DE102013200389A1 - Method of adjusting system pressure in motor vehicle transmission, involves defining determined torque as function of transmission ratios for controlling characteristic curve of system pressure, during gear unit adjustment operation - Google Patents

Abstract

The method involves providing several switching elements (K1-K4,B1) for determining the specific torque applied at the actuation, corresponding to different transmission ratios of the transmission. The determined torque is assigned corresponding to the operating pressure of the switching elements. The determined torque is associated to the actuating pressure of switching elements and is defined as the function of transmission ratios for controlling the characteristic curve of the system pressure, during the gear unit adjustment operation.

Description

The invention relates to a method for adjusting a system pressure in a transmission, with which system pressure at least one switching element is acted upon actuation, wherein each first a torque is determined, which in each case one of a plurality of different transmission ratios of the transmission through the at least one switching element is transmitted, and wherein in the following this torque each associated with a corresponding, to be shown at the at least one switching element actuation pressure. Furthermore, the invention relates to a motor vehicle transmission, in which an aforementioned method can be realized.

In the field of motor vehicle transmissions are used in automated transmissions and automatic transmissions mainly hydraulically operated switching elements used, which transferred when pressurized in a closed state and make a speed equalization between two transmission components as a result. In this case, the one or more switching elements of a transmission are usually associated with a control hydraulics, which ensures a corresponding supply of hydraulic fluid. In most cases, a system pressure of such a control hydraulic is maintained at a constant pressure level, which always ensures a sufficient for the respective torque transmission of the respective switching element at each gear ratio of the transmission. A system pressure of the control hydraulic system is thus adjusted to a constant, high pressure level independently of a pressure which is actually to be respectively applied to the respective switching element. Since in some operating ranges of the transmission, such a high system pressure does not correspond to the actual demand, systems are sometimes used in which adjusting a system pressure is based on a current state of the respective switching element.

From the DE 43 24 810 A1 is a method for adjusting a system pressure forth, with which a switching element in the form of a clutch of a continuously variable transmission is acted upon by the actuation thereof. In this case, the clutch is concretely an overload clutch, via which the continuously variable transmission is secured against torque surges. In order to adjust the system pressure and thus the actuating pressure of the clutch optimally to an actual state of the clutch, a first pressure level, which results from a characteristic curve, is initially set within the scope of the method. With the aid of this characteristic, a respective pressure value is assigned to a torque to be transmitted via the clutch, wherein the torque to be transmitted was calculated from a respective moment of a prime mover, a gain of a converter of the transmission, and a current transmission ratio of the transmission. Starting from the first pressure level, the pressure is subsequently reduced linearly to a lower pressure level until a predetermined speed difference occurs at the clutch and it slips. Then the system pressure is increased again linearly, wherein from reaching a completely slip-free operation of the clutch, the pressure is further increased by a predetermined safety margin. The finally reached pressure level is then used in the following to equalize a characteristic of the system pressure, so that an adaptation to temperature and wear-related state changes of the coupling is possible.

Based on the above-described prior art, it is now the object of the present invention to provide a method for adjusting a system pressure, by which with low effort, an efficiency of a transmission can be improved.

This object is achieved on the basis of the preamble of claim 1 in conjunction with its characterizing features. The following dependent claims give each advantageous embodiments of the invention. A motor vehicle transmission, in which a method according to the invention can be realized, is evident from the claims 7 to 9.

According to the invention, in a method for adjusting a system pressure, which is acted upon in a transmission at least one switching element when actuated, initially each determines a torque which to transmit in each case one of a plurality of different transmission ratios of the transmission through the at least one switching element is. In the following, a respective corresponding actuating pressure to be represented on the at least one switching element is then assigned to this determined torque. The at least one shift element of the transmission may be either one clutch or one brake each, depending on whether two rotatable transmission components are coupled to each other upon actuation of the switching element or a rotatable transmission component is fixed to a housing. Particularly preferably, it is at least one non-positive switching element, for example in the form of a multi-plate clutch or brake. In principle, however, another embodiment of the switching element in the context of the invention is conceivable, which then by appropriate pressurization with the System pressure is converted into a closed state.

