EP3284897A1 - Seal with a movable sealing strip and a reset and/or excess movement mechanism - Google Patents

Abstract

A seal having a sealing strip, a trigger, a sliding part, which is at least indirectly connected to the trigger, and a return mechanism and / or overstroke mechanism, wherein at least one of these mechanisms comprises a spring means, wherein the at least one mechanism comprises a holder for the spring means, the a rod-like portion which passes through the spring means and has a portion guided in a guide structure of the slide member.

Description

The present invention relates to a seal with a sealing strip, a trigger, a sliding part, which is at least indirectly connected to the trigger, and a return mechanism and / or overstroke mechanism, wherein at least one of these mechanisms comprises a spring means.

From the document DE 60 2004 009 845 T2 For example, a seal having a return mechanism and two overstroke mechanisms is known which comprises coil springs as spring means. In addition, the seal also has two scissor mechanisms, which implement a horizontal movement of the trigger of a seal inserted into a groove at the lower end of the door leaf due to a force acting on the trigger in a lowering movement of the sealing strip.

The in the document DE 60 2004 009 845 T2 described seal has one of its trigger to the return mechanism continuous trigger rod. The shear mechanisms are coupled with these release rods via the overload mechanisms. The return mechanism causes in the event of relief of the trigger of the force lifting the sealing strip.

In the document DE 60 200 009 845 T2 For example, the function of the overload mechanisms for protecting the gasket in a case of blockage of the gasket in paragraph [0040] of the gasket is described.

At the seal from the document DE 60 200 009 845 T2 The reset mechanism, but also the scissors mechanisms are supported on an inner housing. The inner housing is referred to in the document as a movement module section. This inner housing is firmly connected to an outer housing and extends over the entire length of the seal. The outer housing is referred to in the document as a housing section.

The seal has some disadvantages.

A disadvantage of the seal is that the coil springs of the return mechanism and the overload mechanisms are penetrated by the release rod. This necessitates that the trigger bar be shaped so that it is possible to mount all of the coil springs on the trigger bar and slide them on the trigger bar until they reach the intended position. In order for this to be possible, the release rod must be shaped in such a way that the insertion and displacement of the coil springs, that is, their assembly, is possible. Protruding structures that hinder the attachment or displacement of the coil springs must not be provided.

This is where the invention starts.

The invention is intended to solve the problem of enabling easy assembly of the spring means of the return mechanism and / or an overload mechanism.

This problem is solved in that the at least one mechanism (return mechanism or overload mechanism) comprises a holder for the spring means, which has a rod-like portion passing through the spring means and having a guided portion guided in a guide structure of the slide member.

A spring means may comprise one or more leaf springs, coil springs and / or coil springs. Alternatively, the spring means may be formed as a coil spring, leaf spring or coil spring.

Unlike the one from the document DE 60 200 009 845 T2 known seal the spring means is not arranged on the trigger rod, but on a special holder, which passes through the spring means. This makes it possible to make the release rod freer. It only needs to be taken care that the one or more holders can be arranged on the sliding part.

In a seal according to the invention, the rod-like region of the holder can be arranged parallel to a displacement direction of the sliding part. Also, the spring means may extend parallel to the direction of displacement of the sliding part and be compressed in this direction and expand. The return spring means, i. the spring means of the return mechanism, then can absorb and store the force applied to the trigger and provide a release of the trigger for a return movement, without it being necessary to change directions of force. The overload mechanism can absorb excess forces that are needed for neither the compression of the return spring means nor for the movement of the sealing strip, without having to change the direction of force. This makes a simple design of the return mechanism as well as the overload mechanism possible.

The guide structure for the guided region of the holder may be a recess, in particular a blind hole. A wall of the recess may have a slot. The slot can be at least partially taper towards the recess. This allows easy mounting of the holder and the spring means on the sliding part, which will be explained in more detail with reference to FIGS. The slot may have a clear width in the tapered portion that is smaller than the width of the portion of the holder guided in the recess.

The holder of the return mechanism of a seal according to the invention may have a region which has attachment structures, in particular raised or projecting structures, which are fastened to a housing or a module housing of the seal. The raised or projecting structure of the holder of the return mechanism can engage in recesses of the housing or the module housing. The portion of the holder of the return mechanism with the raised or projecting structures may be fork-shaped. The raised or protruding structures may be pins.

