CN211059307U - Hydraulic automatic transmission - Google Patents

Abstract

In order to solve the technical problem that the cost of the whole vehicle is increased because a part of the existing seven-gear hydraulic automatic transmissions can only realize 7 forward gears and can realize reverse gear only by an additional structure, the utility model provides a hydraulic automatic transmission, which changes the connection relation of each part in four planetary gear sets by two clutches and four brakes, thereby realizing 7 forward gears and two reverse gears and reducing the production cost of the whole vehicle; and the utility model discloses the output shaft part does not have the nestification between the axle, can effectively guarantee the intensity of output shaft.

Description

Hydraulic automatic transmission

Technical Field

The utility model belongs to the technical field of the car, a hydraulic automatic transmission is related to.

Background

In the existing hydraulic automatic transmission, the power transmission is completed by means of a planetary gear set in the hydraulic automatic transmission. The main structure of the planetary gear set comprises a sun gear, a planet carrier and a gear ring. In the drive line design of the automatic hydraulic transmission, a drive line which changes over a million is formed mainly by changing the connection relationship of the above three components between different planetary gear sets and adding a shift element interposed therebetween.

Some of the currently available seven-speed automatic transmissions, such as the carter CX48, use four planetary gears and six shifting elements to achieve only 7 forward speeds and no reverse. Although reverse gear may be achieved through additional structure, the cost of the entire vehicle may be increased.

SUMMERY OF THE UTILITY MODEL

In order to solve present some seven fender hydraulic automatic transmission and only to realize 7 and go forward the fender, need additional structure just can realize the technical problem that the speed in reverse leads to whole car cost increase, the utility model provides a hydraulic automatic transmission.

The technical scheme of the utility model:

a kind of hydraulic automatic speed changer, including the speed changer shell, clutch assembly, brake assembly, planetary gear assembly and link assembly set up in speed changer shell;

it is characterized in that:

the clutch assembly includes a first clutch and a second clutch;

the brake assembly comprises a first brake to a fourth brake;

the planetary gear assembly comprises a first planetary gear set, a second planetary gear set, a third planetary gear set and a fourth planetary gear set which are arranged on the same axis;

the first planetary gear set comprises a first sun gear, a first planet carrier, a first planet gear and a first gear ring;

the second planetary gear set comprises a second sun gear, a second planet carrier, a second planet gear and a second gear ring;

the third planetary gear set comprises a third sun gear, a third planet carrier, a third planet gear and a third gear ring;

the fourth planetary gear set comprises a fourth sun gear, a fourth planet carrier, a fourth planet gear and a fourth gear ring;

the connector assembly comprises first to seventh connecting elements; the first connecting element is the input of the whole hydraulic automatic transmission, and the seventh connecting element is the output of the whole hydraulic automatic transmission;

the first connecting element is connected with the second sun gear and the third sun gear sequentially through the first clutch and the fourth connecting element;

the first connecting element is connected with the second planet carrier sequentially through the second clutch and the fifth connecting element, and the second planet carrier is connected with the third gear ring and the fourth gear ring simultaneously;

the first connecting element is directly connected with the first sun gear;

the first planet carrier is connected with the transmission shell through a second connecting element and a first brake in sequence;

the first gear ring and the second gear ring are connected with the transmission shell sequentially through a third connecting element and a second brake;

the second planet carrier, the third gear ring and the fourth gear ring are all connected with the transmission shell through a third brake;

the fourth planet carrier is connected with the transmission shell through a sixth connecting element and a fourth brake in sequence;

the third planet carrier and the fourth sun gear are both connected with the seventh connecting element.

Further, the first planetary gear set is a single-row double-stage planetary gear set, and the second planetary gear set, the third planetary gear set and the fourth planetary gear set are single-row single-stage gear sets.

Further, the first planetary gear set has at least three sets of two first planetary gears.

Further, there are at least three second planet gears in the second planetary gear set.

Further, at least three third planetary gears of the third planetary gear set are provided.

Further, the fourth planetary gear set has at least three fourth planetary gears.

The utility model has the advantages that:

1. the utility model realizes the highly efficient gear shifting combination of seven forward gears and two reverse gears through six gear shifting components, and the vehicles can be more oil-saving through a plurality of gears, and can work in a reasonable interval; and, the utility model discloses output shaft portion does not have the nestification between the axle, can effectively guarantee the intensity of output shaft (this is especially important to the output shaft, because the output shaft will bear the moment of torsion that is many times higher than the input shaft, and the diameter of output shaft then can be restricted to the existence of nested structure, influences the intensity of output shaft).