The transmission in which the method according to the invention is used is preferably a motor vehicle transmission and, in particular, a transmission of an agricultural or municipal commercial vehicle, such as an agricultural tractor. In this case, a plurality of different transmission ratios corresponding to a control of the at least one switching element can be displayed between a drive side and an output side of this transmission. For this purpose, the at least one switching element is acted upon by a system pressure set according to the method according to the invention.

The invention now encompasses the technical teaching that the torques to be respectively transmitted for the shifting of the different transmission ratios of the transmission, as well as the actuating pressures of the at least one shifting element associated with these torques, are each mathematically determined prior to operation of the transmission. Furthermore, at least one characteristic curve of the system pressure is then generated from these determined actuating pressures as a function of the gear ratios, according to which the setting of the system pressure is controlled during operation of the transmission. In other words, a fixed characteristic curve of the system pressure is thus generated prior to commissioning of the transmission, in which case the respective transmission torques to be transmitted via the at least one switching element are calculated for all of the representable gear ratios of the transmission and the actuating pressures necessary for their transmission are determined that the respectively required for a reliable closing of the switching element at least required system pressure over the different ratios in the characteristic curve can be specified. In an operation of the transmission, the system pressure is then adjusted according to this at least one characteristic, whereby the at least one switching element is driven at the respective gear ratio with a pressure at least in the amount of the required operating pressure.

Such a method has the advantage that an adjustment of the system pressure adapted to a load is possible, without having to resort to an elaborate control. Thus, in operating ranges of the transmission in which a high transferability to the respective switching element is required, a high system pressure can be set, while in other operating areas with lower load a lower pressure level is selected while still sufficient transferability. As a result, compared to systems in which one works with a consistent, always designed for a maximum transferability system pressure, in the corresponding operating areas by the pressure reduction, a corresponding gain in performance, which in the end in an improvement in the efficiency of the transmission and application in the field a motor vehicle also reflected in a lower fuel consumption. Since this is done in accordance with a curve created before operation of the transmission, can be dispensed with an otherwise complex control system.

In the process of DE 43 24 810 A1 Although it is also possible to achieve an improvement in the efficiency of the respective transmission, since here too the system pressure is adapted to a torque to be transmitted to the clutch at the respective transmission ratio. A control system of the transmission but is correspondingly expensive to make the control method of DE 43 24 810 A1 to be able to realize. Thus, a respective torque must be calculated during operation and adjusted according to a characteristic an associated pressure level at the clutch. Below is then approximated by appropriate pressure reduction and a subsequent increase in pressure to a suitable pressure level and adjusted a curve for future operation in this area accordingly. Overall, the procedure is the DE 43 24 810 A1 correspondingly expensive.

For the purposes of the invention, the torque to be transmitted to the at least one switching element is calculated for each possible gear ratio of the transmission and subsequently, on the basis of the knowledge of the dimensioning of the respective switching element, closed on the required for transmitting this torque actuating pressure. From the respective actuation pressure and the transmission ratio, which is associated with this actuation pressure, the characteristic curve of the system pressure is then subsequently generated via the different transmission ratios of the transmission. In this case, it is also conceivable to generate a plurality of characteristic curves in the manner of a characteristic diagram if, in addition to the dependence on a transmission ratio of the transmission, a dependency of the system pressure on another parameter also makes sense.

By "in advance of operation of the transmission" is meant that generating the at least one characteristic of the system pressure is performed prior to commissioning of the transmission, so in particular when the manufacturer programming the transmission control before the first start. These fall within the meaning of the invention but also adjustments to an existing characteristic curve or the storage of a new characteristic, which can be carried out in the context of maintenance or repairs of the transmission.

According to one embodiment of the invention, in each case a safety surcharge is included in the respective determination of the actuation pressures. Since the generation of the at least one characteristic of the system pressure is carried out prior to operation of the transmission and accordingly can not be responded to deviating from normal conditions, it can be ensured by including a safety impact that always at the at least one switching element sufficient transmissibility of torque given is. This safety surcharge can be present as a fixed offset, which is only offset to the calculated value. However, it is also conceivable to make the safety impact of one or more parameters dependent, if, for example, in certain ratios of the transmission and thus defined speed ranges with highly divergent driving resistances during operation of the motor vehicle is to be expected.

