile and centric in the Stirnradkranz 3a pressed. The housing cover 7 . 8th form collar sections 7a . 8a which act as a bearing seats over which this differential gear can be rotatably mounted.

The introduction of the drive power in the differential gear via the spur gear toothing 3d of the spur gear wreath 3a , About the planetary planets P1, P2 is a power split to the ring gears 1 . 2 and thus on the hubbub 5 . 6 , At the hubbubs 5 . 6 are covenant sections 5a . 6a educated. These waistband sections 5a . 6a are made by pulling technique and with an internal toothing 5b . 6b Mistake. In this internal toothing 5b . 6b Accordingly, complementary toothed end portions of wheel drive shafts, or other power transfer components of the respective wheel drive train may be inserted. Instead of the internal teeth shown here also other connection geometries for torque transmission and centered recording of corresponding components are possible.

The axes XP1 of the planetary planets P1 of the first set and the axes XP2 of the planetary planets P2 of the second set are arranged differently in terms of diameter, but each coaxial with the axis of rotation X axis circles arranged. The diameter of the second axis circle supporting the axes XP2 is smaller than the diameter of the pitch circle carrying the planetary planetary axes XP1 of the first planetary planetary set. The coaxially arranged to the planetary planets P2 of the second set coupling planet PK2 thus come from the first Hohlradinnenverzahnung 1a of the first ring gear 1 free. The circulation planets P1 of the first set, the coupling planets PK2 and also the circulation planets P2 of the second circulation planet set are of identical construction here.

The difference in diameter between the above-mentioned, the axes XP1, XP2-bearing axle circuits is tuned so that the coaxial to the axis X enveloping circle HC of the top circles of the coupling planet PK2 is smaller than the tip circle K1 of the first Hohlradinnenverzahnung 1a ,

At the first ring gear 1 is a negative profile shift executed so it has a slightly larger tip diameter. At the second ring gear 2 If a positive profile shift is realized, it has a slightly reduced tip diameter. The realized by profile shift difference between the head diameter of the first ring gear 1 and the tip diameter of the second ring gear corresponds to at least twice the tooth height of the teeth of the first ring internal gear teeth 1a , The engagement of the coupling planet PK2 in the circulation planet P1 of the first set takes place at the axial level of the first internal gear internal teeth 1a , The head circle diameter of the orbital planets P1 of the first set corresponds to the tip circle diameter of the orbital planets P2 of the second set. The first planetary planetary set, the second planetary planetary set and the coupling planet PK2 here consist of identical shaped spur gears.

The planetary gears P1 of the first planetary planetary gear set and the coupling planetary gears PK2 are as shown in further detail below representations further alternately engaged with each other to form a self-contained gear rim. The coupling planet PK2 and the planetary planets P2 of the second set are as indicated via shaft journals 4 coupled, with these shaft journals 4 the radial mounting of the coupling planet PK2 and the circulation planet P2 in the carrier 3 is accomplished. The coupling planet PK2 and the circulation planet P2 of the second set are here via a on the shaft journal 4 trained splines coupled torsionally stiff together.

In 2 is in the form of a partially broken perspective view of the structure of in 1 "Disassembled" illustrated differential gear according to figure in now assembled state further illustrated. In this presentation are now the two planetary P1 recognizable in the first ring gear 1 engage radially from the inside. The ring gears 1 . 2 , sitting in the hubbubs 5 . 6 , The ring gears 1 . 2 are rigid to the hubbub 5 . 6 tethered and become as with these hubbands 5 . 6 assembled integral structures. The revolving planets P2 of the second set, which can not be seen in this view, engage radially from the inside into the second ring gear 2 one. The coupling of the second ring gear 2 engaged planetary orbits P2 with those with the first ring gear 1 engaged planetary orbits P1 takes place as already mentioned via the coupling planet PK2. These coupling planet PK2 do not engage in the internal teeth 1a of the first wooden wheel 1 one.