2. The utility model discloses form by simple planetary gear set combination completely for holistic reliability very increases, and the combination through specific number of teeth can make the velocity ratio of its first fender very big, and such transmission route is fit for the commercial car of big tonnage very much.

3. The utility model arranges the clutch at the front end, and can disconnect the clutch when the output of the speed changer is not needed, thereby reducing the power loss caused by the drag resistance in the speed changer; when the clutches C1 and C2 are both disconnected, even if the input shaft has power input, only the first sun gear of the first planetary gear set is driven to rotate, and the friction and abrasion caused by the rotation of excessive rotating elements can be effectively avoided.

4. The utility model discloses an actuating mechanism shifts has six, and the fender that advances of controlling has seven, and the ratio that advances to keep off and shift actuating mechanism is 1.167, and this ratio is higher in hydraulic automatic gearbox's the same kind of ratio. This value reflects the utility model discloses hydraulic automatic transmission's transmission line can utilize the actuating mechanism that shifts now effectively, can realize more fender position through less executor of shifting, also can reduce the axial dimensions of gearbox like this effectively.

Drawings

Fig. 1 is a schematic diagram of a planetary gear train of the automatic hydraulic transmission according to the present invention.

Fig. 2 is a schematic diagram of a specific application example of the planetary gear system of the automatic hydraulic transmission according to the present invention, in which the numbers marked on the gears and the ring gears in each planetary gear set are the numbers of teeth.

FIG. 3 is a table of the operation of the driveline torque transmitting devices in each of the gears shown in FIG. 1 to illustrate which shift assemblies are engaged in each of the identified gears and to provide speed ratios for each of the gears in the particular application example shown in FIG. 2.

FIG. 4 is a lever diagram analysis of the exemplary planetary gear train transmission path of FIG. 2.

In the figure:

1. a first connecting element (i.e., input shaft); 2. a second connecting element; 3. a third connecting element; 4. a fourth connecting element;

5. a fifth connecting element; 6. a sixth connecting element; 7. a seventh connecting element (i.e., output shaft);

C1. a first clutch; C2. a second clutch;

B1. a first brake; B2. a second brake; B3. a third brake; B4. a fourth brake;

pg1. a first planetary gear set; pg2. a second planetary gear set;

pg3. third planetary gear set; pg4. a fourth planetary gear set;

s1, a first sun gear; pc1. a first planet carrier; p1. a first planet; A1. a first ring gear;

s2, a second sun gear; pc2. second planet carrier; p2. a second planet wheel; A2. a second ring gear;

s3, a third sun gear; pc3. third planet carrier; p3. third planet; A3. a third ring gear;

s4, a fourth sun gear; pc4. fourth planet carrier; p4. a fourth planet wheel; A4. and a fourth ring gear.

Detailed Description

In order to better explain the solution of the present invention, the present invention will be described in detail with reference to the accompanying drawings and the detailed description.

As shown in fig. 1 and 2, the automatic hydraulic transmission provided by the present invention has seven forward gears and two reverse gears, and includes a first planetary gear set PG1, a second planetary gear set PG2, a third planetary gear set PG3, a fourth planetary gear set PG4, a first clutch C1, a second clutch C2, and a first brake B1, a second brake B2, a third brake B3, and a fourth brake B4, which are disposed on the same axis.

The first planetary gear set PG1 is a single-row double-stage planetary gear set, and includes a first carrier PC1, a first sun gear S1, and a first ring gear a1, and the first planet gears P1 on the first carrier PC1 may be, but not limited to, three groups, two in each group.

The second planetary gear set PG2 is a single row single stage planetary gear set including the second sun gear S2 and the second planet carrier PC2, and the second ring gear a2, and the number of second planet gears P2 on the second planet carrier PC2 may be, but is not limited to, three groups, one each.

The third planetary gear set PG3 is a single row single stage planetary gear set, and includes a third sun gear S3 and a third planet carrier PC3, and a third ring gear A3, and the number of third planets P3 on the third planet carrier PC3 may be, but is not limited to, three groups, one each.

The fourth planetary gear set PG4 is a single row single stage planetary gear set, and includes a fourth sun gear S4, a fourth planet carrier PC4, and a fourth ring gear a4, and the number of fourth planet gears P4 on the fourth planet carrier PC4 may be, but is not limited to, three groups, one each.