In a further development of the invention, a characteristic curve for controlling the pressurization of a plurality of switching elements is used, wherein for the design of this characteristic for each gear ratio in each case the highest of the respective actuation pressures is calculated, with which the involved in the circuit of the respective gear ratio switching elements are to be acted upon. In other words, therefore, with multiple switching elements of a transmission is not made for each of these switching elements an individual pressure supply with a system pressure tuned thereto, but the multiple switching elements of this transmission are powered by the same hydraulic system, so that with simultaneous control of multiple switching elements, these switching elements all the same system pressure is applied. For this embodiment, then a characteristic of the system pressure is selected so that at each ratio of the system pressure is at least the highest operating pressure of the involved in the representation of this ratio shift elements. Such an embodiment of the invention allows multiple switching elements can be easily operated via a common control hydraulics.

According to a further advantageous embodiment of the invention, the adjustment of the system pressure is made during operation of the transmission via a proportional valve. For this purpose, in a motor vehicle transmission, the at least one switching element is connected to a control hydraulic system which has such a proportional valve. Advantageously, this allows a precise control of the system pressure can be made.

According to one embodiment of the invention, in which the two aforementioned variants of the method are combined with each other, a common adjustment of the system pressure for the plurality of switching elements is made via the proportional valve. In this case, not each switching element is assigned its own proportional valve, but a common proportional valve assumes an adjustment of the system pressure in accordance with the characteristic curve created jointly for all switching elements.

It is a further embodiment of the invention that a maximum torque is included in the determination of each torque to be transmitted, this maximum torque is defined depending on the gear ratio either by this maximum possible traction of a motor vehicle having the transmission or by a maximum drive torque of a prime mover , It is therefore considered in determining the at the respective gear ratio to be transmitted to the at least one switching element torque, which torque may be incurred in this area maximum. Depending on the transmission ratio, this maximum torque is determined by the traction of the motor vehicle or by the maximum drive torque of a prime mover upstream of the transmission. For especially in agricultural utility vehicles, such as farm tractors, traction is usually limited at low speeds, as in this driving range only a certain torque can be transmitted via the wheels to the ground. If the maximum torque of a prime mover were always transmitted in this speed range, the wheels would spin.

In the case of the method according to the invention, therefore, it also makes sense to consider a maximum possible traction of the motor vehicle as the maximum torque in a low speed range of the motor vehicle and thus in the corresponding transmission range of the transmission, and only at a maximum when exceeding a speed limit and thus a specific transmission ratio Orient drive torque of the prime mover. For example, a speed limit of 7 km / h can be used as the speed limit.

In a further development of the invention is in the motor vehicle transmission, in which the inventive method is feasible to a continuously variable, power-split automotive transmission. Accordingly, a power flow from the drive side to the output side can be branched via a mechanical branch and a hydrostatic branch. By adjusting a system pressure, via which switching elements of the mechanical branch can be controlled, an efficiency of this motor vehicle transmission can be correspondingly improved.

The invention is not limited to the specified combination of the features of the main claim or the dependent claims. It also results in ways to combine individual features, even if they emerge from the claims, the following description of a preferred embodiment of the invention or directly from the figures. The reference of the claims to the drawings by use of reference numerals is not intended to limit the scope of the claims.

Further, measures improving the invention will be described in more detail below together with the description of a preferred embodiment of the invention, which refers to the drawings shown in the figures. It shows:

1 a schematic representation of a motor vehicle transmission, in which a method according to the invention is used;

2 a diagram showing a characteristic obtained by the method according to the invention; and

3 a flowchart for explaining the method according to the invention.

In 1 is a motor vehicle transmission 1 represented, which is in particular the transmission of an agricultural or municipal utility vehicle, such as a tractor. In the present case, this motor vehicle transmission 1 designed in the manner of a continuously variable, power-split transmission by the motor vehicle transmission 1 over a mechanical branch 2 and a hydrostatic branch arranged parallel thereto in the direction of power flow 3 features. The mechanical branch 2 consists of several planetary stages 4 to 7 together, which can be linked differently by actuation of associated load switching elements K1 to K4 and B1 in the form of multi-plate clutches or a multi-disc brake and depending on the operation of the load switching elements K1 to K4 and B1 different range translations of the mechanical branch 2 define.

