DE1480099C - Hydrodynamic mechanical transmissions, in particular for motor vehicles - Google Patents

Description

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The invention is based on a hydrodynamic channel and one at a distance and in relation to the

mechanical transmission, especially for motor vehicle outer housing, there is a raised container,

testify that from a hydrodynamic device where the channel located in the cover with the

(Flow converter or flow coupling), a container through an at least horizontal or an-

this hydraulically ascending flexible line is connected downstream in the power flow, and into the

actuated clutch and one of the driven channel of the cover over the leakage oil collecting line

The mechanical shaft of the clutch opens into a channel.

Transmission, in which in the fixed outer housing a with As in the transmission according to the invention the dem

Pressurized oil filled, with the driving shaft connected upper container corresponding volume on one

denes, the impeller of the hydrodynamic one is provided in a different place than in the outer housing,

direction forming converter housing is provided, the space requirement of the latter can significantly reduce

whereby from the impeller a ringing in the converter housing.

horizontal turbine wheel is drivable, which with the In the drawings are in the following

also arranged in the converter housing primary description explained in more detail embodiments

part of the clutch is rotatably connected, with the 15 of the hydrodynamic-mechanical transmission after

the shown rotatably arranged on the driven shaft of the invention, namely shows

The secondary part of the clutch can be coupled, for which purpose the F i g. 1 a longitudinal section through a hydrodynamic

Inside of the converter housing in two rooms under-mechanical-transmission,

divides, one of which is formed by a primary part. 2 the top view of a parting line in the direction

The end support plate and a piston and its alternative to the arrows II-II in FIG. 1, the parting line

which is represented by the hydrodynamic device and with its large side horizontally, "

Space outside the clutch in the converter housing. Fig. 3 is a view of the hydrodynamic-mechanical

is formed, the spaces via a distributor, the niche transmission according to the invention in cross section

from one driven by the converter housing, according to the line III-III in F i g. 2,

outside of the same in the fixed outer housing are 25 F i g. 4 is a partial view of the outer housing of the

the oil pump delivered pressure medium optionally to- hydrodynamic-mechanical transmission according to the

is feasible and the invention provided in the outer housing in a diagrammatic representation,

Oil tank to which the pressure oil is fed to a leakage oil line. F i g. 5 is a partial view in cross section according to FIG

is performed, from a lower and an upper line V-V in F i g. 1 with the lid on,

Container consists, which are connected to one another by a line 30 Fig. 6 is a view of the lid from below in the

are connected and the upper container to the direction of the arrows VI-VI in F i g. 5,

filling on a F i g exposed to the atmosphere. Figure 7 is a view of the lid in the direction of

oil level is used. the arrows VII-VII in FIG. 6,

It is already a hydrodynamic-mechanical fig. 8 is a sectional view of another embodiment

Gearboxes for motor vehicles known that have a hydration form,

dynamic device with a downstream F i g. 9 is a view of another embodiment

switchable disconnect clutch and a control device form of the upper container in vertical section,

has device for switching the same. The separation in which a pressure medium level regulator in the upper part

clutch consists of clutch plates, which are provided

are connected to the turbine wheel and through Fig. 10 is a view of the plug of this container

one located between the clutch plates, with a section along the line X-X in FIG. 9,

the driven shaft coupled friction disc. Fig. 11 is a further embodiment of the upper

tensioned or released. The converter housing container.

this transmission is also divided into two chambers. 1 to 7 illustrated embodiment shares, one of which is outside the coupling 45 relates, for example, to an application of the invention clutch plates and the other inside the clutch. on a hydrodynamic-mechanical transmission for plates is located. By a designated oil vehicle. In Fig. 1 is the driving force at 10 divider is designated depending on the operating conditions in the shaft of the hydrodynamic device downstream gear change gearbox the front and with 11 the driven shaft, which is the single side the oil pump with one or the other 50 output shaft of a gear change and / or Chamber connected in the converter housing, whereby reversing gear drives, of which in F i g. 5 at the clutch is disengaged or engaged. 12 the gearshift lever is shown schematically.

