EP3335593A1 - Energy accumulator for a fitting and fitting with an energy accumulator - Google Patents

Abstract

The invention relates to a force accumulator for a fitting, in particular for furniture, in particular for a connection or functional fitting, characterized by a design as a spiral spring arrangement, wherein the spiral spring arrangement has at least one spring core (32).

Description

The invention relates to a power storage for a furniture fitting and a fitting with such a power storage.

The DE 10 2010 060 722 A1 discloses a locking fitting for furniture with a locking device which is arranged on the frame and a corresponding connection fitting to a furniture panel, in particular on a front panel, which is zoomed in with a catch lever, which acts on the power storage, to the front panel. The disclosed energy storage is designed as a spring arrangement. Especially with narrow frames, however, the space is often limited, which complicates the use of compression or tension springs.

The invention has the object to provide a power storage for a fitting, in particular a furniture fitting, as well as a fitting with such a force storage, which is versatile and has a compact design against this background.

The invention solves this problem by the subject matter of claims 1 and 20.

Claim 1 provides a force accumulator, which is designed as a spiral spring arrangement. Such a spiral spring arrangement is widely used and produces particularly well and simply a sufficiently large spring force for actuating a fitting, in particular a furniture fitting, preferably a functional or connection fitting.

The energy storage is suitable for fittings of various kinds. The preferred - but not exclusive - field of application of the energy storage is the furniture industry. Here it is suitable as an energy store, which forms part of an actuating device or holding device, so on front and rear wall connections and / or cabinet and / or shelf hangers and / or as a rack connection of a pullout guide.

It is advantageous if the bending spring of the energy accumulator has at least one, two or more longitudinal limbs and at least one spring housing into which In any case, this or these longitudinal limbs engage or engage over part of their length. This spring housing can be designed according to the invention in various ways. In this case, in particular, a relatively flat housing shape is advantageous, it being possible for projections to protrude from the housing, which allow the bending spring to be coupled with a fitting in a simple manner. The spring housing can be formed in one or more parts. Preferably - but not necessarily - it is inexpensive plastic. The bending spring, however, is preferably made of a metal wire, in particular a steel wire

According to another preferred - as compact and structurally simple - design, the bending spring may be formed as U- or V-shaped bending spring and having two of the longitudinal legs, which are connected to each other directly or indirectly.

According to a variant, the at least two longitudinal limbs are connected to each other directly via at least one bend. According to another variant, the at least two longitudinal limbs, however, are indirectly connected to one another via the spring housing.

It is also advantageous that the bending spring has at least one spring core. This can -must not Naber - be formed on the spring housing, in particular such that the spring core has a straight or curved outer contour on which the one or more longitudinal limbs are supported in the stressed state of the longitudinal leg at least over part of their length.

The advantage of the spring core is to guide the spiral spring and to allow a very good bias, preferably a nearly maximum, bias of the spiral spring. Wire bending springs require only a small space, since the wire is only in one plane, but these springs have a rather lower energy absorption potential. This is due to the fact that these springs are loaded unevenly over the length. In the area of a deflection, the highest stresses occur in the spring, the max. permissible stress is exceeded, a permanent deformation occurs. This limits the energy intake.

It is therefore advantageous if the spiral spring arrangement hangs up during clamping on a spring core, which in turn preferably the min. can correspond to a sustainable bending radius. As a result, allowable stresses in the spring over the entire spring length occur. This significantly increases the energy absorption of the spring. The advantage is to store a large amount of energy in a narrow, short space around a mechanism, e.g. a catch mechanism to operate a fitting.

According to a further advantageous variant of the energy accumulator, it is provided that the spiral spring has a V-shaped or U-shaped spiral spring with at least one, two or more longitudinal limbs, in any case in a tensioned state. In this case, the one or more longitudinal limbs may have a straight or curved shape in the relaxed state. Accordingly, the spring core may be formed as a straight or curved web in the spring housing.

According to an advantageous variant, these longitudinal limbs are placed in sections on or around the at least one spring core, which serves as a spring amplifier. This may be formed as a curved or straight web of the spring housing. But it is also conceivable that the spring core is formed from each other supporting longitudinal limbs of the spiral spring itself.

With regard to a compact design of the spring housing, it is advantageous if according to a variant on the spring housing laterally two parallel walls are formed, between which a slot is formed, in which einliegen the longitudinal leg over a portion of its length.

It is also advantageous if one or more free ends of the longitudinal limb or the longitudinal limbs protrude / protrude from the spring housing as approach or lugs, which are then preferably directly usable as interfaces to a fitting. It is optionally or alternatively conceivable that the spring housing itself has a lug which can be used as an interface to a fitting. The invention also provides a fitting, in particular connection fitting for furniture, with at least one energy accumulator or more force accumulators according to one of the preceding claims. To mention are as suitable fittings in addition to locking devices on furniture, for example, functional fittings, such as intake or ejection devices on pull-out or swivel fittings, the use as energy storage in particular swivel fittings and generally the use of fittings, especially furniture knocks, where a compact, slim force storage arrangement are used should.

Further advantageous embodiments of the invention can be found in the dependent claims.

