DE102015004454A1 - Plate spring, in particular for a drive train of a motor vehicle, and drive train and method for mounting such a plate spring - Google Patents

Abstract

The invention relates to a plate spring (10), in particular for a drive train of a motor vehicle, with an annular base body (12) and radially extending from the base body (12) to a respective free end (16) plate spring tongues (14) for transmitting an axial force at least one component (36), wherein the plate spring (10) of the plate spring tongues (14) different, radially from the base body (12) to a respective other free end (20) extending and in a corresponding recess (24) of a Component (22) can be arranged centering tongues (18) for centering the plate spring (10) relative to the component (22).

Description

The invention relates to a plate spring, in particular for a drive train of a motor vehicle, according to the preamble of patent claim 1, a drive train with such a plate spring and a method for mounting such a plate spring.

Such a plate spring, for example, is already the US 2013/0213168 A1 to be known as known. The diaphragm spring has an annular base body as well as radially extending from the main body to a respective free end plate spring tongues for transmitting axial forces on at least one component. This means that, for example, via the diaphragm spring axial forces can be transmitted from a further component to the at least one component, wherein the diaphragm spring tongues are elastically deformable relative to the base body. If, for example, the at least one component in the axial direction of the plate spring is moved relative thereto in such a way that the plate spring tongues are deformed elastically relative to the base body, then a spring force in the form of an axial force acts on the plate spring on the at least one component, the axial force acting by means of the plate spring tongues is effected.

Object of the present invention is to develop a diaphragm spring of the type mentioned in such a way that a particularly high functional performance of the plate spring can be realized.

This object is achieved by a plate spring having the features of patent claim 1. Advantageous embodiments with expedient developments of the invention are specified in the remaining claims.

In order to develop a diaphragm spring specified in the preamble of claim 1 type such that a particularly high functional performance of the plate spring can be realized, it is inventively provided that the plate spring different from the plate spring tongues, radially from the body to a respective other free end extending and in a corresponding recess of a component, in particular a shaft, can be arranged centering tongues for centering the plate spring relative to the component or to the shaft. For example, the centering tongues extend radially inward from the base body, so that the plate spring can be centered on the component or the shaft by means of the centering tongues. The diaphragm spring thus not only comes to a power transmission function, in the context of which axial forces between the at least one component and, for example, at least one further component, in particular the component, are transmitted via the diaphragm spring, but the diaphragm spring also has a centering and holding function, in whose frame the plate spring on their centering tongues, in particular, held on the component and relative to the component, in particular on the component centered.

Since the centering tongues are part of the plate spring, the plate spring centered relative to the component or on the component itself and is also mounted in a particularly simple manner by the plate spring is inserted, for example in its axial direction on or in the component. As part of the dual function of the plate spring, the plate spring tongues take over the transmission of axial forces, the centering tongues take over the centering and mounting of the plate spring on or on the component. For example, if no axial force acts, the centering acts via the centering tongues. Acts an axial force, for example, by the plate spring tongues are elastically deformed relative to the body or are, so the centering is done via the axial force.

By the described double function of the plate spring, this can be kept and centered without having to use additional weight and space-demanding elements. A cause by the Zentrierzungen holding force is sufficient to hold the dead weight of the plate spring, without requiring additional parts are required.

Preferably, the plate spring is integrally formed. This means that the plate spring tongues, the centering tongues and the base body are formed integrally with each other. As a result, the plate spring is produced in a particularly simple and cost-effective manner. Furthermore, the plate spring can be mounted in short cycle times, so that the disc spring is inexpensive to install. In particular, it is possible to mount the plate spring using a mounting tool. In addition, a particularly time and cost feasible automated assembly of the plate spring can be realized. In addition, the risk of incorrect assembly can be kept very low. Furthermore, the centering tongues allow the realization of a reversibly detachable, that is, non-destructive releasable connection between the diaphragm spring and the component, so that the diaphragm spring, for example, mounted on the component and can be dismantled from the component without destroying the diaphragm spring or the component.

In a particularly advantageous embodiment of the invention, the plate spring tongues circumferentially each have a first shape and the centering tongues each circumferentially one of the first shape different, second form. In other words, the plate spring tongues and the centering tongues differ in their peripheral, for example, outer peripheral side, shape or geometry. This makes it possible, at least substantially optimally adapt the diaphragm spring tongues and the centering tongues to their respective task, namely the transmission of axial forces or the centering and holding the plate spring, so that the plate spring can perform the respective function particularly well.