The holder of the overstroke mechanism of a seal according to the invention may have an area which is guided in a second guide structure of the sliding part. The second guide structure may be fork-shaped. The fork-like structure may be formed by a rod-like portion of the sliding part and an arm of the sliding part, which is explained in more detail with reference to FIGS.

Fig. 1 und 1a

eine perspektivische Ansicht der erfindungsgemäßen Dichtung in einem nicht ausgelösten Zustand und in einem ausgelösten Zustand,

Fig. 2 und 2a

eine Frontansicht der Dichtung in einem nicht ausgelösten Zustand und in einem ausgelösten Zustand,

Fig. 3 und 3a

eine schlossseitige Ansicht der Dichtung in einem nicht ausgelösten Zustand und in einem ausgelösten Zustand,

Fig. 4 und 4a

eine bandsseitige Ansicht der Dichtung in einem nicht ausgelösten Zustand und in einem ausgelösten Zustand,

Fig. 5 und 5a

einen Schnitt durch die Dichtung in einem nicht ausgelösten Zustand gemäß der Linie V-V in Fig. 2 und in einem ausgelösten Zustand gemäß der Linie Va-Va in Fig. 2a, [Verbindung Halter für Rückstellfeder-Modul]

Fig. 6 und 6a

einen Schnitt durch die Dichtung in einem nicht ausgelösten Zustand gemäß der Linie VI-VI in Fig. 2 und in einem ausgelösten Zustand gemäß der Linie VIa-VIa in Fig. 2, [Verbindung kurzes Scherenbein-Gehäusemodul und Verbindung langes Scherenbein-Halteschiene der Dichtleiste]

Fig. 7 und 7a

eine Frontansicht der Dichtung ohne Gehäuse und ohne Dichtleiste in einem nicht ausgelösten Zustand und in einem ausgelösten Zustand,

Fig. 8 und 8a

eine Frontansicht der Dichtung ohne Gehäuse, ohne Haltemodul und ohne Dichtleiste in einem nicht ausgelösten Zustand und in einem ausgelösten Zustand,

Fig. 9 und 9a

einen vergrößerten Ausschnitt IX aus Fig. 8 bzw. einen vergrößerten Ausschnitt IXa aus Fig. 8a,

Fig. 10 und 10a

einen vergrößerten Ausschnitt X aus Fig. 8. bzw. einen vergrößerten Ausschnitt Xa aus Fig. 8a,

Fig. 11

eine perspektivische Ansicht des Scherenmechanismus,

Fig. 12

eine perspektivische Ansicht eines kurzen Scherenbeins,

Fig. 13

eine perspektivische Ansicht eines langen Scherenbeins,

Fig. 14a und b

Ansichten der Montage des Scherenmechanismus,

Fig. 15a bis d

Frontansichten von einer Einheit aus Verbindungsstangen und Verschiebeelement,

Fig. 16a bis d

Ansichten der vorgenannten Einheit von unten,

Fig. 17

eine Frontansicht eines Halters einer Überlastfeder,

Fig. 18

eine Ansicht des Halters der Überlastfeder von unten,

Fig. 19a und b

Ansichten der Montage des Überlastmechanismus,

Fig. 20a und b

Schnittansichten des montierten Überlastmechanismus

Fig. 21a

eine Variante der erfindungsgemäßen Dichtung in einem nicht ausgelösten Zustand und in einem ausgelösten Zustand,

The holder of the overstroke mechanism of a seal according to the invention may have between the rod-like region, which passes through the spring means, and the region, which is guided in the second guide structure, a region which forms a stop, which limits a movement of the holder of the overload mechanism, and / or forms a support for the spring means. Further features and advantages of a seal according to the invention are described with reference to the accompanying drawings. Show:

Fig. 1 and 1a

a perspective view of the seal according to the invention in a non-triggered state and in a tripped state,

Fig. 2 and 2a

a front view of the seal in an untripped condition and in a tripped condition,

Fig. 3 and 3a

a lock side view of the seal in an untripped condition and in a tripped condition;

4 and 4a

a band side view of the seal in an untripped condition and in a tripped condition;

Fig. 5 and 5a

a section through the seal in a non-triggered state along the line VV in Fig. 2 and in a tripped state according to the line Va-Va in FIG Fig. 2a , [Connection Retainer Spring Module Retainer]

FIGS. 6 and 6a

a section through the seal in a non-triggered state according to the line VI-VI in Fig. 2 and in a tripped state according to the line VIa-VIa in FIG Fig. 2 , [Link short scissor-leg housing module and link long scissor-leg retaining rail of sealing strip]

Fig. 7 and 7a

a front view of the seal without housing and without sealing strip in a non-triggered state and in a tripped state,

Fig. 8 and 8a

a front view of the seal without housing, without holding module and without sealing strip in a non-triggered state and in a tripped state,

Fig. 9 and 9a

an enlarged section IX Fig. 8 or an enlarged section IXa Fig. 8a .

