DE1149271B - Telescopic door closer - Google Patents

Description

Telescopic door flower The invention relates to a telescopic closer for the leaves of doors with a hydraulic damping device, consisting of from a cylinder, a piston with a piston rod protruding from the cylinder, a closing spring supported against the cylinder and the piston and one adjustable, regulating the closing movement at three different speeds Throttle device, in particular with one between the piston and the inner wall of the cylinder arranged soft seal or elastic seal.

In such a known embodiment, the throttling takes place in such a way that towards the end of the closing movement, the damping means can flow around unthrottled, so that the wing is pressed into the lock only under the action of the closing spring, switching off the damping. Before the throttling is switched off, a so-called pre-stop takes place, in which the sash is caught regardless of the speed of the start-up and almost comes to a standstill, so that a violent blow when closing is avoided. Furthermore, the Lacre of Vorstops with respect to the opening and s "chließwinkel of the wing is adjustable, so that the strength of the pressing can be changed. The throttle device consists of an axially arranged Umströmrohr which is guided in the interior of the damping piston. This embodiment is expensive and prone to failure due to the necessary sealing effort. Furthermore, the regulating elements for the damping can be adjusted in the direction of the cylinder axis. Due to the different door widths, however, these constructions are difficult to access for the regulation.

A telescopic closer with hydraulic damping is also known, in which the damping is regulated by a flow pipe immersed in the piston and its piston has an elastic seal. This normally open contact is however, the closing speed cannot be regulated in three stages.

It is also known for door closers, the closing speed to be regulated in that an axially slidably mounted valve is arranged in the piston is, which cooperates with an axially adjustable stop at the end of the closing movement and releases a flow cross-section for the damping means.

In contrast, the invention is based on the object of improving a telescopic closer of the type mentioned in such a way that a simple, interference-insensitive design of the throttle and the piston seal is created, which is independent of manufacturing tolerances and which at the same time stuck to the usual with this type of door closer Contributes to the design with a small footprint.

This is achieved according to the invention in that the throttle device consists of a control slide which is slidably mounted in the piston aixal and which passes through a spring is secured in its position and with a means in the cylinder end piece an adjusting device arranged to be longitudinally displaceable at the end of the closing movement cooperates, one after the other due to the axial displaceability of the control slide at least three throttle cross-sections for the damping fluid are released.

This creates a door closer with the smallest closer dimensions Has a minimum of construction effort and finely machined parts.

The regulation of the throttle cross-sections can be done, for example, by means of cross bores, Turns or flats in the control slide in cooperation with the corresponding Parts of the inner wall of the piston take place. According to a preferred embodiment according to Invention are the throttle cross-sections through chord-like flattened areas in the cylinder jacket of the control slide formed with a corresponding collar in the inner wall of the piston cooperate.

The longitudinal adjustability of the stop for the control slide can be achieved by a screw, worm, cone, eccentric, rack, piston or spindle drive that can be actuated perpendicular to the cylinder axis. According to a further feature of the invention, a screw with a conical tip which can be actuated perpendicular to the cylinder axis and through which the stop is longitudinally adjustable against the action of a return spring is used as a preferred embodiment of the adjusting device for the stop.

This results in a further advantage that the door closer can be used for all door widths, since the adjustment elements do not have to extend to the front edge of the door leaf, but are easily accessible through a hole in the upper edge of the leaf. - An embodiment of the subject invention is illustrated in the drawing, Figure 1 shows a longitudinal section through the door closer, Figure 2 is a control slide, in a perspective viewing, Fig 3, 4 and 5, different positions of the control slide....

In a cylinder 1 , a pressure piston 2 with control members is mounted on a piston rod 3 so as to be axially displaceable. The piston rod 3 is guided to the outside through a seal 4 and is hinged to the stationary frame, while the cylinder 1 is attached to the door leaf. When the door leaf is opened, the piston rod 3 and thus the piston 2 is moved in the direction of the arrow against the action of a closing spring 5 relative to the cylinder 1 . The damping agent flows through valves 6, for example ball valves, arranged in the piston 2, from the left to the right side of the piston. After releasing the wing, the closing spring 5 moves the piston 2 and the piston rod 3 relative to the cylinder 1 against the direction of the arrow; the valves 6 close in the process.