A particular disadvantage with the known gear. The hydrodynamic-mechanical transmission has

drive consists in the fact that for the pressure medium a hydrodynamic device 13, the tur-

circuit responsible oil tank difficult to access 55 wheel through a friction clutch 14 with the

is, so that a replacement of the oil or a driving shaft 11 can be connected. The hydrodynamic

Maintenance of the transmission encounters difficulties. mixing device 13 is shown as a flow converter

The invention is based on the object of providing, but can also be used as a fluid coupling

at least the above-mentioned upper container be formed.

ter to be arranged in an easily accessible place, 60 A solid outer housing 15 is between the Gewodurch not only the filling and the pressure medium houses of the internal combustion engine and the gear level control is facilitated, but also a gearbox is arranged. In this external essence easier control is possible. housing 15 is a rotatable converter housing

The object is achieved in that the invention 16, which is filled with oil and the hydrodynamic

according to the lower container from an in the fixed outer 65 device 13 and the friction clutch 14 um-

housing provided cavity and the top there.

Container from one in one the cavity in the with the driving shaft 10 is through a spring outer housing final cover arranged disc 17, the rotatable converter housing 16, which the

Has the shape of a bell, coupled. The converter housing 16 forms the impeller 18 of the hydrodynamic Facility 13 (see Fig. 1). The turbine wheel 19 of the flow converter is provided with a hub 20 firmly connected, which rotates around a fixed sleeve 22 by means of a bearing 21. The latter is with the Outer housing 15 is firmly connected and surrounds driven shaft 11.

The stator 23 of the flow converter is coupled to a ring 24 which rotates in the opposite direction to the direction of rotation of the internal combustion engine through a connection acting in one direction, for example by a freewheel 25, with the sleeve 22 is prevented.

The hub 20 is firmly connected to the middle part of a support plate 26 of the friction clutch 14. The friction clutch 14 serves to couple the turbine wheel 19 to the driven shaft 11 or to be separated from this, depending on whether the gearshift lever 12 is at rest or is actuated and furthermore, depending on the gear change and / or reversing gear is switched or is in neutral is located.

In a cylindrical peripheral part 27 of the support plate 26, which is a drum of large diameter forms, acting as a piston pressure plate 28 is used, which in the direction of the support plate 26 is loaded by a simple plate spring 29.

The pressure plate 28 is with the support plate 26 by several pins 30, for example by three Pins, non-rotatably connected, which are formed on the pressure plate 28 by upsetting and in blind holes 31 of the support plate 26 engage.

At least one small diameter friction disk 32 with friction linings 33 on both of them Pages is arranged between the support and pressure plate 26 and 28 and can be between these be pinched. The friction disk is arranged by means of grooves 34 on a hub 35, which in turn is coupled to the driven shaft 11 via a spline 36, so that the friction disk 32 is rotatably connected to the driven shafts. The hub 35 has essentially the same radius like the sleeve 22 around which the turbine wheel 19 is rotatably mounted.

The friction clutch 14 has around the circumference of the friction disk 32 and between the support and pressure plate 26 and 28 have a circumferential chamber 37 of variable volume containing oil, while they are in the space that is surrounded by the friction linings 33 and between the support and Pressure plate 26 and 28 is located, has an inner chamber 38, which also has a variable volume has and contains oil. The peripheral chamber 37 communicates with the inner chamber 38 through at least one Channel 39 in connection, which is provided for example in the friction disk 32 and in the friction linings 33 is.