As further particularly advantageous, it has been shown that the plate spring tongues are arranged in a first plane and the centering tongues in a different from the first plane, the second plane. In other words, it is preferably provided that the plate spring tongues, which are also referred to as function tongues, and the centering tongues lie in two different planes. As a result, the diaphragm spring tongues and the centering tongues can fulfill their respective function particularly well, without adversely affecting each other.

In a particularly advantageous embodiment of the invention, the centering tongues are elastically deformable relative to the main body. As a result, the diaphragm spring can be latched over the centering tongues, for example with the recess of the shaft, so that the disc spring can be held by the centering tongues particularly firmly on the shaft.

Preferably, it is provided that the plate spring tongues are elastically deformable relative to the main body. By elastically deforming the plate spring tongues in the axial direction relative to the base body, a spring force acting in the axial direction of the plate spring, that is to say an axial force, is produced which acts, for example, on the at least one component or between the component and the component.

The invention also includes a drive train for a motor vehicle, in particular a passenger car. The drive train comprises at least one component and at least one plate spring according to the invention, by means of which axial forces can be transmitted to the at least one component. For example, the axial forces between the at least one component and the example designed as a shaft component via the diaphragm spring can be transferred. In this case, the centering tongues are at least partially accommodated by centering the disc spring relative to the component, in particular on the component, in the recess of the component. Advantageous embodiments of the disc spring according to the invention are to be regarded as advantageous embodiments of the drive train according to the invention and vice versa.

In order to keep the cost of the drive train particularly low, it is preferably provided that the recess of the example designed as a shaft component is formed as an undercut. As a result, the notch effect can be kept particularly low while realizing a firm and stable mounting of the plate spring on or on the component. Here, the undercut, which is for example also referred to as a radial recess, serves as a functional element, wherein the preferably elastic centering tongues are placed in the undercut or radial recess. In particular, this makes it possible for the centering tongues to latch into the undercut, as a result of which the plate spring is held in a force-locking and / or form-fitting manner on the component via the centering tongues.

In order to hold the plate spring particularly well on the component in the recess, it is preferably provided that the respective centering tongues have an inner diameter which is smaller than an outer diameter of the component, in particular the recess. In particular, the inner diameter is smaller than an outer diameter of a region of the component which adjoins the recess in the axial direction of the plate spring. As a result, the centering tongues, which are accommodated at least partially in the corresponding recess, can be supported on the region or on a wall of the region which at least partially delimits the recess in the axial direction of the plate spring, so that the plate springs are held in a form-fitting manner in the recess via the centering tongues can.

It has also proven to be particularly advantageous if the at least one component is a thrust bearing. The diaphragm spring is supported, for example, in the axial direction at least indirectly on the axial bearing. This embodiment is based on the finding that the diaphragm spring, which fulfills both the force transmission function and the holding and centering function, is particularly well suited for transmitting axial forces to a thrust bearing, so that axial forces via the thrust bearing, for example, from a further component of the drive train on the first component, in particular the shaft can be transmitted.

It has been found to be particularly advantageous if the drive train comprises an electric machine with a rotor element, in particular rotor carrier, and a rotatably connected to the device plate carrier for fins of a multi-plate clutch. The plate carrier can be formed integrally with the component. Alternatively, it is conceivable that the plate carrier, which is for example an inner plate carrier, and the component formed separately from each other and connected to each other, in particular rotatably connected, are. The plate spring is supported by the mediation of the thrust bearing in the axial direction of the rotor element and formed for transmitting axial forces between the component and thus the plate carrier and the rotor element. In other words, Axialkräfte between the plate carrier and the rotor element can be transmitted through the intermediary of the plate spring and the thrust bearing, wherein the rotor element is mounted on the disc carrier in the axial direction and supported or supportable via the thrust bearing and the plate spring. The rotor element is, for example, rotatable relative to the plate carrier and thus the component.