Fig. 1:

eine räumliche Ansicht eines Kastenmöbels mit drei Schubkästen, die sich in einem geschlossenen Zustand befinden;

Fig. 2

eine perspektivische Ansicht eines Teils eines Schubkastens für ein Kastenmöbel nach Art der Fig. 1, mit einem Boden, einer Zarge und einer Rückwand und einem in die Zarge eingesetzten Blenden-Arretierbeschlag;

Fig. 3

eine perspektivische Ansicht der Zarge aus Fig. 2 mit einem Blenden-Arretierbeschlag;

Fig. 4

eine perspektivische Ansicht des Blenden-Arretierbeschlags aus Fig.2 und 3 an einem Zargenadapter,

Fig. 5

eine Explosionsansicht der Anordnung aus Fig. 4;

Fig. 6

eine Seitenansicht der Anordnung aus Fig. 4 vor bzw. bei einem beginnenden Ansetzen eines Verbindungsbeschlags für eine Frontblende an eine Arretiervorrichtung des Blenden-Arretierbeschlags, wobei eine Basisplatte ausgeblendet worden ist;

Fig. 7a, b, c

in a) und b) um 180° zueinander gedrehte Seitenansichten der Anordnung aus Fig. 6 in einem im Vergleich zu Fig. 6 etwas späteren Stadiums des Ansetzens des Verbindungsbeschlags an die Arretiervorrichtung;

Fig. 8a, b

in a) und b) um 180° zueinander gedrehte Seitenansichten der Anordnung aus Fig. 7 in einem im Vergleich zu Fig. 7 wiederum späteren Stadiums des Ansetzens des Verbindungsbeschlags an die Arretiervorrichtung, wobei von letzterem nur ein Bolzen dargestellt ist;

Fig. 9a, b

in a) und b) um 180° zueinander gedrehte Seitenansichten der Anordnung aus Fig. 8 in einem im Vergleich zu Fig. 8 wiederum späteren Stadiums des Ansetzens des Verbindungsbeschlags an die Arretiervorrichtung, wobei von letzterem nur ein Bolzen dargestellt ist;

Fig. 10a, b

in a) und b) um 180° zueinander gedrehte Seitenansichten der Anordnung aus Fig. 9 mit vollständig an die Arretiervorrichtung angesetzten und dort verriegelten Verbindungsbeschlag, wobei von letzterem nur ein Bolzen dargestellt ist;

Fig. 11

eine perspektivische Ansicht eines weiteren Blenden-Arretierbeschlags,

Fig. 12

eine Explosionsansicht der Anordnung aus Fig. 11;

Fig. 13

eine Seitenansicht der Anordnung aus Fig. 11 vor bzw. bei einem beginnenden Ansetzen eines Verbindungsbeschlags für eine Frontblende an eine Arretiervorrichtung des Blenden-Arretierbeschlags;

Fig. 14a, b

in a) und b) zwei relativ zueinander um 180° zueinander gedrehte Seitenansichten der Anordnung aus Fig. 11, 12 und 13 in einem im Vergleich zu Fig. 13 etwas späteren Stadiums des Ansetzens des Verbindungsbeschlags an die Arretiervorrichtung;

Fig. 15

in a) und b) eine Seitenansicht und eine perspektivische Ansicht der Anordnung aus Fig. 11, 12 und 13 in einem im Vergleich zu Fig. 14a, b etwas späteren Stadiums des Ansetzens des Verbindungsbeschlags an die Arretiervorrichtung, wobei von letzterem in einigen Zeichnungen nur ein Bolzen dargestellt ist; und

Fig. 16

eine Seitenansicht der Anordnung aus Fig. 15 mit vollständig an die Arretiervorrichtung angesetzten und dort verriegelten Verbindungsbeschlag, wobei von letzterem nur ein Bolzen dargestellt ist;

Fig. 17a - c

in a) bis c) verschiedene Ansichten eines dritten Blenden-Arretierbeschlags vor dem Ansetzen des Verbindungsbeschlags an die Arretiervorrichtung;

Fig. 18a, b

in a) und b) zwei relativ zueinander um 180° zueinander gedrehte Seitenansichten der Anordnung aus Fig. 17 in einem im Vergleich zu Fig. 17 etwas späteren Stadium des Ansetzens des Verbindungsbeschlages, wobei von letzterem nur ein Bolzen dargestellt ist;

Fig. 19a, b

in a) und b) zwei relativ zueinander um 180° zueinander gedrehte Seitenansichten der Anordnung aus Fig. 18 mit vollständig an die Arretiervorrichtung angesetzten und dort verriegelten Verbindungsbeschlag, wobei von letzterem nur ein Bolzen dargestellt ist;

Fig. 20a) -e)

verschiedene Ansichten und Teilansichten eines weiteren Ausführungsbeispiels eines Kraftspeichers, in a) bis c) mit entspannter und in d) und e) mit gespannter Biegefeder;

Fig. 21a) - e), Fig. 22 a) - e) und Fig. 23a) - e)

jeweils verschiedene Ansichten und Teilansichten jeweils weiterer Ausführungsbeispiele von Kraftspeichern, in a) bis c) jeweils mit entspannter und in d) und e) jeweils mit gespannter Biegefeder.

The invention will be described in more detail with reference to an embodiment with reference to the drawings. Show it:

Fig. 1:

a three-dimensional view of a box cabinet with three drawers, which are in a closed state;

Fig. 2

a perspective view of a portion of a drawer for a cabinet furniture in the manner of Fig. 1 with a bottom, a frame and a rear wall and an aperture-locking fitting inserted into the frame;

Fig. 3

a perspective view of the frame Fig. 2 with a shutter lock fitting;

Fig. 4

a perspective view of the shutter locking fitting Fig.2 and 3 on a frame adapter,

Fig. 5

an exploded view of the arrangement Fig. 4 ;

Fig. 6

a side view of the arrangement Fig. 4 before or at an initial attachment of a connection fitting for a front panel to a locking device of the visor locking fitting, wherein a base plate has been hidden;

Fig. 7a, b, c

in a) and b) rotated by 180 ° to each other side views of the arrangement Fig. 6 in one compared to Fig. 6 a little later stage the attachment of the connection fitting to the locking device;