Overall, through the mechanical branch 2 four different range translations are shown, each of these range translations with hydrostatic branch translations 3 can be superimposed, so that a total of a continuously variable ratio of a lowest transmission ratio of the motor vehicle transmission 1 towards a highest transmission ratio can be displayed. In principle, this takes place in a manner known to the person skilled in the art, so that it will not be discussed further in the following.

A control of the switching elements K1 to K4 and B1 is via a higher-level transmission control 8th made by this transmission control 8th a pressurization of the corresponding switching element K1 or K2 or K3 or K4 or B1 with hydraulic fluid of a control hydraulics 9 initiates. This is where this control hydraulics 9 over a hydrostatic branch 3 drive upstream 10 supplied with the corresponding pressurized hydraulic fluid. A special feature here, however, is a system pressure p _{SYS of} the control hydraulics 9 not maintained at a constant pressure level, but the system pressure p _SYS is corresponding to one in the transmission control 8th stored characteristic p _SYS (i) using one of the pump 10 downstream proportional valve 11 as a function of a respective transmission ratio i of the motor vehicle transmission 1 set. When in the transmission control 8th stored characteristic curve p _SYS (i) is, as with reference to the exemplary diagram in 2 can be seen, the system pressure p _SYS on the transmission ratio i of the motor vehicle transmission 1 applied.

The characteristic p _SYS (i) was prior to an operation of the motor vehicle transmission 1 generated by first, as with the help of the flowchart in 3 it can be seen, in a step S1, the different transmission ratios i of the motor vehicle transmission 1 determined and in a subsequent step S2, the respective at the switching elements K1 to K4 and B1 at the individual transmission ratios to be transmitted torque M _x (i) were calculated. In calculating the torque M _x (i) to be transmitted in each case a drive-side maximum torque M _{max was} included, which in a first range of the gear ratios i by a maximum traction of the commercial vehicle and in a second range of the gear ratios i by a maximum torque of the commercial vehicle transmission 1 upstream drive machine is defined.

In a subsequent step S3 became from the respectively to be transmitted moments M _x (i) and actuation pressures p _x (M), with which the respective switching element K1 or K2 or K3 or K4 or B1 to act on the transmission of the respective moment M _x (i) is formed, a characteristic of the respective actuating pressure p _x (i) depending on the transmission ratio i. In addition, a safety surcharge s was included in the form of a fixed offset, and thus the respective actuation pressure p _x (i) was increased by a certain amount compared to the actually determined pressure value.

Finally, in advance of an application of the motor vehicle transmission 1 in a step S4 from the determined for the individual switching elements K1 to K4 and B1 actuation pressures p _x (i) and the gear ratios i of the motor vehicle transmission 1 the characteristic p _SYS (i) for that in the control hydraulics 9 system pressure p _SYS to be set in each case is generated, with the system pressure p _{SYS to} be set in each case being the actuation pressure of the switching element K1 or K2 or K3 or K4 or B1, at which the highest actuation pressure is shown to represent this transmission ratio i p _x (i) is applied. The thus generated characteristic p _SYS (i), as exemplified in 2 is shown below in the transmission control 8th deposited so that the transmission control 8th during operation of the motor vehicle transmission 1 the respective system pressure p _SYS in the control hydraulics 9 with the help of the proportional valve 11 can set according to this characteristic.

Thus, during operation of the motor vehicle transmission 1 What is in the flowchart in 3 is indicated by delimitation of the preceding steps S1 to S4 by means of the dashed line, by the transmission control 8th constantly detected in a step S1 'the respective current transmission ratio i by at corresponding speed sensors of the motor vehicle transmission 1 The respective current speeds of transmission shafts queried and thus the current transmission ratio is calculated. In a step S2 ', this respective current transmission ratio i in the characteristic curve of the system pressure p _SYS (i) is always present in the control hydraulics 9 assigned system pressure p _SYS and then in the following, in a step S3 'by means of the proportional valve 11 set. If the respective switching element K1 or K2 or K3 or K4 or B1 is then activated, the required actuating pressure is available.

As in 2 for the exemplary course of the system pressure p _SYS (i) of the motor vehicle transmission 1 can be seen, a reduction of the system pressure p _SYS is achieved in individual areas, which corresponds to a _gain in performance and also an improvement in the efficiency of the motor vehicle transmission 1 entails, since in the respective operating point by the pump 10 of the motor vehicle transmission 1 a lower system pressure p _{SYS is} build up.