The invention further includes a method for mounting a disc spring according to the invention on the component, in which the centering tongues are spread elastically and pushed from bottom to top on the component. Due to the spreading of the centering tongues, their inner diameter is increased, so that the plate spring can be pushed onto or over the component, in particular the shaft, in a particularly simple manner. The plate spring is pushed so long in the axial direction of the component until the centering engage in the corresponding recess. If the centering tongues are in overlapping or overlapping with the recess, for example, the spreading of the centering tongues is terminated. As a result, the centering tongues can elastically deform back into an initial state or at least in the direction of the initial state and thus come to rest in the recess. In other words, the centering tongues engage in the recess, so that the plate spring is held in its axial direction on the component.

For example, the centering tongues are spread open by means of a tool, in particular an assembly tool, whereby a particularly simple, time-consuming and cost-effective feasible assembly can be realized. Preferably, the centering tongues are so elastic that they can be spread open by means of an assembly tool, such that the plate spring can be pulled over the shaft until the centering tongues engage in the recess.

Preferably, the disc spring against gravity from bottom to top, that is, for example, at least substantially perpendicular to a horizontal plane moves from bottom to top and thereby pushed onto the device. As a result, a particularly easy to be performed assembly can be realized.

To be particularly advantageous, it has been shown that the plate spring has at least three centering tongues, which are spaced apart in the circumferential direction. The centering tongues are preferably distributed uniformly in the circumferential direction of the plate spring, so that the centering tongues in the circumferential direction of the plate spring have the same pairwise distances.

Further advantages, features and details of the invention will become apparent from the following description of preferred embodiments and from the drawing. The features and feature combinations mentioned above in the description as well as the features and feature combinations mentioned below in the description of the figures and / or shown alone in the figures can be used not only in the respectively specified combination but also in other combinations or in isolation, without the scope of To leave invention.

The drawing shows in:

1 a schematic front view of a plate spring for a drive train of a motor vehicle, with an annular base body, with radially from the body to a respective free end extending cup spring tongues for transmitting an axial force on at least one component, and with the plate spring tongues different, radially from the base body extending to a respective further free end and arranged in a corresponding recess of a component centering tongues for centering the plate spring relative to the component;

2 a schematic sectional view of a mounting arrangement of the plate spring on the component, wherein the component is designed as a shaft;

3 partially a schematic sectional view of the mounting arrangement according to 2 ;

4 in sections, a further schematic sectional view of the mounting arrangement according to 2 and 3 , wherein the at least one component is designed as a thrust bearing, which is supported by the intermediary of the plate spring on the shaft, in particular on the collar of the shaft, in the axial direction;

5 Sectionally a schematic sectional view of a drive unit with the Mounting arrangement of the plate spring on the component, wherein the plate spring is centered inside; and

6 partially a schematic sectional view of the drive unit with the mounting arrangement of the plate spring on the component, wherein the plate spring is externally centered.

In the figures, identical or functionally identical elements are provided with the same reference numerals.

1 shows in a schematic front view with a whole 10 designated plate spring for a drive train of a motor vehicle, especially a passenger car. The plate spring 10 has an at least substantially annular body 12 and a plurality of plate spring tongues, of which in 1 two with 14 designated plate spring tongues are recognizable. The plate spring tongues 14 are integral with the annular body 12 formed and in the circumferential direction of the plate spring 10 spaced apart. Furthermore, the plate spring tongues extend 14 radially from the main body 12 to a respective free end 16 , In the present case, the plate spring tongues extend 14 radially inward of the body 12 to the respective free end 16 , The plate spring tongues 14 serve for transmitting an axial force or axial forces on at least one component, as will be explained in more detail below. The plate spring tongues 14 are so-called functional tongues which fulfill an axial force transmission function, in the context of which axial force is transmitted between at least one component and one component. The plate spring tongues 14 are relative to the main body 12 elastically deformable, in particular in the axial direction of the plate spring 10 , Will the plate spring tongues 14 with an axial force, for example, such acted that the diaphragm spring tongues 14 relative to the main body 12 in the axial direction of the diaphragm spring 10 elastically deformed, in particular bent, so are the diaphragm spring tongues 14 moved from an undeformed initial state in a state or deformed, in which the plate spring 10 one in the axial direction of the diaphragm spring 10 acting force, which is also referred to as axial force exerted on the component and / or the component. If, for example, the at least one component is mediated by the plate spring 10 supported on the component in the axial direction, and the component in the axial direction of the plate spring 10 moved towards the component, wherein the plate spring tongues 14 be deformed in the manner described, so causes the diaphragm spring 10 a force acting between the component and the component axial force which is transmitted from the component to the component or vice versa.