Fig. 8a, b

in a) and b) rotated by 180 ° to each other side views of the arrangement Fig. 7 in one compared to Fig. 7 turn later stage of the attachment of the connection fitting to the locking device, the latter being shown only a bolt;

Fig. 9a, b

in a) and b) rotated by 180 ° to each other side views of the arrangement Fig. 8 in one compared to Fig. 8 turn later stage of the attachment of the connection fitting to the locking device, the latter being shown only a bolt;

Fig. 10a, b

in a) and b) rotated by 180 ° to each other side views of the arrangement Fig. 9 with fully attached to the locking device and locked there connection fitting, the latter being shown only a bolt;

Fig. 11

a perspective view of another panel locking fitting,

Fig. 12

an exploded view of the arrangement Fig. 11 ;

Fig. 13

a side view of the arrangement Fig. 11 before or at an initial attachment of a connection fitting for a front panel to a locking device of the shutter locking fitting;

Fig. 14a, b

in a) and b) two relative to each other rotated by 180 ° to each other side views of the arrangement Fig. 11 . 12 and 13 in one compared to Fig. 13 slightly later stage of attaching the connection fitting to the locking device;

Fig. 15

in a) and b) is a side view and a perspective view of the arrangement Fig. 11 . 12 and 13 in one compared to Fig. 14a . b slightly later stage of the attachment of the connection fitting to the locking device, the latter being shown in some drawings only a bolt; and

Fig. 16

a side view of the arrangement Fig. 15 with fully attached to the locking device and locked there connection fitting, the latter being shown only a bolt;

Fig. 17a - c

in a) to c) different views of a third diaphragm locking fitting before attaching the connecting fitting to the locking device;

Fig. 18a, b

in a) and b) two relative to each other rotated by 180 ° to each other side views of the arrangement Fig. 17 in one compared to Fig. 17 slightly later stage of the attachment of the connection fitting, of the latter only a bolt is shown;

Fig. 19a, b

in a) and b) two relative to each other rotated by 180 ° to each other side views of the arrangement Fig. 18 with fully attached to the locking device and locked there connection fitting, the latter being shown only a bolt;

Fig. 20a) -e)

different views and partial views of another embodiment of a force accumulator, in a) to c) with relaxed and in d) and e) with tensioned spiral spring;

Fig. 21a) - e), Fig. 22 a) - e) and Fig. 23a) - e)

each different views and partial views of each further embodiments of force accumulators, in a) to c) each with relaxed and in d) and e) in each case with tensioned spiral spring.

The use of an example of an energy storage device according to the invention on an exemplary furniture fitting will be explained below with reference to the drawings. In addition, the force accumulator used is described in detail and it will some power storage variants are explained, without the following representation of alternative power storage configurations or furniture fittings is to be regarded as complete.

In Fig. 1 is a piece of furniture 1 with a furniture body 2 with side walls 3 shown. In the furniture body 2 are between the side walls 3 more here - purely exemplary three - drawers 4, 5, 6 set by (not shown here) pullout guides are guided displaceable relative to the furniture body 2 on the side walls 3 inside, so that each of the drawers 4, 5, 6 can be pulled out of the furniture body 2 in an open position and back out of this into a closed position.

One or more of the drawers 4, 5 and 6 have (see Fig. 1 and 2 in interaction) preferably a front panel 7a or 7b (here in two different vertical heights) on, two here parallel (side) frames 8 (of which in Fig. 2 one shown), a rear wall 9 and a bottom 10. The in Fig. 2 illustrated drawer 5, the front panel 7a - here a vertically relatively flat front panel - on.

The frame 8 has (see Fig. 2 ) on a main extension direction X. This direction X is also the direction in which the drawer in the furniture body 3 can be inserted and pulled out of this. The after Fig. 1 For this vertical direction is the direction Y - in which the width of the frame 8 is measured - and the other vertical direction in the usual installed position, the direction Z.

The frames 8 - see Fig. 2 and 3 - Are preferably constructed in each case two shells and have an inner shell 11 and an outer shell 12. The inner shell 11 comprises with the outer shell 12 each have a narrow cavity 13. A single-shell construction with a corresponding cavity would also be conceivable.

Preferably, but not necessarily, the outer shell 12 and the inner shell 11 are made of a metal, in particular steel sheets, or of a light metal, in particular of aluminum or an aluminum alloy.

It is further preferred that the outer shell 12 and the inner shell 11 form a very narrow frame 8, the cavity 13 is preferably narrower than 15 mm. Especially with such narrow frames 8, the invention to be explained below can be used advantageously.

The front panels 7a, b are in each case mounted and held on the two frames 8 with at least one diaphragm lock fitting consisting of a connection fitting 15 fastened to the front panel and a locking device 14 arranged and fastened to the frame 8 (FIG. Fig. 4 to 10 ).

In the Fig. 2 shown frame 8 therefore has the in each case Fig. 4 ff or in the Fig. 11 ff pictured locking device 14, which is each designed to first engage behind the connecting bracket 15 on the front panel 7a when attaching the front panel 7a or b to the frame 8, then pull up to the frame 8 zoom and then fixed to this - but again releasable - to keep locked. This is in the Fig. 6 to 10 shown in several consecutive steps.

Since the frame 8 is designed relatively narrow in the Y direction and at least in variants also vertically relatively flat, it is necessary to provide a correspondingly compact designed but still safe and good functioning locking device 14.

This is implemented with the locking device 14 to be described below, which is designed to engage behind the connection fitting 15 and secure it to the frame 8.

