DE7915980U1 - BRAKE ACTUATOR LEVER FOR A SELF-CENTERING PART COVER DISC BRAKE - Google Patents

Description

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. EBrake operating lever for a self-centering Partially lined disc brake

The innovation relates to a brake lever for a self-centering one Partially lined disc brake with the features according to the preamble of claim 1. Such a brake operating lever is from the FR-PS 1 411 427 known. A steel ball provided there only interacts with a plunger with a small end face cross-section.

Part-lined disc brakes are generally not considered to be very extensive Emergency or parking brake used because of the difficulty in applying sufficient brake pressure to the brake pads when the motor vehicle is stationary. For vehicles built in large numbers, disc brakes are for the Braking is arranged on all wheels while driving, whereas a drum brake is usually used as an emergency or parking brake.

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The advancing technology in commercially available disc brakes makes it is now possible to use disc brakes where previously drum brakes were were used.

This makes it possible to use self-centering partial-facing disc brakes as well to be used as an emergency or parking brake on relatively heavy commercial and construction vehicles. In this case it is sufficient to only switch on one brake unit the vehicle output shaft or another driven shaft.

The brake disk driven by the output shaft is usually used here Enclosed like pliers by a self-centering brake housing and braked by a pivotably mounted brake operating lever. The brake housing also serves as a carrier for the brake actuation device .

Compressed air holds one provided in the brake actuation device Compression spring in the compressed state until the compressed air is released. The brake is actuated via the spring force the expanding compression spring.

The expansion or relaxation of a previously compressed compression spring has the effect of decreasing the braking force as the brake is applied, i.e. at the end of the brake application it becomes as much as possible Braking force should be available, exerted too little spring force by the increasingly relaxing compression spring.

The innovation is therefore based on the task of a compressed air operated Brake system for a disc brake used as an emergency or parking brake to train the brake lever so that despite decreasing Spring force of the Breirisbetätigugsvorrichtung an approximately constant Adjusts braking or clamping force on the brake disc, which should also be independent of the degree of wear of the brake pads. The constant braking or The clamping force should be retained during the entire relaxation path of the compression spring.

This task is carried out according to the innovation with the in the characterizing part of claim 1 specified features solved.

■ Y · · · • · Λ ·

The arrangement of a spherical cap-shaped contact surface on the short lever arm and the displacement of the contact point on the end face of the brake piston that interacts with it means that the spring force decreases with increasing brake actuation due to a lever force booster. j counteracted.

The contact surface is advantageously designed as a steel ball, which is partially embedded in a cavity in the short lever arm.

Two exemplary embodiments of the explained in more detail in the description Disc brakes according to the innovation are shown in the drawings. Show it:

Fig. 1 is a side view of the disc brake, partly in section;

Fig. 2 is a view of the brake housing and brake actuation lever, partially on average;

3 shows a partially sectioned side view of a modified one Embodiment of the contact surface between the actuating lever and the brake piston on an enlarged scale and

Fig. 4 in a diagram the vectorial course of the forces on the Brake disc linkage.

As FIGS. 1 and 2 show, the disc brake device 10 is on attached to a support frame 12, not shown in FIG. 1, which is arranged on a part of the vehicle, for example on the axle housing is. The disk brake device is fastened to the support frame 12 in a groove 20 which is bounded at the top by retaining plates 14 which are fixed by screws 16. In this way, the braking device 10 can be held in such a position that a brake disc 22 or some other rotor connected to a drive or output shaft 24 can be gripped around like tongs.

A brake housing 26 is arranged so that, as shown in FIG. 1, there are two on each side of the brake disc 22 mounted friction lining. The lower part of the brake housing 26 runs into a reinforced Part 48 for the articulated reception of a lever arm 74 and on the opposite Page into a part 54 for receiving an adjusting bolt 50. The reinforced part 48 has reinforcing ribs at its lower end 60 and 62 a pivot pin bearing and a bore 32 for receiving a piston 30, while that on the other Side of the brake disc hanging down part 54 contains a threaded hole 52. The piston 30 is slidably displaceable in the bore 32, in order to press a pressure plate 34, 40 connected to the friction lining material 36 against the brake disc 22. The other side of the brake disc During braking, 22 is with the on another pressure plate 42, 44 attached friction layer 46 in contact. On the adjustment-side part 54 of the brake housing 26 can be used for the basic setting of the brake, precisely adjust the adjusting bolt 50 within the threaded bore 52 and fix it by means of a lock nut 56.