The rotating converter housing 16, which is filled with pressurized oil, is divided into two spaces, from one of which is located outside the support and pressure plate 26 and 28 of the friction clutch 14 and the working circuit 40 of the flow converter and a chamber 41 which contains the Support and pressure plate 26 and 28 surrounds and ■ is provided next to the flow converter. the other space lies within the support and pressure plate 26 and 28 and is through the circumferential and Inrienkammer 37 and 38 formed. The two rooms 40, 41 and 37, 38 are only calibrated to each other Openings 42 in communication provided in the hub 20 and with check valves 43 are provided in such a way that an oil circulation from that of the working circuit 40 and the chamber 41 existing space can take place in the space containing the peripheral and inner chambers, however, circulation in the opposite sense is prevented. Each check valve 43 is independent assembled from each other.

The chamber 41 is filled with pressurized oil from a bore 44 of the driven shaft 11 via a row supplied by channels 45 which are provided in the converter housing 16 in a fan-like manner.

The working circuit 40 of the flow converter is filled with oil from the chamber 41 via a Circumferential gap 46, which is provided between the pump wheel 18 and the turbine wheel 19. ..

The oil can from the working circuit 40 through a gap 47 between the turbine wheel 19 and exit the stator 23 and enter the inner chamber 38 via the check valves 43. The inner chamber 38 is in communication with a channel 48, the through the driven shaft 11 and the this surrounding sleeve 22 is formed.

The bore 44 and the channel 48 are through a manifold 49 (Figs. 2 and 5) with a channel 50 and connected to a further channel 51. The distributor is fed with pressurized oil through a channel 52, which is connected to an oil pump 53 (FIG. 1) which sucks in oil from an intake passage 54. In the exemplary embodiment shown, the oil pump 53 is arranged in the vicinity of the pump wheel 18 and is driven by it. The gear of the oil pump 53 is on a white metal bearing 109 arranged. In Fig. 1 is shown with 55 a seal that the space within the outer housing 15 seals, while 55 'denotes a seal assigned to the oil pump 53 and with 56 a channel which, branched off from the sleeve 22 of the stator 23, the various leakage losses of the sealing rings collects in the interior of the outer housing 15 and a discharge for the seal 55 and forms the seal 55 '

The outer housing 15 has been cast in the mold. The various channels 50, 51, 52, 54 and 56 (F i g. 1 to 7) lie in a block 57 which is cast onto the outer housing 15 and an extension forms parallel to the axis of the hydrodynamic-mechanical transmission and above it this axis is located. The channels 50, 51, 52, 54 and 56 are arranged in such a way that the to their shape certain molded parts lifted off at the same time with the corresponding part of the outer housing 15 can be. The mentioned channels have a slightly conical shape, i. H. they rejuvenate and have a cross-section which progressively increases as it extends to a parting line 59, to make it easier to lift off the form. The block 57 is provided with outer cooling fins 58, and the parting line 59 is parallel to the axis of the outer housing 15, with the block 57 at the parting line is closed by a cover 60 (FIGS. 5, 6 and 7). As can be seen, the distributor is 49 firmly connected to the outer housing 15, since the block 57 itself is a part of this outer

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house forms. The knife lying on the parting line 59. The line 74 is such that it does not

Lid 60 serves as a closure for a container 61, the falling part between the lower container 61, 62

62 and the channels 50, 51 and 52 of the manifold 49 and the upper container 75. The transverse

Between the cover 60 and the block is in the cut of the line 74 is sufficient to air out of the

Parting line 59 a seal, for example from 5 lower containers 61, 62 and / or from the channel 56

Paper, provided to rise the inside of the block 57 from to the upper container 75 and remove the oil

to close off the outside and around the channels from the upper container 75 to the lower container 61,

or cavities that can be descended from the parting line into the interior 62, both at the same time,

of block 57 are enough to divide off in a sealing manner. Die _: The upper container 75 is for filling and for

Channels 50, 51 and 52, which is determined by a slider io pressure medium level control and plays the

80 of the manifold 49 are traversed, extend role of an expansion vessel. The upper container

up to the fixed sleeve 22 of the stator 23. As 75 is located outside of the outer housing 15