First, the connection fitting 15 is briefly considered. The connection fitting 15 has a diaphragm support 16 - see Fig. 5 and 6 - On, with one or more fasteners (not shown here) such as screws on the side facing the frame 8 side of the front panel 7 a can be fastened. At the diaphragm support 16 here are two here in the direction of the frame 8 extending parallel webs 17 are provided, which are connected to each other with a bolt 18, wherein the bolt 18 is spaced from the diaphragm support 16 so that there is a free space between them. Here, the pin 18 is the element to be engaged by the locking device 14.

This embodiment of the connection fitting 15 is preferred, but is not mandatory, but can be varied as long as an engageable by the locking device 14 element on the panel support 16 or the front panel 7a, b itself is provided.

The locking device 14 is attached to a carrier element 19 (FIG. Fig. 4 or 11 ) of the frame 8 attached as an abutment. In this case, the connection fitting 15 is further adjustable with at least one or more adjusting devices 50 from the position (Y and / or Z-direction) relative to the locking device 14, which is advantageous but not mandatory.

The support member 19 is here a Zargenadapter, which is further formed here as a sheet metal part, and which is fixed to the frame 8, for example in the cavity 13, e.g. on the inner shell 11 or the outer shell 12. The support member 19 may also be configured integrally with the frame 8. It serves as an abutment for the locking device 14 on the frame 8.

On the support member 19 is a base body, here a base plate assembly with here two base plates 20, 21, attached. The base plates 20, 21 extend in sections parallel to each other and are spaced from each other. They are angled here at one or more edges. Here are the base plates 20, 21 on both sides of the support member 19 and are fixed to this adjustable with fastening means 22 and the side adjustment 50.

The base plates 20, 21 protrude in the direction of the front panel 7a or in this case of the connection fitting 15 both in sections over the carrier element 19, so that a slot 23 is formed between them ( Fig. 4 ). Instead of two (or even more) base plates 20, 21, the base plate assembly could have only a single base plate or more base plates than two, but the embodiment with two base plates 20, 21 is preferred since the elements to be described are well and safe in them held and managed. The base plates 20, 21 are connected to each other with a fixing means such as rivets or the like (reference numeral 22) to a flat base plate assembly with the slot 23. They are arranged on the support member 19 adjustable according to a variant or fixed by another variant - so not adjustable - positioned.

• einen ein- oder mehrteiligen Auslösehebel 24,
• einen Fanghebel 25, und
• einen Kraftspeicher 26.

In addition to the base plate (s) 20, 21 as the main body, the locking device 14 has three main functional elements arranged on the base plate arrangement at least in a manner that is limitedly movable relative to it:

• a one- or multi-part release lever 24,
• a catch lever 25, and
• an energy storage 26th

The release lever 24 is arranged on the one outer side of the base plate assembly and the catch lever 25 on the other side or between the base plates 20, 21 of the plate assembly in the slot 23. Here is the catch lever 25 in the slot 23. Thus, these levers 24, 25 each rotate and / or translationally move on these pages. They are thus compact in a small space. In the side view - see eg Fig. 7a - Are the trigger lever 24 and the catch lever 25 thus partially overlapping one another.

The force accumulator 26 according to the invention is used for energy storage and release on a fitting, here on the Arretierbeschlag, so on an exemplary furniture fitting. Here, the energy storage device 26 is used to apply force to the release lever 24 and the catch lever 25. It can be configured in various ways, with some preferred and advantageous embodiments below with reference in particular to the Figures 5 and 6 and 20 to 23 will be described.

The energy storage 26 is after 4 to 23 each formed as a spiral spring arrangement. The energy storage 26 as a spiral spring arrangement forms a particularly advantageous designed energy storage 26 for applying force to the locking devices 14, in particular according to the accompanying figures. It is thus advantageous as energy storage device for use on fittings of various kinds, in particular furniture fittings. A spring housing 55 protects the inner parts of a spiral spring 28, which on the one hand are damaged and on which other hand, a fitter or user can virtually not hurt.

The spiral spring arrangement comprises in each case at least one bending spring 28 (see, for example, FIGS Fig. 5 ), here a wire bending spring. The bending spring 28 has one or two or more longitudinal limbs 29, 30. To Fig. 5 the bending spring 28 has a U-shaped basic shape with two longitudinal limbs 29, 30.

The longitudinal legs 29, 30 can be connected to each other via at least one bend 31 (see Fig. 5 and Fig. 6 ). The bending spring 28 is then preferably in one piece. But it is also conceivable that the longitudinal legs 29, 30 are not connected to each other, so that the bending spring 28 is not designed in one piece, but in several pieces. Such an embodiment show the Fig. 20a) to Fig. 20e) , Further such embodiments also show the Fig. 21 and 22 ,

After the variants of Fig. 5 and 6 run the bend 31 and the longitudinal leg or limbs 29, 30 and after the other variants of Fig. 20 to 23 at least one or more longitudinal limbs 29, 30 largely in one plane. This plane runs here parallel to the base plate arrangement - here to the base plates 20, 21 in the X / Z plane. The bending spring 28 is therefore also very compactly housed here parallel to the base plate assembly. It lies substantially on the outside of the base plate assembly parallel to this. This is also after Fig. 20 so realizable.

The two longitudinal legs 29, 30 of the bending spring 28 can be compressed in the Z direction at their free ends 36, 37, whereby the bending spring 28 stores energy which is released by relaxation - i. by moving the longitudinal legs 29, 30 away from each other - can be released again to move in a manner to be described, the release lever 24 and the catch lever 25.

The bending spring 28 is partially placed around a spring core 32 (see Fig. 6 and Fig. 20 ), which preferably also serves as a spring amplifier.

After another variant - see also example Fig. 20 - It can be advantageously provided that the two longitudinal legs 29, 30 are each inserted with their one ends in (here blind hole) openings 60, 61 of the spring core 32 and are held and fixed.