10 and 10a

an enlarged section X from Fig. 8 , or an enlarged section Xa Fig. 8a .

Fig. 11

a perspective view of the scissor mechanism,

Fig. 12

a perspective view of a short scissor leg,

Fig. 13

a perspective view of a long scissor bone,

Fig. 14a and b

Views of the assembly of the scissors mechanism,

Fig. 15a to d

Front views of a unit of connecting rods and displacement element,

Fig. 16a to d

Views of the above unit from below,

Fig. 17

a front view of a holder of an overload spring,

Fig. 18

a view of the holder of the overload spring from below,

Fig. 19a and b

Views of the mounting of the overload mechanism,

Fig. 20a and b

Sectional views of the mounted overload mechanism

Fig. 21a

a variant of the seal according to the invention in an untripped condition and in a triggered condition,

A seal according to the invention has a housing 1, which has a constant cross-sectional profile over its length. In the illustrated example, the housing has substantially the shape of an inverted U with two legs 12 and a connecting web 11 which connects the two legs 12 together. On an inner side of the web 11 of the housing 1, two mirror-image webs 111 are attached. These are slightly undercut on sides 1111 facing each other so that the facing sides 1111 form a throat. The mutually remote sides 1112 of the webs 111 are slightly inclined.

The housing may be secured in a known manner in a groove of a door leaf. The attachment can be done for example by means of mounting brackets, which will come back. The person skilled in the art is familiar with various types of attachment from the prior art, in particular from published patent applications. Depending on the type of attachment, the housing may be modified to include, for example, in the housing channels, lands, screw holes or other to provide what is useful for attaching the seal to a door.

A seal also has a sealing strip. In the example, the sealing strip is made in two parts. However, it could be in one piece or have more than two parts. In principle, any known from the prior art sealing strip can be used. In the example, the sealing strip comprises a rigid retaining profile 13, preferably made of aluminum, and an elastomeric sealing profile 14. Both have in the example over their length a constant cross-sectional profile. In the example, the retaining profile 13 as well as the sealing profile in cross section is substantially U-shaped. The retaining profile 13 as well as the sealing profile 14 each have a connecting web 131, 141 and two legs 132, 142, which are connected to each other via the connecting web 131, 142.

The sealing profile 14 is fastened via detent webs 143 in detent channels 133 of the retaining profile 13.

On the inside of the legs 132 of the retaining profile 13, two webs 134 are provided, which together with the connecting web 131 form channels whose purpose will be explained in more detail.

In the seal, two modules Ma, Mb are arranged, which in the exemplary embodiment comprise all parts which serve for a safe movement of the sealing strip relative to the housing.

The parts of the gasket, which belong to the modules Ma, Mb, can be found partly identical in both modules. These parts can then be used in the modules Ma, Mb for the same functions of the modules Ma, Mb. In part, the modules Ma, Mb also have special features that make special parts necessary. Functions the In the example, the first module has, can be perceived in another embodiment of a seal according to the invention of the second module and vice versa. It is therefore within the scope of the invention to modify the parts of the modules Ma, Mb in such a way that, if appropriate, they can also take on fewer, different or additional functions.

Identical or functionally similar parts of the modules Ma, Mb have reference numbers with the same numbers and differ by the attached letters a and b, where a stands for parts of the first module and b for parts of the second module. If details of the parts of the modules Ma, Mb are discussed, they will be referred to without attached letters if they are found in the parts of both modules Ma, Mb.

In the example, both modules Ma, Mb of the seal according to the invention have the function to connect the sealing strip and the housing and implement the movement of the trigger 16 in a movement of the sealing strip relative to the housing 1 in a release of the seal by pressing a trigger 16. For this purpose, each module Ma, Mb has a scissors mechanism Sa, Sb. In order to protect this scissors mechanism Sa, Sb of each module Ma, Mb in a so-called overload case, each module Ma, Mb also has an overload mechanism Ua, Ub.