It can also be seen that the manifold 49 and 49 are in an accessible location for filling and

and the parting line 59 in the vicinity of the axis of the pressure medium level control to facilitate. the

Outer housing 15. 15 Pressure medium level can be visible or on an

The channels 50, 51, 52, 54 and 56 can be read from one another pointing device. The upper container

parallel and preferably perpendicular to the axis of 75, as shown in FIG. 5 shows an overflow pipe 100,

Outer housing 15. Those channels which are expediently extended by a hose 101

are located approximately in a plane, are perpendicular to is, which opens near the bottom. The arrangement

a hub 102 (Fig. 1) of the sleeve 22 of the stator 20 tion of the upper container 75 enables a

.23 arranged. As can be seen from FIG. 1 shows the reduction in space requirements of the hydrodynamic

Channel 56 a part 56 α of smaller cross-section mechanical transmission at the level of the outer

• and a part 56 b of larger cross-section. housing 15.

The part 56 α of smaller cross-section is short, so> As can be seen from FIG. 6 results, the cover 60 has

that the channel 56 does not have any noticeable pressure 25 at its parting line on the block 57 an opening

causes loss. The same goes for the other 76 on, which are to be arranged opposite the

Channels 50, 51, 52 and 54. Channel 56 of the seal 55 is determined. This public

In block 57, a container is provided which has an opening 76 via a channel 77 (FIGS. 5 and 6)

lower chamber 61 and an upper chamber 62 on- with the channel 72 of the cover 60 in connection,

which is connected to each other by a fine filter 63 connected to the upper container 75. Out

are separated. The latter is in its position by this reason, in the arrangement, the flow

a star-shaped part 64 (Fig. 5) held, the air converter contained in the commissioning

is loaded by a spring 66, which would take on the channels 56, 77, 72, 74 to the surface

The underside of the cover 60 is supported. It is also displaced, which is contained in the upper container 75

by the suction effect of the oil pump 53 against an oil held 35 is free and no longer in the circuit

a seat forming shoulder 65 held. The shoulder of the flow converter passed back.

65 is set back with respect to the parting line 59. As shown, the channel 56 does not traverse either

so as not to cause a risk of leakage. As the lower container 61, 62 nor the distributor 49, but

Obviously, the cooling fins 58 extend to the parting line 59 and are connected to the channel 72

connected over the height of the chamber 61 as well as that of the 40 by the channel 77, being in this zone

Chamber 62 of the container. little oil is circulating.

The suction channel 54 of the oil pump 53 is (FIG. 3). The axis of the distributor 49 is horizontal and

at the bottom 67 of the lower chamber 61 of the container to the axis of the hydrodynamic-mechanical device

61, 62 branched off. What the pressure oil promoting drive vertically. The distributor 49 has, as shown in FIG. 5 *

Channel 52 of the oil pump 53 concerns, this is one- 45 shows a slide 80 on which two control collars

on the other hand with a spring-loaded outlet valve 68, 81 'and 82. The control collar 81 is involved

(F i g. 7) and on the other hand with a pressure indicator two holes together, one of which, 83,

69 (Fig. 3). The spring-loaded outlet valve between the compartment 70 and the channel 50 is pilot valve 68 leaves the pressure medium at one pressure which is seen and the other, 84, between the channel is higher than the set value, in a compartment 70 50 50 and the channel 52. The control collar 82 -acts of the block-57 exit via a channel 71, which also has two holes together, one of which Lid 60 (Figs. 6 and 7) is provided. The compartment one, 85, in front of the channels 52 and 51

70 stands with the upper chamber 62 of the container is seen while the other, 86, between the 61, 62 in connection. Channel 51 and the upper chamber 62 is provided.

The upper chamber 62 of the container 61, 62 is with 55 the various bores 83, 84, 85 and 86 a channel 72 of the cover 60 connected, which are through a hole of the same through-hole tubular end piece 73 is extended (Fig. 5). knife of block 57 formed.

