WO2011154115A1 - Connecting link - Google Patents

Abstract

The invention relates to a connecting link (1) for a strand-shaped piece of jewellery, comprising at least one coupling element for two ends of the piece of jewellery, a main body (3), at least one pivot member (5, 5') which pivotably leans on the main body (3) and which can be releasably secured on the main body in the position in which said pivot member is pivoted onto said main body (3), at least one spring arm (41, 43), which has at least one first locking section and which can be displaced against the spring force thereof into an unlocking position and moves into a locking position because of the spring force thereof, and at least one second locking section which co-operates with the first locking section such that the pivot member (5, 5') can be releasably secured on the main body (3), wherein the at least one spring arm (41, 43) having the first locking section is provided on the main body (3) or on the pivot member (5, 5'), while the second locking section is provided on the pivot member (5, 5') or on the main body (3). The connecting link is characterised in that a spring element (47) is provided, which can be biased by pivoting the pivot member (5, 5') onto the main body (3) such that the pivot member (5, 5') is pushed away by the main body (3).

Description

 Link Description

The invention relates to a connecting member according to the preamble of claim 1.

Links of the type discussed here are known. They serve to simplify the creation and removal of rope-shaped pieces of jewelry, so in particular chains, bracelets and the like. They are connected to two ends of the piece of jewelry and change the length of the piece of jewelry when pressed. In the closed state, the jewelry piece has a shorter length, so that it can be safely worn for example on the wrist of a user or a user. When you open the connector, the two ends of the piece of jewelry remain securely connected so that it can not accidentally fall or be lost. The length of the piece of jewelery is however somewhat increased, so that it can be taken off easily, or be stripped off over the hand.

When using such a link in connection with a strand-shaped piece of jewelry, it is possible that on the one hand the removal of the piece of jewelry can not easily be done because the link hooks and / or jams. On the other hand, it can happen that when closing the connecting element this does not hook correctly and unintentionally opens during use. This can cause damage to the piece of jewelry if the user gets stuck with the improperly fitting piece of jewelry and this possibly breaks off. It is also conceivable that the piece of jewelry is lost in an accidental opening of the link.

The object of the invention is therefore to provide a connecting member which avoids these disadvantages. To solve this problem, a connecting member is proposed, which is used in connection with a strand-shaped piece of jewelry. It has a base body and at least one pivotable articulated on this pivoting member which is releasably secured in the pivoted to the base body position on this. If the base body and the pivot member are brought into a first position, namely pivoted to each other, the length of the piece of jewelry is shortened, so that it can be worn safely. If the main body and the pivot member are swung apart, the piece of jewelry is extended, so that, for example, a bracelet can easily be stripped off over the hand. The pivot member is releasably secured in the pivoted-pivoted to the base body position, wherein at least one spring arm is provided, upon actuation of this determination can be canceled. Thus, if the pivot member is pivoted to the main body, it can be fixed in this position, so that a piece of jewelry is held securely. Upon actuation of the at least one spring arm, the pivot member can be pivoted away from the base body, so that the length of the piece of jewelry increases and this can be removed without further notice. The connecting member according to the invention is characterized in that a spring element is provided, which is biased at the pivoting of the pivot member to the main body. This leads to that Swivel member is pushed away from the body. This has two effects: First, the pivot member can be pivoted only against the force of the spring element to the body. If the determination of the pivot member on the body in this position is not done correctly, the link will open again, so that the user can immediately recognize that the link is not properly closed. Secondly, the bias of the spring element causes the pivot member to pop open upon actuation of the spring arm and the subsequent release between the base body and the pivot member, without the user having to apply tensile forces or the like for this purpose. Opening the link is so very comfortable.

Further refinements and advantages emerge from the subclaims.

The invention will be explained in more detail below with reference to the drawing. Show it:

Figure 1 is a schematic diagram of a first embodiment of a connecting member in side view; Figure 2 is a schematic diagram of a second embodiment of a connecting member;

Figure 3 is a plan view of an open link according to Figure 2 and

Figure 4 shows a cross section through the end region

Pivotal member. FIG. 1 shows a first exemplary embodiment of a connecting element 1, also referred to as a lock, which serves to simplify the application and removal of strand-like pieces of jewelery. With the term jewelery, chains, bracelets, and also watch straps, which consist of precious metal, steel, leather, textiles, plastic or the like and / or of a combination of such materials, are addressed in connection with the connecting link 1 described here.