The axes XP1 of the planetary orbits P1 of the first set and the axes XP2 of the orbital planets P2 of the second set are arranged on different sized with respect to their respective diameter Achskreisen.

As already mentioned, the kinematic coupling of the planetary planets P1, P2 is achieved according to the invention by the planetary planets P2 of the second set each have a journal 4 are coupled to a coupling gear PK2, and then engages the respective coupling tooth edge PK2 in a planetary gear P1 of the first set. The planetary planets P1 of the first set also sit on a journal each 4 , The journal bearing the planetary planets P1 4 here is identical to that axle journal 4 executed the circulating planets P2 coupled with the coupling planet PK2. The teeth of the journals remaining free during the bearing of the planetary planets P1 4 is kinematically passive here, it does not mesh with the internal teeth 2a of the second ring gear 2 one.

In 3 are in the form of an axial section of the Hohlradinnenverzahnungen 1a . 2a the ring gears 1 . 2 as well as the planetary orbits P2 and the coupling gears PK2 shown. As already in connection with 1 The axes XP1 of the planetary orbits P1 of the first set are the axes XP2 of the orbital planets P2 of the second set are on different diameter circles CXP1, CXP2 (see 4 ) arranged. The axes XP1, XP2 are aligned parallel to the differential axis X. The ring gears 1 . 2 have the same number of teeth and the same modula. The diameter differences of the axial circles CXP1, CXP2 provided in this embodiment cause the coupling planet PK2 to be released from the first internal gear teeth. The difference in diameter here is at least twice the tooth height of the teeth of the first Hohlradinnenverzahnung 1a , The circulation planets P2 and the coupling planets PK2 are of identical construction.

As can be seen the storage of Umlaufplaneten P2 in the circulation carrier 3 accomplished by the orbital planters P2 over a cylindrical section 4a their respective axle journal 4 in corresponding bearing bores 3e in the circulation carrier 3 be stored radially. The corresponding bearing point is designed here as a sliding bearing. The axle journal 4 sit here under a sufficient motion play directly in a corresponding bore wall of the circulation carrier 3 , The axle journal 4 can also be formed integrally with the respective planetary planetary P2 or a coupling planet PK2. Preferably, however, are the stub axle 4 as shown, manufactured as separate components which have an external toothing 4b have and in a complementary contoured hole in the respective planetary planet P2 can be inserted. The connector structures are preferably dimensioned so that the connector takes place under a slight interference fit. The external toothing 4b that axle journal 4 has a pitch which differs from the pitch of the spur gear toothing of the corresponding planetary planets P1, P2, in particular is finer.

Due to the concept of the kinematic coupling of the planetary planets P1, P2 over the same axis on the journal 4 Seated coupling gears PK2, it is possible that the engagement of that coupling gear PK2 in the corresponding planetary gear P1 (not visible here) of the first set on the axial level of the first Hohlradinnenverzahnung 1a he follows.

In 4 is in the form of a radial section of the transmission structure along in 3 marked sectional plane BB further illustrated. As indicated, the carrier 3 itself formed as a disc body and has an integrally formed therewith spur gear 3a on. This spur gear wreath 3a forms a first and a second inner circumferential wall 3b . 3c , In these Innenumfangswandungen 3b . 3c are the housing cover manufactured as Blechumformteile 7 . 8th ( 1 ) pressed axially. The housing cover 7 . 8th are through the inner peripheral walls 3b . 3c centered. This housing cover 7 . 8th secure the axially attached to the circulation carrier components and hold the differential gear together to form a preassembled unit.

As already in connection with 1 addressed here, but more recognizable are the axes XP1 of the planetary planets P1 of the first set on a first axis circle CXP1 and the axes XP2 of the coupling planet PK2 and also the planetary planetary P2 of the second set on a second axis circle CXP2. The circulation planets P1 of the first set, the coupling planets PK2 and the Circulating planetary P2 of the second set are identical.

