DE10046723A1 - Door positioning device for holding a motor vehicle door in various opening positions comprises a cylinder having a turning sash provided with a check valve having a high opening pressure and a check valve having a low opening pressure - Google Patents

Abstract

Door positioning device arranged between a door and a door frame comprises a cylinder (1) in which a turning sash (2) is rotatably arranged. Pressure chambers are defined by a leaf (4, 5) of the turning sash and a separating wall of the cylinder engaging in between. The turning sash is provided with a check valve having a high opening pressure (step valve (14, 15) and a check valve (16, 17) having a low opening pressure. The check valve with the high opening pressure blocks one pressure chamber defined by the leaf and the check valve with the low opening pressure blocks the other pressure chamber defined the leaf. Preferred Features: The axis of rotation (3) of the turning sash coincides with the axis of rotation of the door.

Description

The present invention relates to door locks between a door and a door frame are arranged. Such door locks are in particular for holding a motor vehicle door in different opening positions relative to provided the door frame.

DE 42 39 172 C1, for example, has disclosed a door arrester, in which a cylinder and a piston displaceably arranged therein are provided can be seen, on the two end faces of each a pressure chamber. The col ben has a step valve and two non-return valves connected to it valves. As the check valves only digitally on pressure differences need to respond, inexpensive spring-loaded ball valves or the same apply. The two check valves are on the stepped valve connected that when the piston is moved into a Actuate the check valve via the fluid column in the closing direction is struck. The fluid column can then continue to flow through the control channel and a corresponding increase in pressure of the fluid in the prechamber of the Introduce the stepped valve. Due to the pressure increase of the fluid in the prechamber  initially only the small piston area is acted upon by the Tight fit of the elevation of the piston crown is limited. Once that force effect is greater than the force of the stepped piston in its upper dead center pressing helical compression spring, the stepped piston is in its lower dead location shifted. This allows the fluid to enter the main chamber of the stepped vein tils overflow, causing the pressure increase of the fluid on the entire Bo the surface of the stepped piston becomes effective.

A disadvantage of such door stays is their relatively large space requirement in Longitudinal direction of the cylinder.

The object of the present invention is therefore to eliminate this disadvantage gene.

A door arrester according to the invention is proposed, which between a door and a door frame is arranged, with a cylinder in which a Swivel wing is pivotally arranged, with pressure chambers of one each Wing of the rotary wing and one between the wings of the rotary wing fenden partition of the cylinder are limited, and wherein the wing with egg a check valve with a high opening pressure and with a return check valve is provided with a low opening pressure, and the rear impact valve with high opening pressure one limited by the wing Pressure chamber locks, and being the check valve with a low opening pressure blocks the other pressure space bounded by the wing.

When the door is swiveled, the rotating wing is turned towards the cylinder instead. With the door arrester according to the invention Therefore, large swivel angles in a small space and in a small space Way to be realized. The door arrester according to the invention works the same principle as the door arrester known from DE 42 39 172 C1.

In the case of check valves with high opening pressure, the closing bodies for example, by a correspondingly strongly biased spring  pressed their valve seat that a minimum pressure overcome in the pressure chamber must be done before the check valve opens. Is the check valve Once opened, the flow resistance of the setback can be low valve a flow through the hydraulic fluid with significantly lowered Allow printing. Check valves with high opening pressure and low According to flow resistance can be formed by step valves, such as For example, are disclosed in DE-42 39 172 C1. The step piston is against one Spring load is axially displaceable, the opening pressure on a small nere piston area and the flow pressure acting in the open position acts on a larger piston area.

Check valves with low opening pressure can be conventional check be impact valves, for example ball valves, in which a spring-loaded closing body is spring loaded against its valve seat, the closing body already under low pressure against the force of the spring from its valve seat lifts.

The cylinder and the wing are in a way on the door and on the Door frames added that in any opening position chosen all non-return valves are in the locked position. To pivot the A minimum force must be applied to the door, which is a minimum pressure in one corresponds to the pressure chambers in the cylinder. Then under this minimum pressure the check valve with high opening pressure in the manner described open.

A partition of the cylinder can be provided on both sides of a wing be seen, both partitions together with the wing one each Limit the pressure space. When the door is swiveled, the rotary flap turns gel in the cylinder. The volume of one pressure chamber increases and that Volume of the other pressure chamber decreases during the rotation of the Rotary wing, hydraulic fluid from the one pressure chamber over the preferably designed as a step valve check valve with high opening pressure reached. The conventional check valve with low opening pressure  locks the pressure chamber, the volume of which is under the swivel movement of the wing reduced.

An axis of rotation of the rotary wing can be provided with a pinion that with a rack combs. The rack can then be hinged to the door be while the cylinder with the sash is housed in the door frame can be.

The pivot axis of the door can coincide with the axis of rotation of the rotating leaf fall. In this case, the rack mentioned above is omitted. The cylinder can be in be housed in the door frame, the rotating sash rotatably with the door can be connected.

The invention is illustrated below with the aid of three in a total of seven figures illustrated embodiments explained in more detail. Show it:

Figure 1 shows a door arrester according to the invention in longitudinal section.

Fig. 2 shows the door arrester according to the invention from Fig. 1 in cross section

Fig. 3, 4, 5 working positions of a step valve, as it is used in he inventive door locks and

Fig. 6 is a characteristic curve of the multistage valve as shown in FIGS. 3 to 5.