The connecting member 1 shown here has a base body 3 and a pivot member 5. This is hinged at one end 7 pivotally mounted on the base body 3. In the embodiment shown here, one end 7 of the pivot member 5 is articulated at one end 9 of the base body 3. But it is possible that the main body 3 - seen in Figure 1 - hinauserstreckt to the right over the pivot point 11 of the pivot member 5. The pivot member 5 has, here at its second end 13 opposite the first end 7, a coupling element 15 on which an end, not shown here, of a strand-shaped piece of jewelry, for example a bangle, an arm chain or a necklace, is articulated.

The pivot member 5 is pivotable relative to the base body 3 and can be applied entirely to this. In FIG. 1, it is not completely pivoted to the main body 3. In the applied position, it can be fixed to the main body 3 in such a way that it can not automatically swing back into the open position shown in FIG. To open the connecting member 1, the pivot member 5 is preferably pivoted so far around the Anlenkpunk 11 clockwise that it is convenient aligned with the base body 3. In this fully open position, the connecting member 1 causes a maximum extension of the piece of jewelry, so that it can be easily removed. In bangles and necklaces, it is possible that the complete unfolding of the connecting member 1 is sufficient to remove the piece of jewelry can. This will not be the case with necklaces. After all, here serves the unfolding of the link 1 to the fact that a necklace is relaxed so that they can be removed from the link 1 or a lock in the course of the chain can be easily opened.

The main body 3 of the connecting member 1 is formed curved for better adaptation to the contour of the user or a user of the piece of jewelry. The pivoting member 5 preferably has the same curvature, so that it rests practically without gaps in its pivoted state on the base body 3 and only takes up very little space. The main body 3 and the pivot member 5 are - viewed in plan view - formed substantially rectangular, both parts are preferably formed not perpendicular to the image plane of Figure 1 is curved. The curvature shown here thus results only in an extension direction of both the main body 3 and the pivot member 5.

The thickness of both the base body 3 and the pivot member 5 is selected depending on the material selected for the realization of the connecting member 1 and its carrying capacity. If metal, preferably a noble metal such as gold, silver or titanium is used, then the connecting member 1 can be made comparatively thin. If plastic is used to form the link 1, larger thicknesses may be required, this depends on the tensile loads of the jewelry and the material properties of the plastic.

At the one end 9 of the main body 3 opposite end 17 of the base body 3, in turn, a coupling element 19 is provided. At this one end of the piece of jewelry, not shown here - preferably pivotally - are attached.

The pivot member 5 has a spring element 21 which projects slightly in the direction of the main body 5. Figure 1 shows that the pivot member 5 has an upper boundary surface 23 and a lower boundary surface 25, and that the spring element 21 projects beyond the lower boundary surface. The spring element 21 is thus assigned to the pivot member 5 here. It is connected at one end to the pivot member 5, while the other end 27 is movable. If the pivot member 5 is applied to the pivot point 11 counterclockwise with its lower boundary surface 25 to an upper boundary surface 29 of the base body 3, the spring element 21, more precisely its end, pushed back. The spring element 21 is resilient, so that it is biased when pushed back and the main body 3 and the pivot member 5 apart. The thickness of the spring element 21 is preferably selected so that it does not protrude beyond the upper boundary surface 23 of the pivot member 5 even in the pushed back state. This embodiment is preferred because it allows the connecting member 1 in the closed state has a very low height. Preferably, the connecting member 1 is formed so that it with a lower boundary surface 31 of the base body 3 on the body of a user rests and only has a total of such a thickness, which is composed of the thickness of the base body 3 and the thickness of the pivot member 5.