To now a particularly high functional performance of the diaphragm spring 10 to realize in a simple, weight and space and cost-effective way, the plate spring 10 a plurality of the plate spring tongues 14 different centering tongues, of which in 1 one with 18 designated centering is recognizable. Preferably, the plate spring 10 at least three centering tongues 18 on, which in the circumferential direction of the plate spring 10 spaced apart and preferably in the circumferential direction of the plate spring 10 are arranged evenly distributed. The respective centering tongues 18 extend radially inwardly from the body 12 until another respective free end 20 and can be arranged in a corresponding and preferably formed as undercut recess of the component.

The centering tongues 18 serve to center the plate spring 10 relative to the component, in particular on the component. The centering tongues 18 thus serve to fulfill a centering and holding function of the diaphragm spring 10 because these are about the centering tongues 18 held on the device and are centered relative to this.

Out 1 it can be seen that the plate spring tongues 14 and the centering tongues 18 Have circumferentially different shapes or geometries, so that the diaphragm spring tongues 14 and the centering tongues 18 can be adapted to the respective function at least substantially optimally. In particular, it is provided that the plate spring tongues 14 are arranged in a first plane and the centering tongues in a different from the first plane, second plane, wherein the planes, for example, obliquely to each other and / or in the axial direction of the plate spring 10 have a distance from each other.

2 shows a mounting arrangement of the diaphragm spring 10 at the aforementioned and in 2 With 22 designated component, which is designed as a shaft of a drive train of a motor vehicle. Out 2 it can be seen that the diaphragm spring 10 on the shaft (component 22 ) arranged and thereby by means of Zentrierzungen 18 centered and held on the shaft. The mounting arrangement is also referred to as assembly and is in 3 explained in more detail. In 3 is particularly well recognizable that the centering tongues 18 and the plate spring tongues 14 are arranged or run in different planes. In 3 is the one with 24 designated recess particularly well visible, which is designed as a relief of the shaft. The undercut thus serves as a functional element for centering and holding a counterpart in the form of the plate spring 10 , which by means of Zentrierzungen 18 over the undercut (recess 24 ) on the shaft (component 22 ) is held and centered.

Out 2 it can be seen that the shaft has a collar, through which a flange 26 is formed. In synopsis with 3 it can be seen that the diaphragm spring 10 over the plate spring tongues 14 in the axial direction on the flange 26 and thus the shaft is supportable, so that, for example, axial forces between the flange 26 and said at least one component via the plate spring 10 are transferable.

In the finished state of the powertrain is the flange 26 arranged for example on the part of an internal combustion engine of the drive train. On one of the internal combustion engine side facing the flange 26 closes a shaft 28 the shaft, wherein in the finished state of the drive train, the shaft 28 For example, facing a transmission of the drive train. For example, via the shaft 28 a gear drive, so that - based on the image plane of 2 - the flange 26 is arranged above and the gear drive is down.

When mounting the diaphragm spring 10 on the device 22 becomes the plate spring 10 in an in 3 by a directional arrow 30 illustrated mounting direction on the shaft, in particular the shaft 28 , postponed or attached. The mounting direction coincides with the axial direction of the shaft. To realize a particularly simple installation, it is provided that the mounting direction against gravity runs from bottom to top, so that so the plate spring 10 from bottom to top on the shaft or the shaft 28 is plugged.

When mounting the centering tongues 18 For example, spread by means of an assembly tool so that they have an inner diameter which is greater than its inner diameter D5 in the undeformed or in the recess 24 arranged state is. In the spread state, the plate spring can 10 over the shaft 28 pulled or pushed onto the shaft until the Zentrierzungen 18 in the corresponding recess 24 engage.

In 3 is an outer peripheral side surface 32 one in the axial direction of the flange 26 away to the recess 24 subsequent area 34 the shaft, in particular the shaft 28 , shown. The area 34 or its outer peripheral side surface 32 has a diameter in the form of an outer diameter D, which is also referred to as a shaft diameter. The inner diameter D5 is less than the outer diameter D, so that the centering tongues 18 into the recess 24 engage and thereby the diaphragm spring 10 can hold on the shaft.