The upstanding reinforcing ribs that form a unit with the brake housing 26 60, 62 are provided in their lower part with aligned bores 64 and 66 into which a pin 70 is plugged in. This pin serves as a swivel joint and as an azhse for the brake operating lever 72. The brake operating lever 72 comprises a long lever arm 74 with a bore 76 on its free one End, as well as a short lever arm 80 which extends from the pin 70 in the opposite direction of the long lever arm. The long lever arm 74 is connected via a linkage 82 to a brake actuation device 84, which in turn is attached to the upper ends of the upright reinforcing ribs of the brake housing 26 is set in such a way that one with a fork head 92 connected Push rod 90 is aligned with a hinge pin 94 which forms the connection between the long lever arm 74 and the brake actuator 84 brings about. The brake actuator is of conventional design and is air operated so that when compressed an internal spring prevents actuation of the disc brake. If the compressed air fails, this spring is relaxed, with the result that the push rod 90 is pushed out and the brake is applied.

The parts essential for the innovation are located in the short lever arm 80 for the mechanical loading of the piston 30 and thus for brake actuation. As FIG. 1 shows, the short lever arm 80 has a cavity 96 for receiving a steel ball in a form-fitting manner or a similarly shaped spherical contact element 100. The The cavity has a dimension adapted to the diameter of the steel ball and a smaller depth compared to the diameter of the steel ball, so that the steel ball protrudes slightly outside the cavity.

The contact point A shown in Fig. 1 between the steel ball and adjacent piston surface is the contact point when the brake is released. The contact point B lying on the dash-dotted line 102 occurs when the brake is applied. These two positions of contact purictes are the extreme situations. The position of the long lever arm 74 indicated in dashed lines can be equated with a Position that results from heavy wear of the friction lining, which would then have to be readjusted. The long lever arm 74 of the brake operating lever 2 always returns to position I illustrated with solid lines, which corresponds to the released state of the brake, in which, however, the steel ball 100 at the contact point A does not yet touch the piston 30. This depends on the degree of wear of the friction lining disks 36 land 46 from. Contact between the steel ball and the piston is not necessary when the brake is released.

Fig. 3 shows a variant of the brake actuation linkage at the end of the short lever arm of the actuating lever 72. The bore 32 receives a piston 104 in this exemplary embodiment. Between An additional pressure plate 106, which has a smooth surface 110, is provided for this piston and the steel ball 100 is provided which is slidable on the adjacent smooth surface 112 of the piston 104 can be moved, while the side 114 of the pressure plate 106 facing the steel ball with a concave Cavity 116 is provided for receiving the steel ball.

The braking device works as follows.

The benefit of using a steel ball inside the brake operating lever lies in the uniform course of the clamping force generated

when the brake is applied. When the brake is released, the compressed air presses in the Brake actuation device 84 the spring provided therein together, so that the long lever arm 74 is in the position illustrated in FIG. 1 with solid lines. As soon as the compressed air relaxes is, the spring in the brake actuator 84 urges the push rod 90 outward so that the long lever arm 74 into the in Fig. 1 position II shown in dashed lines is moved (the dashed line Position II shown is comparable to an extreme position in the case of strong Wear of the friction lining disks. Adjustment by means of the adjustment bolt 50 would be appropriate in this case. During normal operation, the pivoting of the long lever arm 74 would make less than it would with the Position II is indicated.) Due to the great length of the long lever arm 74 in relation to the length of the short lever arm 80, the leverage is from the pivot point of the pivot pin 94 to the steel ball 100 reinforced and transferred to the piston 30 via the steel ball, creating a clamping force against the brake disc, which is held by the pressure plate 42 on its opposite side from which the adjusting bolt 50 is located.

It is important for the effectiveness of the braking device that the steel ball 100 is arranged on the short lever arm 80 and executes such a relative movement with respect to the pin 70 that when the long lever arm 74 is pivoted from position I to position II, the contact path of the steel ball on Piston changes the leverage ratio. In other words, when the long lever arm is moved into position II, the effective length of the short lever arm is shortened, since during this pivoting movement the contact point between the steel ball and piston moves upwards and the distance between this contact point and the axis of the pin 70 becomes smaller . This increases the leverage between the long lever arm and the short lever arm as a function of the pivoting dec long lever arm.

The uniformity of the clamping force over the entire brake actuation path remains during the pivoting of the long lever arm about the pin 70 despite the decrease in the spring force in the Brake operating device provided spring received. By approaching the contact point on the side of the piston The lever force amplification caused by the steel ball migrating with respect to the axis of the pin 70 acts namely to ease the force against the spring force when it relaxes from its compressed state. There is thus the effect that A decreasing spring force and an increasing lever force add up to a constant clamping force.