The channel 72 plays the role of a calming The slide 80 is connected to an electromagnet 87 chamber. The end piece 73 is connected via a flexible one. For sealing between a room Line 74 is connected to a further container 75, which is connected to the compartment 70, and the one, which is arranged higher than the container 62 on the outside, a sealing ring 105 is used and such an arrangement of the hydrodynamic-mechanical transmission is an accurate machining insofar is independent, as he avoided at any direction of the pads and the Er-spot of the vehicle can be arranged. The aim of a higher adjustment precision of the slide Container 61, 62 is referred to as a "lower container" 65 80 enabled as would be obtained if a net, while container 75 as the "upper" container denotes conventional planar seal between the annals will. The conduit 74 has a strong connection surface in which Cross-section of, for example, 15 to 20 mm through-seal there is a risk that its thickness will be in front

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depends on tightening assembly bolts. related the way: channel 45, bore

The sealing ring 105 is from the assembly 44, channel 50, bore 83, compartment 70, upper chamber

nen independent. 62. The pressure in the inner and peripheral chambers

In the zone in which the block 57 from the outside 37 and 38 is higher than the pressure in the

not through the compartment 70 or the upper chamber 5 chamber 41, so that the friction clutch 14 is

62 is separated, is in the parting line 59 (Fig. 2) is moved.

Channel 106 is provided in order to be able to replace a lead-sealed pin 107 in the outer housing 15

Finding leakage from the channels under pressure in (Fig. 1) attached. The pin extends through the

to direct the upper chamber 62 (Fig. 5). Delimitation of the outer housing and its interior

The slide 80 of the distributor 49 is through the io res in front of the starter ring gear 108 in such a

Electromagnet 87 and by means of a counter spring 88 spaced from these, on the one hand, the operation

controls. The electromagnet 87 is not laterally protruding from the hydrodynamic-mechanical transmission

attached to block 57, while the return spring interferes, but on the other hand, when the starter tooth

88 at the opposite end of the slide ring 108 make contact during disassembly

is seen and acts on the control collar 82. 15 is located with the pin 107, the seal 55 always

To facilitate assembly, the remains effective to maintain the seal.

Counter spring 88 in a groove 110 of the slide 80 th. The pin 107 has the task of stepping out

anchored. the hydrodynamic device 13 from his

The feed circuit of the electromagnet 87 to prevent the outer housing 15. The stylus 107 detects, as shown in FIG. 5 shows two switches in parallel 2 ° enables the delivery of the hydrodynamic-mechanical circuit, one of which, 89, is fully assembled through the niche gearbox and actuated with oil lever 12, while the other, filled and gives an effective Guarantee, since 90 does not respond to the idle position of the gear change - for example the freewheel 25 without certain gear. The switch 89 is closed every time the gearshift lever 12 is touched, left 25 and the fill of oil is also determined and opened every time the gearshift lever requires precautionary measures. The arrangement is released. The switch 90 is in the Idle - also avoids wrong action when exhibition closed, but open when building an aisle.
is switched. A sheet metal bridge 11 ', which the driven shaft

In the in F i g. The position shown in FIG. 5 is the electrical 30 ■ 11 holds, is used to control the hydrodynamic Einrichmagnet87 upset. The control collars 81 and 82 together with the friction clutch with the toothed wheel linden in the bores 83 and 85. The channels to connect change gear. The driven shaft 52 and 50 are connected to one another, and 11 cannot therefore spoil during transport Channel 51 and the upper chamber 62 are lost and do not fall out during installation connected. 35 rather installation, often perpendicular to the driven shaft

When the electromagnet 87 is energized, move downward and longitudinally with respect to FIG

the control collars 81 and 82 in the bores is done in this way. The sheet metal bridge 1Γ also has

84 and 86. The channels 52 and 51 are due to the fact that the seal 55 is in its position

associated with each other while the is held and the seal during the

Channel 50 with compartment 70, i.e. H. with the top 40 transportation and handling maintained

