DE3411824A1 - PISTON UNIT - Google Patents

Description

The invention relates to a piston unit according to the preamble of the claim 1. · .

In vehicle brake and clutch hydraulics, piston units are usually used, Consisting of a sealing element, piston and piston rod, the pistons of which have a cylinder profile and those in the cylinder bore sliding outer surface guides the piston unit. Pressure bolts or piston rods are used to transmit power and generate hydraulic force used, which execute a pivoting movement in relation to the cylinder center axis during the stroke movement of the piston. To make this possible, up to now, the thick bolts or piston rods are articulated in the piston (see e.g. DE-OS 11 97 770 or DE-OS 29 34 218). There is now a lifting movement of the piston executed with a pivoting movement of the piston rod in relation to the cylinder axis Piston radial forces, which act on the cylinder wall. The radial forces are dependent on the piston force applied in the axial direction and on the size of the swivel angle. The adverse consequence of this is one one-sided and premature material removal on the piston skirt and on the cylinder wall, leading to premature destruction of the sealing surfaces and to the ^ Failure of the. Sealing element and ultimately the entire unit leads. the end from SE-PS 210 202 pivotable, one-piece piston units with spherical pistons and spherically machined sealing elements are already known. In order to The relatively complex movable piston rod restraint is no longer necessary and the piston unit can be pivoted. The side forces that occur remain but unchanged due to the sealing plane acting perpendicular to the cylinder axis. In addition, a piston unit designed in this way is only known in axial piston pumps, but not in the piston units of the initially introduced mentioned Art.

It is therefore an object of the invention to provide a piston unit that pressurized even when the piston rod is inclined with respect to the cylinder axis does not exert any side forces on the cylinder bore wall. The solution to this problem is the characterizing part of claim 1 to remove. Claims 2 and 3 contain advantageous refinements.

To solve this problem, the force-transmitting piston rod is rigidly connected to the piston carrying the diaphragm. With a swivel movement

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the piston rod doing a certain angular amount guides the piston in the The cylinder bore also swivels by the same angle the end. In order to enable this pivoting movement, the shoulder of the piston in the contact area with the cylinder wall is designed so that a Panning is possible. This collar approach is designed as a disk-shaped spherical zone. This results in between the cylinder wall and the spherical zone a circumferential contact line for the structurally defined swivel range, whose plane is always at right angles to the cylinder axis. Jamming of the piston unit is prevented. The end face on the pressure chamber side the spherical zone itself is the support collar of the sealing element, which swivels with the push rod when swiveling or when force is introduced at an angle is, so that the sealing plane on the sealing element relative to the cylinder wall performs the same movement. The sealing plane thus assumes the same angle to the cylinder transverse plane as the push rod to the cylinder longitudinal axis. Since the Hydraulic force acting on the inclined sealing plane has a component directed perpendicular to the cylinder wall that is just as large like the corresponding, oppositely acting component of the inclined one Piston rod, the piston unit is free from radial forces. The invention enables the production of piston or cylinder liners Materials with lower surface hardness, up to the use of elastomers, thus a reduction in the quality of the sliding pairing of the piston and cylinder running surface. Furthermore, a reduction in the overall length and weight of the cylinder housing is achieved because the leading and load-bearing areas of the piston can be made very short. Another advantageous application is the one-piece design of the sealing and guide element Made of elastomer that is vulcanized onto the metallic piston part.

The invention thus articulated connections of pivotable, im Piston attached push rods obsolete. The well-known "baking" of the cylindrical piston known from dirt and corrosion of slave cylinders on drum brakes is reduced.

Another advantageous application of the invention is particularly important Pairings of plastic cylinders with "plastic pistons" come into their own, since in addition to the gate parts according to the invention, there is only one temperature-independent Swelling conditioning of the piston pie in the cylinder bore becomes necessary.

The invention is to be explained in more detail with reference to the following figures. It demonstrate:

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-A-

Fig. 1 shows an inventive design of the basket unit with the theoretical occurring forces.

2 shows the design of the piston unit with a parallel sealing and pivoting plane.
3 shows the piston unit with the sealing plane lying in the swivel plane.

Fig. 4 shows the one-piece design of the sealing and guide element as Elastomer-metal compound.

The functional model shown in FIG. 1 shows the schematically illustrated, deflected piston unit 1 in the bore 2 of a cylinder 3, which is deflected with its rigid piston rod 4 and the sealing plane 6 of the sealing element 5 arranged at right angles to it by the angle oC. Furthermore, the vectors of the force components are shown with their effective directions. In detail, these are the force F introduced via the push rod 4 with the associated axial component F_ ^. .. = F χ cosoO and the radial components closing the triangle of forces F_ radial = F χ sinoC »whose lines of action are at right angles to one another. On the pressure chamber side, the hydraulic force F "= ρ χ A acts in the axial direction, the force F_ being the product of the medium pressure ρ and the projection area A of the bore diameter D. _{The radial component F 71} - standing at right angles to it. ,. , = ρ χ A. results from the product of the medium HEadial P ^r oj · _v ρ

pressure ρ and the radial projection area A_. = -γ- χ D χ sinoC. at tlihiht it IJ F ^ ζ it ζ jr ^ F ^

The equilibrium of forces is IJ + F ^, = ζ with ζ ₌ jr ^ ₊ F ^^, whereby the radial components F_,.

= F__,. - cancel and thus freedom from lateral forces between the piston unit

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and the bore wall of the cylinder prevails.

However, this consideration only applies to the case that sealing level 6 and The pivot plane 8 of the collar attachment 7 is congruent in the pivot plane 8. With lip rings commonly used in vehicle brake hydraulics therefore the sealing plane 6 usually by an amount "f" in front of the pivot plane 8 be arranged in the direction of the pressure chamber 9 (Fig. 2).