The components of the first to fourth planetary gear sets are connected with the connecting elements and are mutually connected through the connecting elements to form seven rotating elements:

a first rotating element, consisting of a first connecting element 1 (i.e. the input shaft) rigidly connected to the first sun gear S1, both always rotating at the same rotational speed, the first connecting element 1 being configured as a member receiving torque and rotational speed of the hydrodynamic torque converter.

The second rotating element, which is constituted by the second connecting element 2 and the first carrier PC1, is selectively connectable to the transmission case through the first brake B1.

The third rotating element is constituted by connecting the first ring gear a1 and the second ring gear a2, and is selectively connectable to the transmission case through the second brake B2.

And a fourth rotating element which is formed by connecting a fourth connecting element 4, a second sun gear S2 and a third sun gear S3, wherein the fourth connecting element 4 can be selectively connected to the first rotating element.

A fifth rotating element consisting of a fifth connecting element 5 connected with the second planet carrier PC2 and the third ring gear A3 connected with the fourth ring gear a4, the fifth connecting element 5 being selectively connectable to the first rotating element and selectively connectable to the transmission housing through the third brake B3.

The sixth rotating element is constituted by the fourth carrier PC4 and the sixth connecting element 6, and is selectively connectable to the transmission case through the fourth brake B4.

A seventh rotating element is constituted by the third planet carrier PC3, the fourth sun gear S4, and a seventh connecting element 7 (i.e., an output shaft) that is connected, the seventh connecting element 7 being configured as a member that outputs the converted torque and rotational speed to the outside.

The clutch is interposed between selected ones of the seven rotating elements to perform torque and rotational speed transmission.

A first clutch C1 is provided between the first connecting element 1 of the first rotating elements and the fourth connecting element 4 of the fourth rotating elements, and is operated as a selective input element.

A second clutch C2 is provided between the first connecting element 1 of the first rotating elements and the fifth connecting element 5 of the fifth rotating elements, and is operated as a selective input element.

A brake is interposed between a rotating member selected from the seven rotating members and the stationary member to restrict the degree of freedom of the planetary gear set in which it is located so that torque is transmitted along a set path.

The first stopper B1 is interposed between the second linking member 2 and the fixing member, operating as a selective fixing member.

A second brake B2 is interposed between the third connecting element 3 and the fixing, operating as a selective fixing element.

A third brake B3 is interposed between the fifth connecting element 5 and the fixing, operating as an optional fixing element.

A fourth brake B4 is interposed between the sixth connecting element 6 and the fixing, operating as an optional fixing element.

Among the first through seventh connecting elements 1 through 7, there may be a fourth connecting element 4 and a fifth connecting element 5 as selective input members selectively connected to the first connecting element 1 of the input end through a first clutch C1 and a second clutch C2, respectively.

Among the first to seventh connecting elements 1 to 7, there may be selectively fixed to the stationary member by a second connecting element 2, a third connecting element 3, a fifth connecting element 5 and a sixth connecting element 6, respectively, via a first brake B1, a second brake B2, a third brake B3 and a fourth brake B4.

Referring to fig. 3, fig. 3 is an operation chart of each gear and torque transmission device of the present invention for explaining which shift assemblies are closed in each determined gear.

Also, the table of FIG. 3 shows the speed ratios for each gear according to the number of gear teeth shown in FIG. 2, with the black dot table representing an engaged shift assembly and the blank table representing an disengaged shift assembly. The table only shows the numerical values in the case of the example tooth numbers of fig. 2, and each set of numerical values is changed according to the change in the tooth number.

Fig. 4 shows the result of the analysis using the transmission line analysis method, i.e., the lever principle, in which two horizontal lines are respectively shown as: the horizontal line "0" represents a speed of zero, and "1" represents a speed of the input rotation speed and the same rotation speed as the first connecting member 1. The characters on the horizontal line refer to the names in the connection schematic diagram of the components shown in fig. 2, the spacing of the characters is determined by the number of teeth between the components and the matching relationship between the teeth, and the straight line between the components represents the corresponding connecting element fixedly connected with the components, which is a common speed comparison method for those skilled in the art.