Otherwise correspond structure and function of the spring element of Fig. 20 as far as possible of the spring element of Fig. 6 , in particular with regard to the possibility of connection to the locking device. In Fig. 20 missing however the bend 30 of the Fig. 5 and 6 , In addition, the longitudinal legs in Fig. 20 in the relaxed state substantially straight and are bent when tightening each other.

The spring housing 55 has two parallel walls 33, 34, between which a slot 35 is formed, in which the longitudinal legs 29, 30 over part of their length and - if present - preferably the bend 31 are arranged. The spring core 32 connects here like a web, the two walls 33, 34. The walls 33, 34 and the spring core 32 thus form a kind of spring housing. Preferably This is very flat, so that is well suited for use in fittings of various kinds.

The spring core 32 preferably has ( Fig. 5 and 6 . 20 ) adapted to the shape of the straight or curved in the initial state or relaxed longitudinal leg 29, 30 shape and allows partial support of these longitudinal legs 29, 30 over a portion of the length of these legs, in particular in their sections, which widening to the bend 31 connect ( Fig. 6 ) or which adjoin the ends of the longitudinal legs 29, 30, which are facing the spring core 32 ( Fig. 20 ).

Thus, the bending spring 28 is well protected and guided defined on the spring core 32. By the spring housing 55 with the spring core 32, the effect of the bending spring 28 is advantageously optimized. The walls 33, 34 are parallel to the base plate assembly in the X / Z plane.

The object and the advantage of the spring core 32 achieved here is to guide the bending spring 28 and to increase the energy storable or stored in the bending spring 28 relative to a spring without a core. It is conceivable to design the spring core in one or more pieces.

The physical basis for the design of the spring core 32 is according to a preferred embodiment is to bias the one or more parts bending spring 28 of the energy accumulator 26 - partially or even in almost every area to all or relatively close to the smallest possible elastic bending radius, which here as Energy increase is understood, since this position would not be practically usable without spring amplifier. If this radius is undershot, a plastic deformation occurs in the bending spring 28, as a result of which further energy storage is no longer possible. The bending spring 28 is then overstretched. Conceptually, the spring core 32 corresponds to a portion of a cylinder around which the spring wire is wound and assumes the straight shape when unwinding. Parameters required for calculation are wire cross-section, material yield strength, modulus of elasticity. Thus, with a material yield strength of 1100 N / mm ² , a spring diameter of 2.5 mm, an E modulus of 185000 N / mm ² on a wire wound around a cylinder results in a bending inner radius of 208, 98 mm. Alternatively, the spring core 32 can be easily designed in the experiment.

The radius R of the spring core 32 (see Fig. 7a and 20a ) preferably corresponds to the maximum or maximum elastic elongation of the bending spring without adverse deformation effects.

Preferably, the one or more straight or arcuate longitudinal legs 29, 30 are arranged parallel to the main extension direction of the frame 8 and the bend 31 of the bending spring 28 is oriented to the side facing away from the connecting fitting 15 side of the locking device 14, so that the bending spring 28 well in the in X-direction long cavity 13 of the frame 8 on the side facing away from the release lever 24 side of the locking device can be accommodated.

To Fig. 21a - e are the two longitudinal legs 29, 30 respectively inserted with their one ends in (here blind hole-like) openings 60, 61 of the spring housing 55.

They also extend in the slot 35 between the two walls 33, 34 of the spring housing 55, wherein between the walls 33, 34 in the region in which the openings 60, 61 are formed, a connecting web 56 is formed.

In this variant of the energy accumulator 26, no spring core is formed on the housing 55. The two longitudinal legs 29, 30 of the spiral spring 28 are at least partially arcuate configured. In this case, the two longitudinal legs 29, 30 are in the relaxed state of the bending spring 28, starting from the two ends, which are inserted into the openings 60, 61 against each other over part of their length. Then follows in each case a bent portion, wherein the curvatures of the two longitudinal limbs run in opposite directions. Such results in a side view in approximately a V-shape of the bending spring 28, wherein the two legs of the V are curved in opposite directions. The free ends 36, 37 project from the spring housing 55. They are here in turn advantageously bent from the main extension plane of the spring housing 55, in particular bent by 90 ° to the main extension plane of the spring housing 55, so that they are good at elements of a fitting to which the energy storage device 26 is to be used, can be attached.

When the bending spring 28 is tensioned, the two longitudinal limbs 29, 30 on the two protruding ends projecting from the spring housing 55 are each in the direction P and -P ( Fig. 21b and c ) moves toward each other. The two longitudinal legs 29, 30 reversibly lose their curved shape with the continued movement until, in the tensioned state, they are aligned parallel to one another over their entire length and lie directly against each other ( Fig. 21d ).

In this way, the bending spring 26 is stretched. It thus stores energy, which is released by relaxing in the state of Fig. 21b ) can deliver again.

The Fig. 21a ) to e) show in summary an example of an energy accumulator 26 with spring housing 55, in which the two pre-bent longitudinal legs 29, 30 mutually supported under load and thereby mutually even functionally relative to each other also form a kind of spring core.

Even after the Fig. 21a ) to e) could the two longitudinal legs 29, 30 in the spring housing 55 at the otherwise free ends via a bend in the manner of the bend 31 of Fig. 5 or 6 be connected to each other and be placed with the bend in the spring housing around a bridge.