Preferably, the centering tongues 18 integral with the main body 12 trained and thereby relative to the body 12 elastically deformable. For example, the centering tongues 18 in the axial direction of the diaphragm spring 10 relative to the main body 12 elastically deformable. When spreading the centering tongues 18 these become relative to the main body 12 elastically deformed, so that they hit the shaft or over the area 34 can be pushed. Are the centering tongues 18 in overlap or overlap with the recess 24 , so is the spreading of the Zentrierzungen 18 terminated, for example, by the mounting tool of the diaphragm spring 10 or the centering tongues 18 is solved. This allows the Zentrierzungen 18 deform elastically back to its initial state, so that the centering tongues 18 into the recess 24 intervention.

In 3 is with D4 an inner diameter of the diaphragm spring tongues 14 which is larger than the inner diameter D5 of the centering tongues 18 is. With D2 is an inner diameter of the annular body 12 denoted by D1, wherein with D1 a diameter of the annular base body 12 is designated. Further, with D3, another diameter of the centering tongues 18 designated. How out 3 can be seen, a respective vertex is arranged on the diameter D3, at which respective, each extending at an angle to each other length ranges of the respective centering tongue 18 to meet.

Because of the centering tongues 18 in the corresponding recess 24 (Puncture) intervene, the plate spring 10 centered on the shaft and held against its own weight, that is against gravity on the shaft, so that the diaphragm spring 10 can not slip down from the shaft. The respective centering tongue 18 is sufficiently elastic to help with the assembly of the diaphragm spring 10 over the outer peripheral side surface 32 pushed and then placed in the groove.

Furthermore, in 3 with t1 a depth of the recess 24 designated. The depth t1 indicates the measure or the amount by which the recess 24 in the radial direction inwardly bounding bottom, which through a corresponding wall portion of the device 22 is formed, in the radial direction inwardly relative to the outer peripheral side surface 32 is set back.

4 shows the mounting arrangement according to 2 and 3 , where in 4 the aforementioned component is shown, which serves as a thrust bearing 36 is trained. In synopsis with 5 It can be seen that the drive train a plate carrier in the form of an inner disc carrier 38 for holding fins of a multi-plate clutch of the drive train comprises. The lamellae mentioned are inner lamellae, which can interact with outer lamellae in a closed state of the multi-plate clutch, so that frictional forces are transmitted between the lamellae and in the lamellae. The inner disc carrier 38 is rotatably with the designed as a shaft component 22 connected, wherein the plate carrier 38 and the shaft can be formed separately from each other and rotatably connected to each other. Alternatively, it is conceivable that the plate carrier 38 integral with the shaft (component 22 ) connected is.

In addition, the drive train comprises an electric machine with a rotor element, which in the present case as a rotor carrier 40 is trained. On the rotor carrier 40 For example, rotor parts are provided for guiding a magnetic field, which is generated by magnets of the electric machine. The rotor carrier 40 is relative to the shaft (component 22 ) and thereby radial bearings 42 on the device 22 rotatably mounted. The component 22 is at least part of it 44 formed as a hollow shaft, in which a further shaft 46 the drive train is partially received. In the subarea 44 is another radial bearing 48 arranged, by means of which the shaft 46 on the device 22 is stored. The wave 46 is about respective gears 50 with another plate carrier 52 the drive train rotatably coupled, wherein the further disc carrier 52 for example, also an inner disc carrier is. Out 5 is recognizable that the device 22 and thus the plate carrier 38 via at least one thrust bearing 54 in the axial direction on the plate carrier 52 are stored as the component 22 and the plate carrier 38 relative to the plate carrier 52 are rotatable.

The plate carrier 52 is for example part of a further multi-plate clutch, wherein it can be provided that the plate carrier 38 and 52 are rotatably coupled to each other via the multi-plate clutches. Furthermore, it is conceivable that the rotor carrier 40 non-rotatably with the plate carrier via the first multi-plate clutch 38 and thus with the shaft (component 22 ) can be coupled.