The modules Ma, Mb can be placed in a housing 1 at the option of a person skilled in the art. But it is also possible that a seal according to the invention has no housing and the modules are placed directly in a groove of a door. It is possible to design a gasket to have only one module.

The first module Ma comprises a module housing 2a. This has a substantially constant cross-sectional profile in the form of an inverted U. It has a connecting web 21 which connects two legs 22 of the module housing 2a. On the inner sides of the legs 22 webs 221 are attached. These form together with the connecting web 21 channels whose function will be explained.

The connecting web 21 projects beyond the outer sides of the legs 22. These projecting ends 211 of the connecting web are designed such that they form a fit with the grooves on the mutually facing sides 1111 of the webs 111 of the housing 1. In particular, the fit can form a clearance fit with little play. The module housing 2a is inserted with the ends 211 in the grooves on the mutually facing sides 1111 of the webs 111 of the housing 1 and so fixed in the housing at least positively. For example, complete fixation may be achieved by at least selective deformation of the webs 111 of the housing inwardly, i. take place against the ends 211 or the legs 22. Parts of the webs 111 can thereby be pressed against the ends 211 or legs 22, so that at least one frictional connection is made.

On the other hand, missing in a range at the trigger side end of the module housing of the connecting web 21. The absence of the connecting web at the trigger end of the module housing 2a has its reason that due to the absence of the connecting web 21 on the trigger side end of the module housing 2a space is created to insert a mounting bracket in the housing 1.

In a region remote from the trigger of the module housing 2a of the first module Ma, two opposing holes are provided in the legs 22 directly adjacent to the webs 221. Corresponding holes are also provided in the module housing 2b of the second module Mb. In these holes, pins 71 of a short scissor element 7a are rotatably arranged. These pins 71 are also on the underside of the webs 221, whereby the pins 71 are supported at a load in the direction of the webs 221 and protected against shearing.

The short scissors element 7a of the first module Ma - it is identical to the short scissors element 7b of the second module Mb - is substantially H-shaped. It has a connecting web 72, from which two arms 73 and two legs 74 extend. At the ends of the arms 73, which are slightly shorter than the legs 74, are the outwardly projecting pins 71, the function of which has already been explained. The ends of the arms 73 abut on the webs 221, which supports the arms 73 under load in the direction of the webs 221. A load of the short scissor element 7a - and thus the pin 71 and the arms 73 - can arise when pressing the sealing strip to a floor when lowering or lowered sealing strip.

On the legs 74, two inwardly projecting pins 75 are provided, which serve to connect to a long scissor element 6a.

The long shearing element 6a of the first module Ma - it is identical to a long scissor element 6b of the second module Mb - can be divided into two sections, namely a first portion 61 which forms a frame, and a second portion 62, which is a rod forms. The two sections 61, 62 are connected. In the region of the connection, the second section 62 of the long scissor element 6a has two blind holes which are open towards the outside. In these blind holes, the inwardly projecting pin 75 of the short scissor element 7a are inserted. As a result, the long and the short scissors element 6a, 7a are pivotally connected to each other.

The inserted into the blind holes pin 75 and the ends of the legs 74 abut against bearing shells 611, which are formed on the first portion 61 in the region of the connection of the first portion 61 with the second portion 62. This makes it possible to transmit greater forces into the long scissor element 6a via the pins 75 or legs 74 than when the bearing shells were missing.

The second portion 62 of the long scissor element 6a has a tapered region 621 from the blind holes toward the free end of the second portion 62. This conical taper of the second portion 62 facilitates the assembly of the short scissor element 7a on the long scissor element 6a. To this end, the inwardly projecting pins 75 of the short scissor element can be placed on the second section 62 at the most tapered end of the taper so that the pins lie on both sides of the second section. From this end of the taper, the pins 75 can then be pushed in the direction of the blind holes. The pins 75 are bent apart until they finally engage in the blind holes.

The free end of the first section 61 or the opening present in this first section 61 serves to guide and support the long scissors element 6a, which will be explained in more detail. This free end is movable to the module housing 2a.

At the free end of the second portion 62 of the long scissor element, two outwardly projecting pins 63 are provided, which serve to connect the long scissors element 6a to the retaining profile 13. The pins 63 are movably guided and supported in the channels formed by the webs 134 and the connecting web 131 of the holding profile 13.