Chamber 62 is brought into connection. can be. The sheet metal bridge 11 'can also be used as

As long as one gear of the gear change transmission securing for fastening screws 22 of the sleeve is engaged, the electromagnet 87 is de-energized. How 22 serve on the outer housing 15,
As described above, the channel 52 of FIG. 8, the oil pump 53 is now in connection with the channel 50. Reference is now made to FIG. 45 in which the arrangement of the compound supplied to the channel 50 through the channel 52 in connection with FIG. 1 through 7, pressurized oil enters the bore 44 (Fig. 1) and, however, while the block 57 consists of two parts 91 feeds the channel 45, the chamber 41, the working and 91 'which are separate from each other through a separation circuit 40, then passes through the openings 42 separated by a joint 92, which passes horizontally in the check valves 43, whereby there is an upper height of the outer housing 15. The lower part 91 contains the various channels chamber 62 of the lower container 61, 62 via the 50, 51, 52, 54 and 56. The upper part 91 'contains the following path back: inner chamber 38, Channel 48, distributor 49 and laterally carries the electromagnet 87, channel 51, bore 86, upper chamber 62. Since that is switched by the switches 89 and 90. Pressure in the chamber 41 because of the mentioned 55 In addition, the part 91 'forms the lower chamber pressure loss higher than the pressure in the circumferential 61 of the container 61, 62, while the upper chamber and inner chamber 37 and 38 is, the friction 62 is formed by a cover 60 α . The clutch 14 is held engaged. kel 60 α is through the flexible line 74 with the

When the gear change transmission is connected in the empty upper container 75.

is running or if the gearshift lever 12 is 60 The in F i g. 9 and 10 shown upper container

is actuated, the electromagnet 87 is energized. The 75 is designed in such a way that the overflow pipe 100 is

Channel 52 of the oil pump 53 is therefore available with the channel can be left.

51 in connection. The pressurized oil in channels 52 on container 75 (Fig. 9) is, for example

and 51 feeds the channel 48 and the inner chamber by welding a sleeve 120 attached to the

38 and then the circumferential chamber 37. The back filling 65 is used. On this sleeve is in one for this one Check valves 43 close. A seal 121 is made of the groove provided for the working circuit purpose

40 and the chamber 41 are arranged with the upper chamber an elastomeric material. The you-

mer 62 of the lower container 61, 62 above the follower 121 is such that its inner diameter

knife at rest is smaller than the diameter of the groove, so that the clamping of the seal is effective even at the bottom of the groove in which there are bores 122 of the sleeve 120, which the seal should close. The groove is formed with two 5 inclined boundaries around the seal 121 to be traced back to the bottom of the groove. A tube 123 is pressed into the sleeve 120, the length of which depends on the desired pressure medium level. A cap 124 (Figs. 9 and 10) is for the interaction with the sleeve 120 and the seal 121 is determined! ■

When filling, the connection cover 124 is removed so that the bores 122 are closed will. The level of the pressure medium reaches the highest point of the lower end of the tube 123, then rises in tube 123, trapping the air in the top of the container.

In the closed position, the edge 124 a of the cap 124 presses against the seal 121 and sets the interior of the container 75 with the outside air through the bores 122, whereby the free expansion of the oil in the power transmission is made possible. The upper edge of the lower end of the tube 123 is at such a height that this expansion does not create the risk of the liquid being spilled. The closure cover 124 is held on the sleeve 120 by a bayonet connection 125, 126. With such a fastening there is no risk of the seal 121 being damaged, and there is security that the seal 121 exposes the bores 122 when the closure cover 124 is in place.

The seal 121 has the action of a spring through which the closure cover 124 is in its position is held.