The diagram in FIG. 4 illustrates this geometric relationship. DAwith the braking force over the entire pivoting path of the long lever arm remains uniform, so F must be approximately equal to F ", where F and F" are the braking forces in a first position A and B in a second layer. The relationship between the position I and the position II is based on the following 4 are illustrated.

On condition that

> Sf ₂ ; R ₁ > R ₂ ; r _± >

x R, = M = F ₁ χ r

Sf ₂ χ R ₂ = M ₂ = F ₂ χ

M, and M represent the moments 1 and

Sf. χ R _n M _n __ ι ι ^

1 r, r.

^Sf 2 ^{x R} 2

^{2 r} 2 ^r 2

whereby

M ₁ r-, M ₁ Mp

- ^L = - or - = - = ■ M

- 13 -

These relationships presuppose ideal conditions as they approximate can be achieved with the embodiment of this innovation. An approximation to ideal conditions is, however, with a brake not necessary at all. For example, at contact point B in Fig. 4, initial forces and also losses between pressure ball and piston are in the direction of the pressure components is not taken into account.

The disc brake according to the invention is a self-centering one Brake that adjusts itself in a self-centering manner during actuation by aligning it in the groove 20. After releasing the brake the friction lining disks can still touch the brake disk, but do not produce any effective braking force or clamping force, so that the brake disk is freely rotatable. The long lever arm 74 always returns to position I, while the steel ball 100 depending on the degree of wear of the friction lining disks 36 and 46 can more or less touch the piston 30 at the contact point A, while the brake disk 22 running around. Contact between the steel ball and the piston is not necessary when the brake is released (position I). With only a little Around the circumference of the brake disk or a rotor comparable to it, the disks can touch each other up to a fraction of a millimeter.

The adjusting bolt 50 can be screwed in so far that the friction lining disk adjacent to it is brought close enough to the brake disk to ensure proper operation of the disc brake.

Claims (7)

1. Brake actuation lever for a self-centering partially-lined disc brake, which is pivotably mounted around a pin in front of the end face of a piston that cooperates with brake linings in the lower part of a brake housing, and which is connected with its long lever arm to a brake actuation device operating under spring pressure and at the end of its short lever arm has a spherical cap-shaped contact surface pointing towards the end face of the piston, characterized by such an arrangement of the contact surface with the end face of the piston (30) that the contact surface with increasing brake actuation moves closer to the axis of the pin (70) on the end face of the piston (30) relocated. 2. Brake operating lever according to claim 1, characterized in that the spherical cap-shaped contact surface of a steel ball partially embedded in a cavity (96) of the shorter lever arm (80) (100) is formed, which can be rolled off on the end face of the piston (30) when the brake is actuated, the contact point being between the steel ball and the piston face of the axis of the pin (70) approaches. 3. Breras actuation lever according to claim 2, characterized in that the depth of the cavity (96) is smaller than the diameter of the steel ball (100), and that the cavity matched one of the steel balls Has inner diameter. 4. Brake operating lever according to claim 2, characterized in that the short lever arm (80) extends from the axis of the pin (70) to Ui.:.er the axis of the piston (30) and the steel ball (100) is opposite in the axis of the end face of the piston (30) when the brake is not actuated. 5. Brake operating lever according to claim 1, characterized in that between the steel ball (100) and the end face (110) of the piston (104) one on the end face (110) is slidably displaceable Pressure plate (106) is arranged with a recess (116) adapted to the curvature of the steel ball (100). 6. Brake operating lever according to claim 5, characterized in that the pressure plate (106) is disc-shaped and has a larger diameter than the contact surface and a smaller one Has diameter than the piston bore (32). 7. brake actuation lever according to claim 5, characterized in that when the brake is actuated, the pressure plate (106) can slide on the end face (110) and the opposing contact surfaces move the axis of the pin (70) closerη. Brake actuation lever according to Claim 1, characterized in that one leg of the brake housing (26) is a reinforced part
(48) carries the pin (70) for the brake actuation lever (72) and the piston (30), and the other leg has a threaded bore (52), and that both legs are connected to one another by a bridge member (28) and upwards in two with
Reinforcing ribs (60, 62) provided webs run out, which at
their upper end is provided with flange bores for the brake actuation device (84). Brake operating lever according to claim 8, characterized in that there is a an adjusting bolt (50) can be screwed into the threaded bore (52).