The second portion 62 of the long scissor element 6a has a width which is not greater than the distance of the legs 74 of the short scissor element 7a. Thus, it is possible that the second portion 62 is submerged between the legs 74, for example, when the seal is not triggered.

The long scissor element 6a and the short scissor element 7a together form a first scissor mechanism Sa of the first module Ma, which is also present as a second scissor mechanism Sb formed by the long scissor element 6b and the short scissor element 7b in the second module.

The first module Ma has a displacement part 3a. This sliding part has a flat, rod-like portion 31 which extends over the entire length of the sliding part 3a. This flat, rod-like portion 31 has approximately the shape of a T. Two protruding edges 311 of the rod-like portion 31 protrude into the channels, which are formed by the webs 221 and the connecting web 21 of the module housing 2a. The edges 311 and thus the entire displacement part 3a are slidably guided in the channels.

On an underside of the bar-like portion 31, three different structures 32, 33a, 34a are provided.

The structure 32 at a trigger-side end of the slide member 3a serves as a first connection structure provided for connecting the slide member 3a of the first module Ma to a first link rod 8. Furthermore, the structure 32 is part of the overload mechanism of the first module Ma.

The structure 33 cooperates with the scissor mechanism Sa of the first module and is a part of the overload mechanism of the first module Ma.

The structure 34 is a second connection structure that serves to connect the displacement part 3a of the first module Ma to a second connection rod 9.

The first as well as the second connection structure 32, 34 are designed such that both tensile forces and compressive forces can be transmitted via the connection structures 32, 34.

The structure 33 has an arm 331 extending toward the trigger-side end, which extends parallel to the rod-like portion 31 of the slide part 3a. This arm 331 passes through the opening in the first section 61 of the long scissor element 6a of the scissors mechanism Sa of the first module Ma. A free end 612 of the first portion 61 is thereby supported and guided between the arm 331 and the rod-like portion 31 of the sliding part 3a.

The free end 612 is held by a holder 4a for an overload spring 5a and the overload spring 5a of the first module Ma in a position between the arm 331 and the rod-like portion 31 of the slide member 3a. The overload spring 5a is around a helical compression spring. The holder 4a for the overload spring is rod-like.

It can be in the holder roughly four areas 41, 42, 43, 44 distinguished.

A first portion 41 is configured to be guided between the arm 331 and the rod-like portion 31 of the slide member 3a. For this purpose, the first region 41 of the holder 4a has on a lower side a channel in which a web 3311 engages, which is provided on the upper side of the arm 331. A free end 411 of the first portion 41 has a throat and forms a bearing cup for the free end 612 of the first portion 61 of the long scissor element 6a.

A second region 42, which has a larger cross-sectional area than the first region 41, adjoins this first region. This second region 42 forms a stop on the one hand, and a first end of the overload spring 5a, on the other hand, is supported on this second region is stuck on the third rod-like portion 43 of the holder 4a. A second end of the overload spring 5a is supported on the structure 32 of the sliding part 3a. The overload spring 5a pushes the holder and in particular the first portion 41 of the holder against the structure 33 of the sliding part. Thereby, the free end 612 of the first portion of the long scissor element 6a is held between the arm 331 and the rod-like portion 31. The abutment function of the second region 42 of the holder 4a ensures that the overload spring 5a does not press the free end 612 of the first section 61 of the long scissor element 6a against the structure 33, which could impair a slight pivoting of the long scissor element. The length of the first region 41 of the holder 4a is chosen so that the free end 612 of the first portion 61 of the long scissor element 6a is supported at least with slight play between the structure 33 and the first region 41 of the holder 4a.

The third area 43 of the holder 4a is adjoined by a fourth area 44. This fourth region 44 is guided in a blind hole in the structure 32. A lower boundary wall 321 of the blind hole has a downwardly open slot. This slot is from bottom to top, i. from the outside in the direction of the blind hole, rejuvenated. This makes it possible to press the fourth portion 44 of the holder 4a from below through the slot in the blind hole. The slot is widened elastically. The fourth region 44 of the holder 4a can not be easily removed from the blind hole through the slot or fall out.

The second module Mb also comprises a module housing 2b. The module housing 2b of the second module Mb has the same cross-sectional profile as the module housing 2a of the first module. It is essentially different in length. The module housing 2b of the second module Mb is longer than the module housing 2a of the first module Ma. This extra length is needed to accommodate a return mechanism R.