The illustrated in FIGS. 1 and 2, door arrester according to the invention is arranged between a door and a door frame, wherein the door and the door frame are not shown in the illustration. The door arrester has a cylinder 1 in which a rotating leaf 2 is received. An axis of rotation 3 of the rotary wing 2 coincides with the longitudinal axis of the cylinder 1 . The rotary wing 2 is pivotally mounted in the cylinder 1 about its axis of rotation 3 . The rotary wing 2 has two wings 4 , 5 , which extend in the radial direction up to the cylinder wall 6 .

Between the two wings 4 , 5 integrally ausgebil Dete partitions 7 , 8 are formed on the cylinder 1, which engage between the two wings 4 , 5 a. The partitions 7 , 8 each extend up to a teilzylindri's section 9 of the rotary wing 2nd

The cylinder 1 with the partitions 7 , 8 together with the rotary wing 2 limits a total of four pressure chambers 10 , 11 , 12 , 13th Each wing 4 , 5 is provided with a step valve 14 , 15 and with a conventional check valve 16 , 17 . The step valves 14 , 15 are shown in FIGS. 1 and 2. The check valves 16 , 17 are only shown in FIG. 1. The stage valve 14 blocks the pressure chamber 12 . The stepped valve 15 blocks the pressure chamber 11 . The check valve 17 blocks the pressure chamber 13 . The check valve 16 blocks the pressure chamber 10 .

In the present embodiment, the axis of rotation 3 can be articulated from the door not shown. In the event that the door is pivoted out of any intermediate position, the axis of rotation 3 is rotated, that is, the rotating leaf 2 is rotated in the cylinder 1 . If the rotary wing 2 is to be turned clockwise, for example, it is necessary that a minimum pressure in the pressure chamber 13 opens the step valve 14 . For this purpose, a correspondingly large torque must act on the axis of rotation 3 of the rotary wing 2 . Once the step valve 14 is opened, there is a wide res pivoting of the rotary wing 2 with a significantly reduced torque, hydraulic fluid from the pressure chamber 13 via the check valve 17 entering the pressure chamber 12 , and hydraulic fluid from the pressure chamber 11 via the check valve 16 arrives in the pressure chamber 10 . The pivot angle is positively limited by the partitions 7 , 8 .

In FIGS. 3 to 6, the structure and operation of a contemporary stage valve 14 Inventive explained in more detail 15th A stepped piston 18 is pressed against a valve seat 20 by means of a valve spring 19 . In the closed position shown in FIG. 3, only a small piston surface 21 is available for pressurization, which is limited by the valve seat 20 . The stepped piston can also be designed as a ball.

When the above-mentioned minimum pressure is exceeded, the step piston 18 is shifted to the left. Under this shift, the stage piston ben 18 moves away from its valve seat 20 , so that instead of the reduced piston surface 21 , the full piston surface of the stage piston 18 , that is to say an enlarged piston surface 22 , is now available. As a result of this enlarged piston surface 22, there is now a rapid displacement of the stepped piston 18 to the left, so that hydraulic fluid can flow through the step valve under significantly reduced pressure. Fig. 5 shows the step valve in the open position, hydraulic fluid flowing through the step valve with reduced flow pressure.

Fig. 6 now shows the characteristic of a multi-stage valve according to the invention with three operating points A, B, C. In operating point A, the required minimum pressure has just been reached, below which the multi-stage piston 18 begins to move away from its valve seat 20 . This situation is shown in FIG. 3. At operating point B, the stepped piston 18 is in the open position, the pressure being considerably reduced. The pressure drop from point A to point B is brought about by the displacement of the stepped piston 18 , as shown in FIG. 4. The pressure increase is dependent on the flow speed with which hydraulic fluid flows through the stepped valve. In Fig. 6, V _c denotes a swiveling speed of the motor vehicle door, below which a flow pressure is established in the stepped valve, which is marked on the characteristic curve under point C. This situation shows Fig. 5.

reference numerals

1

cylinder

2

rotary wing

3

axis of rotation

4

wing

5

wing

6

cylinder wall

7

partition wall

8th

partition wall

9

partially cylindrical section

10

pressure chamber

11

pressure chamber

12

pressure chamber

13

pressure chamber

14

stage valve

15

stage valve

16

check valve

17

check valve

18

stepped piston

19

valve spring

20

valve seat

21

small piston area

22

enlarged piston area

Claims (3)

1. Door arrester, which is arranged between a door and a door frame, with a cylinder ( 1 ) in which a rotating wing ( 2 ) is pivotally arranged, pressure chambers ( 10 , 11 , 12 , 13 ) each of a wing ( 4th , 5 ) of the rotary wing ( 2 ) and of a partition ( 7 , 8 ) of the cylinder ( 1 ) between the wing ( 4 , 5 ) are inserted, the wing ( 2 ) with a check valve with a high opening pressure (step valve 14 , 15 ) and with a check valve with a low opening pressure ( 16 , 17 ), and wherein the check valve with a high opening pressure (step valve 14 , 15 ) defines a pressure chamber ( 11 , 12 ) delimited by the wing ( 4 , 5 ) blocks, and wherein the check valve with low opening pressure ( 16 , 17 ) the other by the wing ( 4 , 5 ) limited pressure chamber ( 10 , 13 ) blocks. 2. Door arrester according to claim 1, wherein the door is pivotable about a pivot axis, wherein the axis of rotation ( 3 ) of the rotating leaf ( 2 ) coincides with the pivot axis of the door. 3. Door arrester according to claim 2, in which the cylinder ( 1 ) is received on the door frame, the axis of rotation ( 3 ) of the rotating leaf ( 2 ) being connected in a rotationally fixed manner to the door.