The utility model discloses in the clutch be in the corresponding plug-in position of the horizontal line of input for "1", the stopper be in the corresponding plug-in position of fixed horizontal line "0"; the speed transfer line, which will pass through the active brake or clutch, will ultimately take the value at the output shaft, i.e. the seventh connecting element 7, as the ratio of the speed at the output to the speed at the input for the set of torque-transmitting mechanism operating conditions.

The utility model discloses automatic transmission has two torque transmission device to operate simultaneously under each fender position, below the detailed description under each embodiment condition the utility model discloses an each shift speed of planetary gear train and the rotational speed condition of each component.

(1) Go forward first gear

In forward first gear, only the first clutch C1 and the fourth brake B4 are applied.

When the fourth brake B4 is closed, the fourth planet carrier PC4 is connected to the transmission housing, stationary;

the speed "1" of the first connecting element 1 is input to the fourth connecting element 4 via the first clutch C1, and the fourth connecting element 4 drives the third sun gear S3 as the speed "1";

the sixth connecting element 6 is connected to the fixed element by means of a fourth brake B4, the speed of which is 0;

the combined action of the third planetary gear set PG3 and the fourth planetary gear set PG4 results in a reduced speed, which can be transmitted to the seventh connecting element 7 (i.e. the output shaft) via the speed relationship n of the planet carrier, sun gear and ring gear of the planet carrier₁-i₀n₂+(i₀-1)n₃Calculated as 0.

In the formula: n is₁-sun gear rotational speed;

n₂-the ring gear rotational speed;

n₃-planet carrier rotational speed;

i₀-the ratio of the number of teeth of the ring gear to the number of teeth of the sun gear;

the speed "1" of the fourth connecting element and the speed "0" of the sixth connecting element 6 form a forward first gear speed line, and the intersection D1 of the forward first gear speed line with the seventh connecting element 7 is the forward first gear speed ratio.

(2) Two forward gears

In forward second gear, only the first clutch C1 and the third brake B3 are closed.

The speed "1" of the first connecting element 1 is input to the fourth connecting element 4 via the first clutch C1, and the fourth connecting element 4 drives the third sun gear S3 as the speed "1";

the fifth connecting element 5 is connected to the fixed element by a third brake B3, the speed of which is 0;

a reduced speed is imparted to the seventh connecting element 7 (i.e., the output shaft) through the action of the third planetary gear set PG3. Here, the speed "1" of the fourth connecting element 4 and the speed "0" of the fifth connecting element 5 form a forward second speed line, and the intersection D2 of the forward second speed line and the seventh connecting element 7 is a forward second speed ratio.

(3) Three forward gears

In forward first gear, only the first clutch C1 and the second brake B2 are closed.

When the second brake B2 is closed, the first ring gear A1 and the second ring gear A2 are both connected to the transmission shell and are fixed;

the speed "1" of the first connecting element 1 is input to the fourth connecting element 4 through the first clutch C1, and the fourth connecting element 4 drives the second sun gear S2 and the third sun gear S3 as the speed "1";

the third connecting element 3 is connected to the fixed element by means of a second brake B2, the speed of which is 0;

a reduced speed "m" is first formed by the action of the second planetary gear set PG2 and then a speed "n" is formed by the action of the third planetary gear set PG3 to be transmitted to the seventh connecting element 7 (i.e., the output shaft), satisfying the relationship m < n < 1. The speed "1" of the fourth connecting element 4 and the speed "0" of the third connecting element 3 form a forward third gear speed line, and the intersection D3 of the forward third gear speed line with the seventh connecting element 7 is the forward third gear speed ratio.

(4) Forward four-gear

In forward fourth gear, only the first clutch C1 and the first brake B1 are closed.

When the first brake B1 is closed, the first carrier PC1 is connected to the transmission case, stationary;

the speed "1" at which the first connecting element 1 rotates the first sun gear S1 of the first planetary gear set PG1 jointly is input via the first clutch C1 to the fourth connecting element 4, and the fourth connecting element 4 drives the second sun gear S2 and the third sun gear S3 as speed "1";

the second connecting element 2 is connected to the mount by a second brake B1, the speed of which is 0;

first, the speed "1" of the sun gear S1 is reduced to the speed "a" through the reduction of the first planetary gear set PG1 and output to the third connecting element 3, and then a speed "b" is formed by the action of the second planetary gear set PG2 and transmitted to the fifth connecting element 5, the speed "b" satisfying a < b <1, and then a speed "c" satisfying b < c <1 is input to the seventh connecting element 7 through the action of the third planetary gear set PG3. The speed "1" of the fourth connecting element 4 and the speed "a" of the third connecting element 3 form a forward fourth speed line, and the intersection D4 of the forward fourth speed line with the seventh connecting element 7 is the forward fourth speed ratio.