The energy storage of Fig. 22a ) to e) corresponds in terms of its structure largely the energy storage of Fig. 21a to e. However, here is a narrow spring core 32 formed in the spring housing 55 between the two longitudinal legs 29, 30. This spring core 32 is formed as a straight web 57 here. The two longitudinal legs 29, 30 are arranged on both sides of this web 57, that on the one hand in the relaxed state of the bending spring 28 again (as to Fig. 21 described) results in a V-shape of the bending spring 28 with longitudinal limbs bent away from one another, which in turn also lie parallel to one another in the tensioned state. To Fig. 22a ) - e) (see in particular Fig. 21d ) are the two longitudinal legs 29, 30 then but not directly to each other, but just on the two outer sides of the spring core 32, on which they are supported.

Even after the Fig. 22a ) to e) could the two longitudinal legs 29, 30 in the spring housing 55 at the otherwise free ends via a bend in the manner of the bend 31 of Fig. 5 or 6 be connected to each other and be placed with the bend in the spring housing around a bridge.

The Fig. 23a-e show yet another variant of the energy storage 26. In this energy storage 26, the bending spring 28 only a single longitudinal leg 29. This longitudinal leg 29 is analogous to the longitudinal legs 29 of the Fig. 21 and 22 built up. It is inserted with its one end in a blind hole-like opening 60 in the spring housing 55 and extends there in a slot 35 between the two walls 33 and 34. The longitudinal leg 29 is bent in and protrudes with a free end 36 of the housing , A straight web 58 serves as an abutment web and spring core 32 for this longitudinal limb 29, when it is used to store energy in a straight shape (FIG. Fig. 23d ) is bent. Instead of a second spring longitudinal leg 30 is provided here that the spring housing 55 forms an abutment on which a projection 59 is formed, which is usable as the second interface adjacent to the free end 36 to a fitting out. This energy storage 26 is particularly compact, but stores less energy than the variants of Fig. 5 . 20 . 21 and 22 ,

Not shown but also feasible is a variant of a pre-bent spring longitudinal leg 29, which hangs under load on a curved spring core.

The two longitudinal legs 29, 30 of the bending spring 28 of the variants (or corresponding to the longitudinal legs and the approach 59 in Fig. 23 ) can be pressed in the Z direction at their free ends to each other, whereby the bending spring 28 stores energy that can be released by relaxing - ie by moving the longitudinal leg 29, 30 away from each other - to be described in more detail, the release lever 24 and the catch lever 25 to move. The bending spring 28 is partially placed around the spring core 32 (see Fig. 6 and Fig. 20 ), which serves as a spring amplifier.

The spring core 32 enables a partial support of these longitudinal limbs 29, 30 over part of the length of these limbs, in particular in their sections which adjoin the bend 31 in an expanding manner ( Fig. 6 ) or which adjoin the ends of the longitudinal legs 29, 30, which are turned to the spring core 32.

There are on the spring core 32 laterally two parallel walls 33, 34 is formed, between which a slot 35 is formed, in which the longitudinal legs 29, 30th over a portion of its length and - if present - preferably the bend 31 are arranged.

It is conceivable to design the spring core in one or more pieces.

Alternatively, the spring core 32 can be easily designed in the experiment.

The radius R of the spring core 32 (see Fig. 7a and 20a ) preferably corresponds to the maximum or maximum elastic elongation of the bending spring without adverse deformation effects.

Below is the use of the energy storage 26 of the Fig. 5 and 6 described on the locking fitting. Instead of this energy storage could each one of the energy storage of FIGS. 20 to 22 are used, which are designed so far outwardly or substantially identical.

The longitudinal legs 29, 30 of the energy accumulator 26 of the Fig. 5 and 6 (and the Fig. 20 ff) are respectively at their free ends 36, 37, which are oriented in the assembled position on the frame 8 and the pre-assembled drawer 4 in the direction of the front panel 7a, bent by 90 ° (ie perpendicular to the base plate assembly). The one - here upper - free end 36 passes through a bore 38 of the base plate assembly (here the two base plates 20, 21) and the other - here lower free end 37 on the other hand, a slot (or a slot 39) of the base plate assembly (here the two base plates 20, 21). The bore 38 and the slot 39 are here in the Z direction (in the usual installed position on a drawer, the vertical direction) vertically aligned. The slot 39 is also vertically aligned here and lies here in the vertical direction (Z) below the bore 38th

This is the one free end - here the upper end - 36 of the spiral spring defines stationary but preferably rotatable on the base plate assembly in the bore 38, while the other - here lower free end 37 can move in the slot 39 of the base plate assembly.

The lower free end 37 of the spiral spring 28 further penetrates a bore 40 of the release lever 24. The lower free end 37 thus serves as a rotary shaft for the release lever 24, which can rotate about the free end 37 of the bending spring 28, which in turn can move in the slot 39. In this way, the release lever 24 can perform a superimposed rotational and translational movement on the base plate assembly.

The lower free end 37 of the spiral spring 28 also passes through a bore 41 of the catch lever 25, so that this can perform a superimposed rotational and translational movement of the base plate assembly. In this case, the catch lever 25 also has a slot 42 which is slightly bent here and is located above the bore 41. This slot 42 is penetrated by the other - here upper - free end 36 of the spiral spring 28. In this way, the catch lever 25 is forced to a defined rotational and translational movement (to be described in more detail) when the lower free end 37 of the bending spring 28 shifts in the slot 39 of the base plate arrangement, which entrains the catch lever 25.

The lower free end 37 of the bending spring 28 is located at the upper end of the slot 39 of the base plate assembly, the bending spring 28 is tensioned. This position corresponds to a position in which the front panel 7 is not yet attached.

On the other hand, if the lower free end 37 of the bending spring 28 is located at the lower end of the slot 39 of the base plate arrangement, then the bending spring 28 is in its relaxed state or in a more relaxed state. This position corresponds to a position in which the front panel 7 has been attached. The catch lever 25 has a hook-like locking 43, which then engages behind the undercut, here the bolt 18 of the connection fitting 15, which is then inserted into a horizontally extending slot 44 of the base plate assembly, which is open towards the front panel 7a.