At the first Hohlradinnenverzahnung 1a of the first ring gear 1 there is a negative profile shift. At the internal gear teeth 2a of the not visible here second ring gear is implemented as a positive profile shift realized. The realized by profile shift difference between the tip diameter of the first Hohlradinnenverzahnung 1a and the tip diameter of the second ring gear internal teeth 2a corresponds to at least twice the tooth height of the teeth of the first Hohlradinnenverzahnung 1a , The engagement of the coupling planet PK2 in the circulation planet P1 of the first set takes place at the axial level of the first internal gear internal teeth 1a ,

The planetary planetary gears P1 of the first planetary planetary gear set and the coupling planetary gears PK2 are as now recognizable alternately engaged with each other to form a self-contained gear rim. The coupling planet PK2 and the peripheral planets P2 of the second set, which are not visible here, are as indicated via shaft journals 4' coupled, with these shaft journals 4' the radial mounting of the coupling planet PK2 and the circulation planet P2 in the carrier 3 is accomplished. The coupling planet PK2 and the circulation planet P2 of the second set are on the visible here in cross-section, at the shaft journal 4 trained splines coupled torsionally stiff together.

In 5 is in the form of an axial section of the engagement of the first planetary gears P1 in the first ring gear 1 illustrated. The first planetary gear wheels P1 are also here via journals 4 in the carrier 3 stored. The axle journal 4 cause here no torque transmission and are only to reduce the variety of parts identical to those journals 4 formed as coupling the coupling planet PK2 and the second planetary planets P2 (both components not visible here). The ring gears 1 . 2 are in hubbub 5 . 6 edged. The internal gear teeth 1a . 2a and also the matching Stirnradverzahnungen the planetary planets P1, P2 are designed as straight involute. The tip circle diameter of the internal gears 1a . 2a are different here.

In 6 is the engagement of the second planetary planetary P2 in the second ring gear associated therewith 2 illustrated. The radial mounting of the planetary planetary P2 is done via the axis also serving the torque transmission 4' , It is possible in the area of the planetary carrier 3 Form structures, or to set to this cause as such a top circle guide and thus radial support of the planetary orbits P2. This structure can be carried out in particular as an insert which also the journals 4 of the first circulating planet bears or stores. The coupling of the ring gears 1 . 2 with the assigned hub plates 5 . 6 takes place via the here recognizable axial profiling of the outer peripheral portion of the ring gears 1 . 2 ,

In 7 the differential gear according to the invention is shown in the assembled state. The summary of the individual components of the differential gear is essentially done by the two housing cover 7 . 8th in the carrier 3 are pressed axially. The housing cover 7 . 8th are designed as Blechumformteile and centric in the Stirnradkranz 3a pressed. The housing cover 7 . 8th form as configured waistband sections 7a . 8a which act as a bearing seats over which this differential gear can be rotatably mounted.

The introduction of the drive power in the differential gear takes place in the spur gear toothing 3d of the spur gear wreath 3a , About the here not visible, the above described internal mechanics is a power split on the hub plates 5 . 6 trained waistband sections 5a . 6a , These waistband sections 5a . 6a are made by pulling technique and with an internal toothing 5b . 6b Mistake. In this internal toothing 5b . 6b Accordingly, complementary toothed end portions of wheel drive shafts, or other power transfer components of the respective wheel drive train may be inserted. The housing cover 7 . 8th are by staring 7b stiffened.