Out 4 and 5 is particularly well recognizable that the thrust bearing 36 under the mediation of the diaphragm spring 10 in the axial direction on the component 22 and thus the plate carrier 38 is supportable, so that over the plate spring 10 Axial forces between the thrust bearing 36 or the rotor carrier 40 and the device 22 are transferable or be transferred. The rotor carrier 40 is thus under mediation of the thrust bearing 36 and the plate spring 10 in the axial direction on the component 22 supported, so that the diaphragm spring 10 the aforementioned Axialkraftübertragungsfunktion belongs. In addition, the diaphragm spring meets 10 the holding and centering function, as they by means of Zentrierzungen 18 centered and held on the shaft.

The plate spring 10 is formed, for example, of a metallic material. Alternatively, it is conceivable that the plate spring 10 is formed of a plastic, in particular fiber-reinforced plastic.

According to 5 is the plate spring 10 body-centered. 6 shows the mounting arrangement according to 5 , but with the difference that the diaphragm spring 10 in 6 is externally centered.

LIST OF REFERENCE NUMBERS

10

Belleville spring

12

body

14

Belleville spring tongue

16

free end

18

centering tongue

20

another free end

22

module

24

recess

26

flange

28

shaft

30

arrow

32

outer peripheral side surface

34

Area

36

thrust

38

plate carrier

40

rotorarm

42

radial bearings

44

subregion

46

wave

48

radial bearings

50

gearing

52

plate carrier

54

thrust

D1

diameter

D2

Inner diameter

D3

diameter

D4

Inner diameter

D5

Inner diameter

D

outer diameter

t1

depth

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

• US 2013/0213168 A1 [0002]

Claims (10)

Disc spring ( 10 ), in particular for a drive train of a motor vehicle, having an annular base body ( 12 ) and radially from the main body ( 12 ) to a respective free end ( 16 ) extending diaphragm spring tongues ( 14 ) for transmitting an axial force to at least one component ( 36 ), characterized in that the plate spring ( 10 ) of the plate spring tongues ( 14 ) different, radially from the main body ( 12 ) to a respective further free end ( 20 ) and in a corresponding recess ( 24 ) of a component ( 22 ) locatable tongues ( 18 ) for centering the plate spring ( 10 ) relative to the component ( 22 ) having. Disc spring ( 10 ) according to claim 1, characterized in that the plate spring tongues ( 14 ) on the circumferential side, in particular on the outer peripheral side, in each case a first shape and the centering tongues ( 18 ) circumferentially, in particular on the outer peripheral side, each having a different from the first shape, second shape. Disc spring ( 10 ) according to claim 1 or 2, characterized in that the plate spring tongues ( 14 ) in a first plane and the centering tongues ( 18 ) are arranged in a second plane different from the first plane. Disc spring ( 10 ) according to one of the preceding claims, characterized in that the centering tongues ( 18 ) relative to the main body ( 12 ) are elastically deformable. Drive train for a motor vehicle, comprising at least one component ( 22 ) and at least one plate spring ( 10 ) according to one of the preceding claims, by means of which axial forces on the at least one component ( 36 ) are transferable, wherein the Zentrierzungen ( 18 ) while centering the plate spring ( 10 ) relative to the component ( 22 ) in its recess ( 24 ) are included. Drive train according to claim 5, characterized in that the recess ( 24 ) of the component ( 22 ) is formed as an undercut. Drive train according to claim 5 or 6, characterized in that the respective centering tongues ( 18 ) have an inner diameter (D5) which is smaller than an outer diameter (D) of the component (D5) 22 ). Drive train according to one of claims 5 to 7, characterized in that the at least one component ( 36 ) an axial bearing ( 36 ). Drive train according to claim 8, characterized in that the drive train is an electric machine with a rotor element ( 40 ) and one with the component ( 22 ) rotatably connected plate carrier ( 38 ) for disks of a multi-plate clutch, wherein the plate spring ( 10 ) mediated by the thrust bearing ( 36 ) in the axial direction on the rotor element ( 40 ) and for transmitting axial forces between the component ( 22 ) and the rotor element ( 40 ) is trained. Method for mounting a plate spring ( 10 ) according to one of the preceding claims on the component ( 22 ), in which the centering tongues ( 18 ) spread elastically and from bottom to top on the device ( 22 ) are pushed.

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