Characterized ⁿ f "in the functional limit of the invention to about 8 ° deflection occurs with increasing deflection angle 0L and depending on the size of a noticeable ¹ parallel displacement of the line of action of F_. On the piston rod 4, which produced a resultant moment M with the product of the order Lateral force F _c χ piston rod length 1, generated with the lateral force F_ =

r \ 2. ^

- ^The side force F_ occurring here, which is caused by the distance

COSod · \ ν · U S

"f" of the sealing plane 6 to the deflection plane 8 and of the length 1, the piston

ic

"'depends on rod 4, is with usual deflection angles and push rod

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length less than 8 % of the side forces of the movably mounted push rods in the piston.

In Fig. 3 an embodiment of the piston unit 1 and its position in the cylinder 3 can be seen. In this variant, the pivot and sealing plane are offset by the amount ^M f "due to the geometry of the sealing element used for this purpose. It essentially consists of axially lined up, rotationally symmetrical elements and is shown as a design with and without return spring 10 in cylinder 3. In the variant With the return spring 10, the conical centering projection 11 is located on the pressure chamber side to fix the adjacent return spring 10, which secures the sealing element 5 against axial displacement in the groove 13 of the sealing element seat via a collar 12 with a larger diameter Collar approach 7> which has a circular surface line 15 in the side view and represents a spherical zone 16, such that upon actuation and "deflection to the cylinder bore axis 14 the; Piston unit 1 pivoted about the angle Λ on the bore wall of the cylinder 3 can be tilted or deflected all around and without jamming. The plane-parallel spherical zone -16 is part of an enveloping sphere 17, the diameter "D" of which corresponds to the nominal dimension of the cylinder bore 2 of the cylinder 3, the position of the center 18 of the enveloping sphere 17 on the plane surface 19 or within the plane-parallel spherical zone 16 so that the Tilting the same always · there is a linear contact with the cylinder wall. The minimum width "2e ^{n of} the spherical zone 16 required for this depends on the deflection angle oC of the piston unit 1 to the cylinder bore axis 14" and the nominal diameter "D" of the cylinder bore 2 and is symmetrical to the center of the enveloping sphere 17 with the minimum width "e", the flat surface 19 is the seat of the center 18 of the enveloping ball 17 and thus the stop for the bottom of the sealing element 5 The conical centering projection 11 and the return spring 10 as well as the dimension "e" on the spherical zone 16 are omitted, which leads to shorter overall lengths of the piston unit 1.

. The application shown in Fig. 3 shown two piston units 1 which upon deflection by the elliptical shape of the sealed cross-section of a different gap widening "s" out depending on the angle of deflection, will always be to the application of the piston unit 1 subjected sejLn, djh-gich the gap "s" for the spherical zone width "e" without um- '

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gripping, linear contact on both sides evenly enlarged and for the spherical zone width "2e", the gap is doubled on one side, but instead maintains a comprehensive, linear contact or guidance. Extrusion damage on the sealing element 5 by introducing a support disk 20 for the ones shown in FIG Lip rings avoided.

Fig. 4 shows the structural design of the spherically shaped, piston unit 1 with a seated in the annular groove 13 made of PTFE plastic primary sealing ring 5 ¹ and an elastomeric O-ring 21 as an elastic tensioning element. The sealing edge 22 (equivalent to the sealing plane 6 of the primary sealing ring) lies congruently with the pivot plane 8 of the spherical zone 16 of the piston one above the other and brings about the freedom of lateral forces described above. Due to the position of the sealing edge 22 in the swivel plane 8, the hard primary sealing ring 5 'also takes over the piston guide in the cylinder housing 3. The structural design is the same as that already described in FIG. 3.

In Fig. 5 is a one-piece design of sealing element 5 and spherical zone 16 made of the same material. The metallic Piston part 23 is advantageous as a combined deep-drawn part with loose push rods 4 executed, which are then rigidly joined together by form or force fit will. The metallic piston part 23 consists of the cylindrical Blind hole cup 24, at the open end of which the piston head 25 is stretched radially and at right angles to the longitudinal axis and via a Badius runs out as an axially parallel collar 26. Piston crown 25 and collar 26 of the metallic Piston part 23 are the connecting surfaces for the one-piece vulcanized elastomeric sealing element 5 "with the elastomeric spherical zone 16. The effect of the pivoting of the sealing plane 6 in connection with the spherical zone and the effect that is almost free of radial forces therefore make it possible to achieve this Centering and guiding part, the ball zone 16 together with the sealing element ' 5 "made in one piece from an elastomer with relatively low compressive strength and vulcanized in one operation, which is an optimal solution in terms of damage and wear and tear means and reduces production costs.

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Claims (3)

10 1. Basket unit for master cylinder / or slave cylinder of hydraulic vehicle clutch and / or brake systems, consisting of a sealing element, a piston rod guided in the cylinder and an oscillating piston guided in the cylinder bore with a spherical zone, the piston rod being rigidly connected to the spherical zone and the longitudinal axis of the piston unit can be deflected by an angle relative to the center axis of the cylinder, characterized in that the spherical zone (16) of the piston unit (i) has a pivot plane (8) perpendicular to the piston rod axis, in which or to the parallel sealing elements (5, 5 ', 5 ") are arranged, which form a jointly pivotable sealing plane (6). 2. Piston unit according to claim 1, characterized in that the sealing elements (5 »5 ¹ ) are arranged positively and / or non-positively in an annular groove (13) of the piston unit (i). 3. Piston unit according to claim 1, characterized in that the piston unit (1) with the sealing element (5 ") is made in one piece, the elastomeric sealing element (5 ⁿ ) and the elastomeric spherical zone (16) on the metallic piston part (23) are vulcanized. EPO-COPY