(5) Five forward gears

In the fifth forward gear, only the first clutch C1 and the second clutch C2 are closed.

The speed "1" of the first connecting element 1 is input to the fourth connecting element 4 via the first clutch C1, and the fourth connecting element 4 drives the third sun gear S3 as the speed "1";

the speed "1" of the first connecting element 1 is input via the second clutch C2 to the fifth connecting element 5, and the fifth connecting element 5 drives the third ring gear A3 as the speed "1"; under the action of the third planetary gear set PG3, the third planet carrier PC3 outputs speed "1" to the seventh connecting element, and the speed of the output shaft is also "1".

(6) Six forward gears

In the sixth forward gear, only the second clutch C2 and the first brake B1 are closed.

When the first brake B1 is closed, the first planet carrier PC1 is connected with the transmission shell and is fixed;

the speed "1" at which the first connecting element 1 rotates the first sun gear S1 of the first planetary gear set PG1 jointly is input via the first clutch C2 to the fifth connecting element 5, and the fifth connecting element 5 rotates the second planetary gear set PC2 and the third ring gear A3 as speed "1";

the second connecting element 2 is connected to the fixed element by a first brake B1, the speed of which is 0;

first, the speed "1" of the sun gear S1 is reduced to the speed "a" through the reduction of the first planetary gear set PG1 and output to the third connecting member 3, a speed "d" is formed to be transmitted to the fourth connecting member 4 by the action of the second planetary gear set PG2, the speed "d" satisfies a <1< d, and then a speed "e" is input to the seventh connecting member 7 through the action of the third planetary gear set PG3, the speed "e" satisfies a <1< e < d. Wherein the speed "1" of the fifth connecting element 5 and the speed "a" of the third connecting element 3 form a sixth forward speed line, the intersection D6 of which with the second connecting element 7 is the sixth forward speed ratio.

(7) Seven forward gears

In the seventh forward gear, only the second clutch C2 and the second brake B2 are closed.

When the second brake B2 is closed, the first ring gear A1 and the second ring gear A2 are both connected to the transmission shell and are fixed;

the first connecting element 1 is connected to the fifth connecting element 5 at a speed "1" by actuation of the first clutch C2, and the fifth connecting element 5 drives the second planetary gear set PC2 and the third ring gear A3 as a speed "1";

the third connecting element 3 is connected to the mount by means of a second brake B2, the speed of which is 0;

first, an increased speed "f" is established by the action of the second planetary gear set PG2, which satisfies 1< f, to the fourth connecting element 4, and then a speed "g" is input to the seventh connecting element 7 by the action of the third planetary gear set PG3, which satisfies 1< g < f. The speed "1" of the fifth connecting element 5 and the speed "0" of the third connecting element 3 form a seventh forward gear speed line, and the intersection D7 of the seventh connecting element 7 is the seventh forward gear ratio.

(8) First reverse gear

In the first reverse gear, only the first brake B1 and the fourth brake B4 are closed.

When the fourth brake B4 is closed, the fourth planet carrier PC4 is connected to the transmission housing, stationary;

the second connecting element 2 is connected to the fixed element by a first brake B1, the speed of which is 0;

the sixth connecting element 6 is connected to the fixed element by a fourth brake B4, its speed being 0;

the first connecting element 1 rotates the first sun gear S1 of the first planetary gear set PG1 at speed "1", outputting a reduced speed to the third connecting element 3 by the action of the first planetary gear set PG 1; a reverse rotational speed is output by the combined action of the second planetary gear set PG2, the third planetary gear set PG3, and the fourth planetary gear set PG4. The speed line of the first reverse gear is formed by the speed of the third connecting element 3 and the speed "0" of the sixth connecting element, and the speed ratio of the first reverse gear is determined by the intersection R1 of the third connecting element and the seventh connecting element 7.

(9) Second reverse gear

In the second reverse gear, only the first brake B1 and the third brake B3 are closed.