Thus, the bending spring 28 can be held in the cocked position and thus they can be released from this and also so that the bending spring 28 can be moved from the relaxed position in the cocked, the release lever 24 is provided.

The trigger lever 24 has a torque transmission contour 45. Here, this is not for a direct manual movement, but for setting a corresponding Tool provided (exemplary training: Phillips and screwdrivers).

The trigger lever 24 also has an arc shape, wherein at the inner radius of this arc, a control contour 46 is formed. With this control contour 46, the release lever 25 adjoins the base plate arrangement in the mounted position on a pin 47 (FIG. Fig. 7b ), which is provided on the side of the base plate assembly and projects therefrom, on which also the release lever 24 is provided.

In this case, the coordination of the control contour 46 and pin 47 and the pivot bearing at the lower free end 37 of the bending spring 28 in the slot 39 is such that the release lever 24 is movable with the tool in a release position, in which the lower free end 37 of the spiral spring 28 is located in the slot 39 of the base plate assembly at the upper end, so that the bending spring 28 is tensioned. The control contour 46 has for this purpose a cam portion 48. Upon rotation of the trigger lever 24 in the position in which the one free end 37 of the spiral spring 28 in the slot 39 of the base plate assembly is at the top, the cam portion 48 has been run over in a locking direction / position. This position is in the manner of an over-center position a very stable position (here Fig. 6 . 7b ). It requires an external action, a trigger to release the locking device or the release lever 24 from this position.

The locking device 14 is biased in this state. The locking 43 of the catch lever 25 is outside - here above - the slot 44 for insertion of the connection fitting 15th

In this position further is a free end 49 - a web 49 - of the trigger lever 24 approximately at the height of the slot 44 for insertion of the connection fitting 15. This free end 49 of the trigger lever 24 is dimensioned so that at him when attaching the front panel an edge of the connection fitting 15 comes to rest ( Fig. 7a . 7b ). Upon further insertion of the connection fitting 15 or the front panel 7a or 7b, the free end 49 of the release lever 24 is moved further, so that the release lever 24 begins to rotate. During this rotation, the cam portion 48 is overrun in the opposite direction as when tightening ( Fig. 8a . 8b ). This solves the arrangement of the over-center position. As a result, now the spring, here the bending spring 28, relax. This in turn causes the already described movement of the catch lever 25 in the locked position. The lower free end 37 of the spiral spring 28 pulls the catch lever 25 down so that the upper end 36 of the spiral spring 28 is displaced in the slot or in the slot 42 of the catch lever 25.

The vote of the slots or scenes and pivot bearing of the locking device 14 is such that the catch lever 25 begins the undercut (here the bolt 18) of the connection fitting 15 with its locking 43, to engage behind what the connection fitting 15 due to the action of the bending spring 28th continues to pull the locking device 14 and keeps it stable. This position is releasable by turning back the release lever 24 with a tool, to which again the cam portion 48 is to be run over by tool operation.

Overall, such a very compact and yet secure Arretierbeschlag is created.

The Fig. 11 to 16 show a further embodiment of a diaphragm lock fitting.

This aperture lock fitting is largely identical to that of Fig. 4 to 10 designed. Therefore, like reference numerals have been given, and it is possible to fully refer to the description of the structure and function of the first embodiment.

• Bei dem Ausführungsbeispiel der Fig. 11 ff ist das Langloch 39 in den Basisplatten nicht vertikal bzw. senkrecht zur Haupterstreckungsrichtung X der Zarge 8 ausgerichtet, sondern leicht schräg geneigt zur Vertikalen (Z-Achse) in einem Winkel < 30°.

However, there are the following differences:

• In the embodiment of the Fig. 11 ff is the slot 39 in the base plates not vertically or perpendicular to the main extension direction X of the frame 8 aligned, but slightly inclined to the vertical (Z-axis) at an angle <30 °.

In addition, the upper end 36 of the spiral spring 28 engages through a bore 51 in the catch lever 25 'and the lower end 37 of the spiral spring 28 a slot 42' below this bore 51. In addition, in the catch lever 25 'below the slot 42', which is the lower free End 37 of the spiral spring 28 passes through, another slot 52 is formed, which extends substantially in the main extension direction X, thus aligned at an angle to the slot 42 'and is penetrated by a mounted on the base plate assembly pin 53.

In this way, the catch lever 25 ', in turn, from a starting position in which the hook-like locking member 43 is outside the height Z of the slot 44 on the front panel assembly, move to a position in which the locking 43 an undercut, in particular again the bolt 18, engages behind the connection fitting 15. The triggering by the release lever 24 and the further course of the movement are essentially analogous to the Fig. 6 to 10 from.

This means that the connection fitting 15 first reaches the web 49 as the free end of the release lever 24 (FIG. Fig. 13 to Fig. 14a . b ). The release lever 24 is thereby rotated and is released from a locking position / Übertotpunktstellung. As a result, the bending spring 28 can relax, the here lower free end 37 in the scenes / slots 39 and 42 'shifts what the catch lever 25' rotates and moves so that its locking 43 engages the bolt 18 on the connection fitting, this further the locking fitting 14 or to the corresponding frame 8 and then spring-assisted holds there ( Fig. 14 . 15 . 16 ).

Also the variant of Fig. 11 to 16 locked the front panel 7 safely and is designed compact, the variant of the Fig. 4 to 10 is preferred because of the even simpler or more compact design.