The return mechanism R serves to return the seal from a tripped condition to an untripped condition when the triggering force is removed from the trigger 16.

The second module Mb, like the first module Ma, has a displacement part 3b. This sliding part has a flat, rod-like portion 31 which extends over the entire length of the sliding part 3 a and the cross section of which the corresponding section 31 of the sliding part of the first module corresponds.

The flat, bar-like portion 31 carries on its underside three structures 32, 33b, 34b.

The structure 32 at a trigger side end of the slide member 3b serves as a first connection structure provided for connecting the slide member 3b of the second module Mb to the second link rod 9. Furthermore, the structure 32 is part of the overload mechanism of the first module Ma. The structure is identical to the corresponding structure 32 of the displacement part 3a of the first module Ma.

The structure 33b cooperates with the scissors mechanism Sb of the second module Mb and forms part of the overload mechanism Ub of the second module Mb. In addition, it forms part of the return mechanism R.
The structure 34b serves as part of the return mechanism.

The structure 34b could also serve as a second connection structure, which could serve to connect the displacement part 3b of the second module Mb with another connecting rod 9, which is not provided in the exemplary embodiment.

The overload mechanism Ub of the second module Mb is designed in the same way as the overload mechanism Ua of the first module Ma.

Also, the scissor mechanism Sb of the second module Mb is designed in the same way as the scissor mechanism Sa of the first module.

The return mechanism R comprises in addition to the structures 33b and 34b mentioned a holder 10 for a return spring 11 and the return spring 15 as return spring means. The holder 10 has a first fork-shaped portion 101, which has two pins 1011 on its outer sides. These pins 1011 are inserted into holes in the module housing 2b of the second module Mb. As a result, the holder 10 with respect to the module housing 2b is immovable.

At this first region 101, a second region 102 connects, on which the return spring 11 is attached. The return spring 11 is a helical compression spring.

The third area is adjoined by a third area 103. This third area is guided in a blind hole of the structure 33b of the displacement part 3b. A lower boundary wall 331 of the blind hole has a downwardly open slot. This slot is from bottom to top, i. from the outside in the direction of the blind hole, rejuvenated. This makes it possible to press the third portion 103 of the holder 10 from below through the slot in the blind hole. The slot is widened elastically. The third region 103 of the holder 10 can not be easily removed from the blind hole through the slot or fall out. As a result, the position of the return spring is secured in the seal.

The connections between the trigger 16, the first connecting rod 8, the sliding part 3a of the first module Ma, the second connecting rod 9 and the sliding part 3b of the second module Mb are loaded both upon release and upon return to pressure, on the one hand by the pressure, which is exerted on the trigger 12 and the other by the pressure exerted by the return spring 15.

By the movement of the unit of the trigger 16, the first connecting rod 8, the sliding part 3a of the first module Ma, the second connecting rod 9 and the sliding part 3b of the second module Mb and the holders 4a, 4b for the overload springs, the free ends 612 of long scissors elements 6a, 6b with moves. As a result, these ends 612 are displaced relative to the housing 1 and the module housings 2a, 2b and the pins 71 of the short scissor elements 7a, 7b mounted pivotably therein. The scissor mechanisms Sa, Sb open and the sealing strip is thereby displaced downwards.

If, for whatever reason, the sealing strip is prevented from a complete downward movement, the or possibly one of the overload mechanisms Ua, Ub becomes effective. If the sealing strip is prevented from (further) downward movement, the scissor mechanisms Sa, Sb can not open any further. The free ends 612 of the long scissors elements 6a, 6b can then not be displaced together with the unit of the trigger 16, the first connecting rod 8, the displacing part 3a of the first module Ma, the second connecting rod 9 and the displacing part 3b of the second module Mb. A despite the stoppage of the sealing strip further taking place movement of the unit of the trigger 16, the first connecting rod 8, the sliding part 3a of the first module Ma, the second connecting rod 9 and the displacement part 3b of the second module Mb then causes the free ends 612 of long scissor elements 6a, 6b press against the holders 4a, 4b for the overload springs 5a, 5b and these are displaced in the direction of the trigger 16. As a result, the overload springs 5a, 5b are compressed.