The underlying this differential gear core concept is based on the arrangement of Umlaufplanetenachsen XP1, XP2 on differently dimensioned diameter circles in relation to a negative or positive profile displacement of the ring gears 1 . 2 , With this concept it becomes possible, the orbital planets including coupling planets, the hubbear 5 . 6 and the housing cover 7 . 8th as each identical components perform. By realization of a profile shift on the ring gears 1 . 2 such that the root circle of the second ring gear 2 is smaller than the tip circle of the first ring gear, it becomes possible, the second planetary planets 2 and the coupling planet PK2 identical. The embodiment described above corresponds to this variant. It is also possible to make a pronounced positive profile shift on the circulation planetary P2 of the second planetary planetary set, so that the two ring gears can be made identical.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 4027423 A1 [0003]
• FR 2798178 [0004]
• DE 102007040479 A1 [0005]

Claims (10)

Spur gear differential, comprising: - a support provided for circulation around a revolving axis ( 3 ), - a first ring gear ( 1 ) is arranged coaxially to the revolving salmon (X) and a first internal gear internal teeth ( 1a ) forms, - a second ring gear ( 2 ) which is also arranged coaxially to the revolving salmon (X) and a second internal gear teeth ( 2a ) forms, - a first set of first planetary planets (P1) with the first Hohlradinnenverzahnung ( 1a ) of the first ring gear ( 1 ), and - a second set of second planetary planets (P2) with the second Hohlradinnenverzahnung ( 2a ) of the second ring gear ( 2 ), wherein - the first and second planetary planets (P1, P2) are rotatably coupled together in opposite directions, - those gear coupling by coupling planet (PK2) takes place with the orbital planets (P1) of the first set are engaged and this coaxial to the circulation planets (P2) of the second set, - the circulation planets (P1) of the first set and the coupling planets (PK2) have the same number of teeth, - the axes (XP1) of the circulation planets (P1) of the first set on a first axis circle ( CXP1) and the axes (XP2) of the second planetary planets (P2) are arranged on a second axis circle (CXP2) whose diameter is smaller than the diameter of the first axis circle (CXP1), and - the diameter difference between the first axis circle (CXP1 ) and the second axis circle (CXP2), and the tip circle diameter of the coupling planet (PK2) is tuned such that the coaxial to the axis (X) enveloping circle (H C) the top circles of the coupling planet (PK2) is smaller than the top circle (K1) of the first internal gear internal teeth ( 1a ). Spurraddifferential according to claim 1, characterized in that the circulating planet (P1) of the first set and the coupling planet (PK2) have identical tip diameter. Spurraddifferential according to claim 2, characterized in that the circulation planet of the first set (P1) and the coupling planet (PK2) are designed identical in terms of their teeth. Spurraddifferential according to at least one of claims 1 to 3, characterized in that on the first Hohlradinnenverzahnung ( 1a ) a negative profile shift is realized, and that at the second Hohlradinnenverzahnung ( 2a ) a positive profile shift is realized. Spurraddifferential according to at least one of claims 1 to 4, characterized in that the engagement of the coupling planet (PK2) in the circulation planet of the first set on the axial level of the first Hohlradinnenverzahnung ( 1a ) he follows. Spurraddifferential according to at least one of claims 1 to 5, characterized in that the tip circle diameter of Umlaufplaneten (P1) of the first set corresponds to the tip circle diameter of Umlaufplaneten (P2) of the second set. Spurraddifferential according to at least one of claims 1 to 6, characterized in that the first planetary gear set and the second planetary planetary gear set each have two circulating planets (P1, P2). Spurraddifferential according to at least one of claims 1 to 6, characterized in that the first planetary gear set and the second planetary planetary gear set each have three circulating planets (P1, P2). A spur gear according to at least one of claims 1 to 8, characterized in that the Umlaufplanetenräder (P1) of the first planetary gear set and the coupling planetary gears (PK2) are mutually engaged to form a self-contained gear rim. Spurraddifferential according to at least one of claims 1 to 9, characterized in that the coupling planet (PK2) and the circulation planet (P2) of the second set with each other via shaft journals ( 4 ) are coupled, and that on these shaft journal ( 4 ) the radial bearing of the coupling planet (PK2) and the rotating planet (P2) in the carrier ( 3 ) is accomplished.

Images