Instead of providing a separate support element 19 which is or is arranged on the frame 8, the base plate arrangement, in particular one of the base plates 20, 21 may be connected directly to the frame 8 or consist of a part of the frame 8.

To 17 to 19 the trigger lever 24 is multi-piece, here designed in two pieces and has a first lever arm 24a and a second lever arm 24b articulated thereto. The first lever arm 24 a is here provided with the torque transmission contour 45. He has here as the upper axis of rotation of the end 37 of the spiral spring 28, which passes through him and the slot 39 in the body. It is designed such that it with the connection fitting 15 (see Fig. 17a . b ) is solvable from an over-center position assumed together with the second lever arm 24b, wherein it rotates the second lever arm 24b during a deflection so that it is rotated with the over-center position, so that the energy accumulator 26 can exert its effect. Here is the energy storage the Biegefederanordnung with the spiral spring 28, which can relax so that the catch lever 25 is analogous to Fig. 7 to 10 is moved into a locking position.

Thus, the locking device 14 from the over-center position of Fig. 17a , b solved. The relaxation of the bending spring 28 in turn causes the already described movement of the catch lever 25 in the locking position. The lower free end 37 of the bending spring 28 pulls the catch lever 25 down so that the upper end 36 of the spiral spring 25 is displaced in the slot or in the slot 42 of the catch lever 25.

The vote of the slots or scenes and pivot bearing of the locking device 14 is in turn such that the catch lever 25 begins the undercut (here the bolt 18) of the connection fitting 15 with its locking 43 to engage behind what the connection fitting 15 due to the action of the spiral spring 28 continues to pull the locking device 14 and keeps it stable. This position is releasable by turning back the release lever on the lever arm 24a with a tool. Overall, a very compact and yet secure Arretierbeschlag is created in such a way. <B> reference numerals </ b> Furniture 1 furniture body 2 Side wall 3 drawer 4, 5, 6 front panel 7a, 7b frame 8th rear wall 9 ground 10 inner shell 11 outer shell 12 cavity 13 locking device 14 connecting fitting 15 Screen support 16 web 17 bolt 18 support element 19 baseplate 20, 21 fastener 22 slot 23 sear 24 lever arm 24a, b catch lever 25, 25 ' power storage 26 bending spring 28 longitudinal leg 29, 30 bend 31 innerspring 32 wall 33, 34 slot 35 Free end 36, 37 drilling 38 Long hole 39 Bore release lever 40 Bore catch lever 41 Long hole catch lever 42, 42 ' arresting 43 Slot for bolts 44 Torque transmission contour 45 control contour 46 pen 47 cam section 48 web 49 adjustment 50 drilling 51 Long hole 52 pen 53 spring housing 55 connecting web 56 web 57 web 58 approach 59 opening 60, 61 direction P, -P radius R direction X direction Y direction Z

Claims (15)

Power storage for a fitting, in particular for furniture, in particular for a connection or functional fitting, characterized by a design as a spiral spring arrangement, wherein the spiral spring arrangement has at least one spring core (32). Power accumulator according to claim 1, characterized in that the spiral spring arrangement comprises at least one bending spring (28) having one, two or more longitudinal limbs (29, 30). Power accumulator according to claim 2, characterized in that the spiral spring arrangement has at least one spring housing (55). Power accumulator according to claim 3, characterized in that the one or more longitudinal legs (29, 30) at least over a part of their length in the spring housing (55) engages or intervene. Power accumulator according to one of claims 2 to 4, characterized in that the bending spring (28) as U- or V-shaped bending spring (28) is formed and two of the longitudinal legs (29, 30) which are connected to each other directly or indirectly. Power accumulator according to claim 5, characterized in that the at least two longitudinal limbs (29, 30) are connected to each other directly via at least one bend (31) or that the at least two longitudinal limbs (29, 30) are indirectly (31) via the spring housing (55). connected to each other. Power accumulator according to one of the preceding claims, characterized in that the spiral spring arrangement has at least one spring core (32), wherein the spring core (32) is preferably formed on or in the spring housing (55). Power accumulator according to one of the preceding claims, characterized in that the spring core (32) has a straight or curved outer contour, at which the longitudinal limb or legs (29, 30) in the tensioned state of the longitudinal limbs (29, 30) at least over part of their Support the length. Power accumulator according to one of the preceding claims, characterized in that the bending spring (28) is placed in sections around the at least one spring core (32), which serves as a spring amplifier. Power accumulator according to one of the preceding claims, characterized in that the spring core is formed from mutually supporting longitudinal limbs (29, 30) of the spiral spring arrangement itself. Power accumulator according to one of the preceding claims related thereto, characterized in that on the spring housing (55) laterally two parallel walls (33, 34) are formed, between which a slot (35) is formed, in which the longitudinal limbs (29, 30) over a part of their length einliegen, wherein preferably the at least one spring core (32) as a bent or straight web (57, 58) in the spring housing (55) is formed. Power accumulator according to one of the preceding claims, characterized in that the one or more longitudinal limbs (29, 30) in the relaxed state has a straight or curved shape / have. Power accumulator according to one of the preceding claims, characterized in that the bending spring (28) in a side view has a U-shape or V-shape, wherein the two longitudinal legs (29, 30) in the relaxed state have a straight or curved shape. Power accumulator according to one of the preceding claims, characterized in that from the spring housing (55) a free end or a plurality of free ends (36, 37) of the longitudinal limb (29) or the longitudinal limbs (29, 30) protrudes / project, which as interfaces to a fitting can be used and / or that the spring housing (55) itself has a projection (59) formed on it, which can be used as an interface to a fitting. Fitting, in particular connection or functional fitting for furniture, with at least one energy accumulator or more force accumulators according to one of the preceding claims.

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