In the modified arrangement shown in FIG. 11, the upper container is filled at the opening 130. A float 131 carries a valve 132, which for the cooperation with the refill opening is determined, which closes it when the pressure medium level has reached a certain level achieved. Openings 133 are provided for communication with the outside air. For a satisfactory Operation of the arrangement are der.Schwimmer 131 and valve 132 out, for example a cylinder, optionally formed from perforated sheet metal, and a sieve disk 134. A large-meshed one Sieve 135 prevents the operation, for example by inserting a funnel is affected.

In a modification of the exemplary embodiments, the parting line 59 can be inclined in different ways Laying levels.

Claims (12)

55 claims: 1. A hydrodynamic-mechanical transmission, in particular for motor vehicles, consisting of a hydrodynamic means (60 transducers flow or fluid coupling), one connected downstream in the force flux hydraulically betä- <saturated clutch and a driven from the shaft of the clutch driven mechanical transmission, in which In the fixed outer housing there is a converter housing filled with pressurized oil, connected to the driving shaft and forming the pump wheel of the hydrodynamic device, with a turbine wheel located in the converter housing being drivable from the pump wheel, which is rotatably connected to the primary part of the clutch, which is also located in the converter housing , with which the secondary part of the clutch arranged in a rotationally fixed manner on the driven shaft can be coupled, for which purpose the interior of the converter housing is divided into two spaces, one of which is formed by a support plate forming the primary part and a piston and the other by the hydrodynamic device ichtung and the space outside the clutch is formed in the converter housing, whereby the pressure medium conveyed by an oil pump, which is driven by the converter housing and located outside of the same in the fixed outer housing, can be optionally supplied to the spaces via a distributor, and the oil container provided in the outer housing to which the pressure oil of a leakage oil line can be supplied is supplied, consists of a lower and an upper container, which are connected to each other * by a line and the upper container is used to refill an oil level exposed to the atmosphere, characterized in that the lower container consists of a fixed outer housing (15) provided cavity (61, 62) and the upper container from a channel (72) arranged in a cover (60) closing the cavity in the outer housing (15) and a container (72) arranged at a distance and raised with respect to the outer housing (15). 75), the channel in the lid (60) with the container (75) du rch an at least horizontal or rising flexible line (74) is connected, and in the channel (72) of the cover (60) the leak oil collecting line opens via a channel (77). 2. Transmission according to claim 1, characterized in that the upper container (75) has a Has pressure medium level regulator. 3. Transmission according to claims 1 and 2, characterized in that the pressure medium level regulator from a per se known overflow pipe (100) or a per se known, there is a pipe (123) serving for filling, the length of which determines the pressure medium level. 4. Transmission according to claim 1, characterized in that the provided with a slide (80) The distributor (49) forms a parting line (59) with the cover (60). 5. Transmission according to claims 1 and 4, characterized in that the slide (80) between two control collars (81 and 82) have a pressure medium supply from the oil pump (53). 6. Transmission according to claims 1 and 4 or 1 and 5, characterized in that the slide (80) and the parting line (59) are arranged near the axis of the outer housing. 7. Transmission according to claim 1, characterized in that a channel in the parting line (59) (56) is provided for absorbing leakage losses and the channel (56) with the flexible suction channel (54) is connected. 8. Transmission according to claim 1, characterized in that the lower container consists of a lower Chamber (61) and an upper chamber (62) is formed and the lower chamber (61) connected via the flexible suction duct (54) to the oil pump (53) and from the upper one Chamber is separated by a filter (63). 9. Transmission according to claims 1 and 8, characterized in that the upper chamber (62) is connected to the upper container (75) via a channel (72) arranged in the cover (60) is. 10. Transmission according to claim 1, characterized in that the lower and / or upper Chamber of the lower container is provided with cooling fins (18). 11. Transmission according to claims 1 and 8, characterized in that one is on the lid (60) supporting spring (66) is provided to keep the filter (63) in the operative position. 12. Transmission according to claims 1 and 4, characterized in that the slide (80) can be actuated by an electromagnet (87) attached outside the outer housing (15). For this purpose 4 sheets of drawings