By means of the method according to the invention for adjusting a system pressure can thus at low cost an improvement in the overall efficiency of the motor vehicle transmission 1 be achieved.

LIST OF REFERENCE NUMBERS

1

Motor vehicle transmission

2

Mechanical branch

3

Hydrostatic branch

4

planetary stage

5

planetary stage

6

planetary stage

7

planetary stage

8th

transmission control

9

hydraulic control

10

pump

11

proportional valve

K1-K4

switching elements

B1

switching element

p _SYS

system pressure

p _SYS (i)

Characteristic system pressure

p _x (M)

Actuation pressure as a function of transmittable torque

p _x (i)

Actuation pressure in dependence of gear ratio

M _x (i)

Torque depending on gear ratio

M _max

 maximum torque

i

ratio

s

security surcharge

S1-S4

Single steps procedure before operation gear

S1'-S3 '

 Single steps procedure during operation gear

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 4324810 A1 [0003, 0010, 0010, 0010]

Claims (9)

Method for setting a system pressure (p _SYS ) in a transmission, with which system pressure (p _SYS ) at least one switching element (K1 to K4, B1) is acted upon by the actuation, wherein first each torque (M _x (i)) is determined (S2), which in each case one of several different transmission ratios (i) of the transmission is to be transmitted through the at least one switching element (K1 to K4, B1), and wherein in the following this determined torque (M _x (i)) one each corresponding thereto, on the at least one switching element (K1 to K4, B1) to be displayed actuating pressure (p _x (i)) is assigned (S3), characterized in that for the circuit of the different transmission ratios (i) each to be transmitted torques (M _x (i)), as well as the actuating pressures (p _x (i)) of the at least one switching element (K1 to K4, B1) assigned to these torques (M _x (i)) in advance prior to operation of the transmission r be determined by calculation (S1 to S3), and that at least one characteristic curve (p _SYS (i)) of the system pressure (p _SYS ) is generated from these determined actuation pressures (p _x (i)) as a function of the transmission ratios (i) (S4) according to which the setting of the system pressure (p _SYS ) is controlled during operation of the transmission. A method according to claim 1, characterized in that in each case a safety surcharge (s) is included in the determination of the respective actuation pressures (p _x (i)). A method according to claim 1, characterized in that a characteristic curve (p _SYS (i)) is used to control the pressurization of a plurality of switching elements (K1 to K4, B1), wherein for the design of this characteristic (p _SYS (i)) for each transmission ratio ( i) in each case the highest of the respective actuation pressures (p _x (i)) is taken into account, with which the switching elements (K1 to K4, B1) involved in the switching of the respective transmission ratio (i) are respectively to be acted upon. A method according to claim 1, characterized in that the adjustment of the system pressure (p _SYS ) during operation of the transmission via a proportional valve ( 11 ) is made (S3 '). A method according to claim 3 and 4, characterized in that via the proportional valve ( 11 ) a common setting for the plurality of switching elements (K1 to K4, B1) is made. Method according to Claim 1, characterized in that a maximum torque (M _max ) is included in the determination of the torque (M _x (i)) to be transmitted (S2), this maximum torque (M _max ) being dependent on the transmission ratio (i). is defined either by a maximum possible traction of a motor vehicle having the transmission or by a maximum drive torque of a prime mover. Motor vehicle transmission ( 1 ), in which a plurality of different transmission ratios (i) corresponding to a drive at least one switching element (K1 to K4, B1) can be displayed between a drive side and an output side, wherein the at least one switching element (K1 to K4, B1) for this purpose with a system pressure (p _SYS ) can be acted upon, which is adjusted according to a method according to one of claims 1 to 6. Motor vehicle transmission ( 1 ) according to claim 7, characterized in that the at least one switching element (K1 to K4, B1) with a control hydraulics ( 9 ), which is a proportional valve ( 11 ), wherein via the proportional valve ( 11 ) the system pressure (p _SYS ) is adjustable. Motor vehicle transmission ( 1 ) according to claim 7, characterized in that a power flow from the drive side to the output side branched via a mechanical branch ( 2 ) and a hydrostatic branch ( 3 ) Is feasible and thereby the different transmission ratios (i) are infinitely represented.

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