When the third brake B3 is closed, the fifth connecting piece 5, the second planet carrier PC2, the third ring gear A3 and the fourth ring gear A4 are all connected with the transmission shell and are fixed;

the second connecting element 2 is connected to the fixed element by a first brake B1, the speed of which is 0;

the fifth connecting element 5 is connected to the fixed element by a third brake B3, its speed being 0;

the first connecting element 1 rotates the first sun gear S1 of the first planetary gear set PG1 at speed "1", outputting a reduced speed to the third connecting element 3 by the action of the first planetary gear set PG 1; outputting a reverse speed to the fourth connecting member 4 through the action of the second planetary gear set PG 2; under the action of the third planetary gear set PG3, a speed is output to the seventh connecting element 7. The speed line of the second reverse gear is formed by the speed of the third connecting element 3 and the speed "0" of the fifth connecting element, and the intersection R2 of the speed line with the seventh connecting element 7 is the speed ratio of the second reverse gear.

The speed lines of the gears listed above are shown in fig. 4, and the intersection of the speed line of each gear with the vertical line passing through the name of each member is the speed of rotation of that member in the case of that gear.

It should be noted that fig. 2 is merely exemplary of a particular configuration of the transmission shown in fig. 1, and the numbers below the various elements represent the number of teeth of the elements under the particular conditions, and these particular numbers are not intended to limit the present invention.

Claims (6)

1. A kind of hydraulic automatic speed changer, including the speed changer shell, clutch assembly, brake assembly, planetary gear assembly and link assembly set up in speed changer shell;

the method is characterized in that:

the clutch assembly includes a first clutch (C1) and a second clutch (C2);

the brake assembly comprises a first brake (B1) to a fourth brake (B4);

the planetary gear assembly comprises a first planetary gear set (PG1) to a fourth planetary gear set (PG4) which are arranged on the same axis;

the first planetary gear set (PG1) includes a first sun gear (S1), a first carrier (PC1), a first planet gear (P1), and a first ring gear (a 1);

the second planetary gear set (PG2) includes a second sun gear (S2), a second planet carrier (PC2), second planet gears (P2), and a second ring gear (a 2);

the third planetary gear set (PG3) includes a third sun gear (S3), a third carrier (PC3), a third planet gear (P3), and a third ring gear (A3);

the fourth planetary gear set (PG4) includes a fourth sun gear (S4), a fourth carrier (PC4), a fourth star gear (P4), and a fourth ring gear (a 4);

the connector assembly comprises first (1) to seventh (7) connecting elements; the first connecting element (1) is the input of the whole hydraulic automatic transmission, and the seventh connecting element (7) is the output of the whole hydraulic automatic transmission;

the first connecting element (1) is connected to the second sun gear (S2) and the third sun gear (S3) in that order via a first clutch (C1), a fourth connecting element (4);

the first connecting element (1) is connected with the second planet carrier (PC2) sequentially through a second clutch (C2) and a fifth connecting element (5), and the second planet carrier (PC2) is connected with the third ring gear (A3) and the fourth ring gear (A4) at the same time;

a first connection element (1) is directly connected to the first sun gear (S1);

a first planet carrier (PC1) is connected to the transmission housing via a second connecting element (2) and a first brake (B1) in this order;

the first ring gear (A1) and the second ring gear (A2) are connected with the transmission housing through a third connecting element (3) and a second brake (B2) in sequence;

the second planet carrier (PC2), the third ring gear (A3) and the fourth ring gear (A4) are all connected with the transmission housing through a third brake (B3);

a fourth planet carrier (PC4) is connected to the transmission housing via a sixth connecting element (6) and a fourth brake (B4) in this order;

a third planet carrier (PC3), a fourth sun gear (S4) are both connected to the seventh connecting element (7).

2. A hydraulic automatic transmission as recited in claim 1, wherein: the first planetary gear set (PG1) is a single-row double-stage planetary gear set, and the second planetary gear set (PG2), the third planetary gear set (PG3) and the fourth planetary gear set (PG4) are single-row single-stage gear sets.

3. A hydraulic automatic transmission as recited in claim 2, wherein: the first planetary gear set (P1) of the first planetary gear set (PG1) has at least three groups, and each group has two.

4. A hydraulic automatic transmission as recited in claim 3, wherein:

at least three second planet gears (P2) of the second planetary gear set (PG2) are provided.

5. The automatic hydrodynamic transmission of claim 4, wherein:

at least three third planetary gears (P3) of the third planetary gear set (PG 3).

6. The automatic hydrodynamic transmission of claim 5, wherein:

at least three fourth planets (P4) of the fourth planetary gear set (PG 4).

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