In the piston 2, a control slide 7 according to FIG. 2 is arranged to be axially displaceable. The control slide 7 is held in the stop position shown in FIG. 1 by a spring 8. As a result of an axial bore 9 , the same pressure conditions prevail on both sides of the control slide. During most of the piston stroke, the control slide 7 allows the damping means to move from the right side of the piston to the left through a gap formed by a chord-like flattening 10 of the control slide 7 and a collar 11 of the piston 2. From there, the damping agent flows on through flow transfer channels 12, 13 in the piston 2 to the left side of the piston (cf. FIG. 3). Towards the end of the closing movement, the control slide 7 runs against an adjustable stop 14 in the cylinder end piece 15, which is under the pressure of a spring 14 ', until a smaller flat 10' in the front part 16 of the control slide 7 and the collar 11 of the piston 2 coincide. As a result, the inlet in the flow passage 12, 13 is reduced to a minimum (cf. FIG. 4), thus achieving the greatest damping and absorbing the momentum of the door leaf (preliminary stop).

The wing moves only very slowly until the part 16 of the control slide 7 has passed over the collar 11 of the piston 2 (see FIG. 5). A relatively large annular gap is now created between the collar 11 and the tapered part 17 of the control slide 7 , which unthrottled releases the rest of the damping fluid from the right-hand side of the piston 2 to the left-hand side. In this way, the last part of the closing movement is undamped, and the wing is pressed into the lock solely under the action of the spring 3, possibly supplemented by the kinetic energy of the wing which is set again.

As a result of the adjustability of the stop 14, the beginning of the greatest damping and the cancellation of the damping relatively far before the closed position of the sash, provided that the stop is far enough to the left is set. However, the beginning of the greatest attenuation can only be quite a bit start just before the sash is in the closed position or be switched off completely, so that the wing in special cases in the area of the greatest damping, possibly even before that, falls into the lock.

The axial adjustment of the stop 14 takes place by means of a screw 18 with a conical end that is movable perpendicular to the piston axis, as shown in FIG. 1 . But worm drives, eccentric drives, rack and pinion drives, cam drives or spindle drives can also be provided. The backward movement of the stop is ensured by a spring.

The different throttle cross sections which are obtained in the embodiment by chordal flats 10, 10 'in the control slide 7 may also by means of transverse bores in the control slide 7 or turned grooves can be achieved, so that all the cross sections are formed by different annular gaps. The first version has described JE but the advantage of continuous self-cleaning with respect to oil depositions and good command of the necessary tolerances. The sealing cross-sections of the control slide 7 are finely machined and made without the use of elastic seals or soft seals, but there is the possibility of using such seals.

Claims (3)

PATENT A NSPRÜCH E. 1. Telescopic closer for the leaves of doors with a hydraulic damping device, consisting of a cylinder, a piston with a piston rod protruding from the cylinder, a closing spring which is supported against the cylinder and the piston and an adjustable closing spring, the closing movement in three different speeds regulating throttle device, in particular with a between piston and cylinder inner wall arranged soft seal or resilient seal, characterized in that the throttle device consists of an axially slidably mounted in the piston (2) control slide (7) by a spring (8) in its Position is secured and which interacts with a stop (14) arranged in the cylinder end piece (15) so as to be longitudinally displaceable by means of an adjusting device at the end of the closing movement, with at least three throttle cross-sections for the damping fluid in succession due to the axial displaceability of the control slide (7) t be released. 2. Telescopic closer according to spoke 1, characterized in that the throttle cross-sections are formed by chord-like flats (10, 10 ') in the cylinder jacket of the control slide (7) , which cooperate with a corresponding collar (11) in the inner wall of the piston (2). 3. Telescopic closer according to claim 1 or 2, characterized in that the adjusting device for the stop (14) consists of a screw (18) with a conical tip which can be actuated perpendicular to the cylinder axis and through which the stop (14) counteracts the action of a return spring ( 14 ') is adjustable lengthways. Considered publications: German Patent Nos. 207 033, 845 174; German Auslegeschrift No. 1038 886-Austrian Patent No. 208 259; British Patent No. 748,770; USA. Pat. No. 1,021,803.