Advantageously, the way by which the free ends 612 against the overload spring 5a, 5b can be moved as long as the way the unit of the trigger 16, the first connecting rod 8, the sliding part 3a of the first module Ma, the second connecting rod 9 and the sliding part 3b of the second module Mb can be moved. The scissor mechanisms Sa, Sb are then protected against damage due to overload.

1

Gehäuse

2a

Modulgehäuse des ersten Moduls

2b

Modulgehäuse des zweiten Moduls

3a

Verschiebeteil des ersten Moduls

3b

Verschiebeteil des zweiten Moduls

4a

Halter für die Überlastfeder des ersten Moduls

4b

Halter für die Überlastfeder des zweiten Moduls

5a

Überlastfeder des ersten Moduls

5b

Überlastfeder des zweiten Moduls

6a

langes Scherenelement des Scherenmechanismus des ersten Moduls

6b

langes Scherenelement des Scherenmechanismus des zweiten Moduls

7a

kurzes Scherenelement des Scherenmechanismus des ersten Moduls

7b

kurzes Scherenelement des Scherenmechanismus des zweiten Moduls

8

erste Verbindungsstange

9

zweite Verbindungsstange

10

Halter für die Rückstellfeder

13

Halteprofil

14

Dichtungsprofil

15

Rückstellfeder

16

Auslöser

Ma

erstes Modul

Mb

zweites Modul

Sa

Scherenmechanismus des ersten Moduls

Sb

Scherenmechanismus des zweiten Moduls

Ua

Überlastmechanismus

Ub

Überlastmechanismus

R

Rückstellmechanismus

When in the Fig. 21a , b illustrated inventive variant of the embodiment described above, the return mechanism R is not provided in the second module Mb, but in the first module Ma. This has the advantage that the scissors mechanism Sb could be arranged at the trigger-remote end of the seal. This can provide for a stronger pressure of the sealing strip on the trigger remote end, which may be particularly important for the Schlagregedichtigkeit the seal of importance.

1

casing

2a

Module housing of the first module

2 B

Module housing of the second module

3a

Shifting part of the first module

3b

Shifting part of the second module

4a

Holder for the overload spring of the first module

4b

Holder for the overload spring of the second module

5a

Overload spring of the first module

5b

Overload spring of the second module

6a

long scissor element of the scissors mechanism of the first module

6b

long scissor element of the scissors mechanism of the second module

7a

short scissor element of the scissors mechanism of the first module

7b

short scissor element of the scissors mechanism of the second module

8th

first connecting rod

9

second connecting rod

10

Holder for the return spring

13

retaining profile

14

weatherstrip

15

Return spring

16

trigger

Ma

first module

mb

second module

Sat.

Scissors mechanism of the first module

sb

Scissors mechanism of the second module

Ua

Overload mechanism

ub

Overload mechanism

R

Reset mechanism

Claims (11)

A seal having a sealing strip, a trigger, a displacement part, which is at least indirectly connected to the trigger, and a return mechanism and / or overstroke mechanism, wherein at least one of these mechanisms comprises a spring means,
characterized,
in that the at least one mechanism has a holder for the spring means, which has a rod-like region, which passes through the spring means and has a region which is guided in a guide structure of the displacement part. Seal according to claim 1, characterized in that the rod-like portion of the holder and / or the spring means is arranged parallel to a displacement direction of the sliding part. Seal according to one of claims 1 to 2, characterized in that the guide structure is a recess, in particular a blind hole. Seal according to claim 3, characterized in that a wall of the recess has a slot. Seal according to claim 4, characterized in that the slot tapers at least in sections in the direction of the recess. Seal according to claim 5, characterized in that the slot in the tapered portion or a clear width has, which is smaller than the width of the guided in the recess portion of the holder. Seal according to one of claims 1 to 6, characterized in that the holder of the return mechanism has a region having attachment structures, in particular raised or projecting structures which are fixed to a housing or a module housing. Seal according to claim 7, characterized in that the raised or projecting structure of the holder of the return mechanism engage in recesses of the housing or the module housing. Seal according to one of claims 1 to 8, characterized in that the holder of the over-stroke mechanism has a region which is guided in a second guide structure of the sliding part. Seal according to claim 9, characterized in that the second guide structure is fork-shaped. A seal according to claim 9 or 10, characterized in that the holder of the overstroke mechanism has between the rod-like region, which passes through the spring means, and the region, which is guided in the second guide structure, a region which forms a stop, which is a movement of the Holder of the overload mechanism limited, and / or forms a support for the spring means.

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