If one end of the piece of jewelry (not shown here) is attached to the coupling element 15, the piece of jewelry can, in the closed state of the connecting element 1, bear completely against the upper boundary surface 23 of the pivoting element 5. The other end of the piece of jewelry is preferably attached to the coupling element 19 of the base body 3. FIG. 1 shows that the coupling element 15 can have, for example, an eyelet connected to the pivot member 5 via a web extending substantially perpendicularly to the upper boundary surface 23. Accordingly, the coupling element 19 likewise has an eyelet which is connected to the end 17 of the main body 3 via a web extending substantially perpendicularly to the upper boundary surface 29. This is slightly longer than that of the coupling element 15, so that in the closed state of the connecting member 1, the two coupling elements 15 and 19 are at the same distance from the lower boundary surface 31 of the base body 5. In other words: In the closed state of the connecting member 1 are the eyelets both coupling elements 15 and 19 next to each other, so that the ends of a piece of jewelry connected here also lie as close as possible next to each other and the outer surface of the jewel in the region of the coupling elements 15 and 19 has no step. This results in an optimal appearance of the closed piece of jewelry in the region of the connecting link. 1 From the explanations it is clear that at the end 13 of the pivot member 5 and at the end 17 of the base body 3 wells can be provided, engage in the projections at the ends of a piece of jewelry. However, the embodiment of the connecting member 1 shown here is preferred, because then ends of a piece of jewelry do not have to be specially matched to the connecting member 1 shown here, in particular not if the piece of jewelery consists of a multiplicity of similar decorative elements which have coupling areas at their ends with which they mesh. The coupling elements 15 and 19 need only be matched to the coupling regions of a piece of jewelry and can then be easily connected to this. Characterized in that coupling elements 15 and 19 protrude in the same direction relative to the pivot member 5 and the base body 3, the ends of a piece of jewelry can be attached to the coupling members 15 and 19, so that the connecting member 1 is completely hidden and does not affect the impression of a piece of jewelry. Of course, then measured perpendicular to the image plane of Figure 1 width of the connecting member 1 to the width of the piece of jewelry, so that the connecting member 1 does not protrude laterally beyond the piece of jewelry.

Figure 1 it can be seen that optionally also the coupling element 19 is omitted and the base body 3, as shown in dashed lines in Figure 1, continues directly into the piece of jewelry. Accordingly, the pivot member 5, in a suitable embodiment of the piece of jewelry, be part of the same, so that here too can be dispensed with the coupling element 15. It is So it is possible that the link 1 is partially or completely integrated into the piece of jewelry.

The connecting member 1 has at least one, not visible in Figure 1 spring arm, which may be provided on the base body 3 or on the pivot member 5. The spring arm, which will be discussed in more detail below, is designed so that it is attached at one end to the connecting member 1, that is to the base body 3 or pivot member 5, and has a free end which is movable against the spring force of the spring arm, This has the consequence that during the deflection of the free end of the spring arm this remains between the boundary surfaces 23 and 25 of the pivot member 5 or the boundary surfaces 29 and 31 of the body 3 and not over these surfaces protrudes. The spring arm is thus protected within the main body 3 or pivot member. 5

The spring arm has at least one first locking section, which interacts with a second locking section in such a way that the pivoting member 5 can be releasably secured to the base body 3. It is therefore possible to apply the pivot member 5 completely to the base body 3 and to fix it in this position. In this case, as explained above, the spring element 21 is biased. If the spring arm is actuated and displaced against its spring force, it assumes an unlocking position, so that the pivot member 5 is released and the spring force of the spring element 21 following pivots away from the base body 3, wherein it is pivoted about the pivot point 11 in the clockwise direction. FIG. 2 shows a modified exemplary embodiment of the connecting link 1. Identical and functionally identical parts are provided in FIG. 2 with the reference numerals used above, so that reference is made to the description for FIG. 1 in order to avoid repetitions.

The exemplary embodiment according to FIG. 2 differs from that shown in FIG. 1 exclusively in that two pivoting links are articulated to the main body 3, which are preferably of identical design and arranged symmetrically to an imaginary middle plane M. Therefore, in the following, only the right-hand pivot member 5 of the connecting member 1 according to FIG. 2 will be discussed. This is articulated with its end 7 at the end 9 of the base body 3 so that it is pivotable about the articulation point 11. FIG. 2 shows, like FIG. 1, the pivoting member 5 is not completely applied to the upper boundary surface 29 of the base body 3, so that the lower boundary surface 25 of the pivoting member 5 is arranged at a distance from the base body 3. The pivot member 5 has a coupling element 15 to which an end of a piece of jewelry, not shown here, can be attached. The base body 3 has at its end 9 opposite the end 9 ', a second pivot member 5', which is pivotable about the pivot point 11 '. In Figure 2, both pivot members 5 and 5 'of the connecting element 1 are not applied to the base body 3, but slightly open. The left pivot member 5 'also has a coupling element 15' on which an end of the piece of jewelry, not shown here, can be attached. Here, the coupling elements protrude beyond the upper boundary surface 23 of the pivot member and the upper boundary surface 23 'of the pivot member 5', so that in the closed state of the connecting member 1, the two end areas of a piece of jewelry completely obscure the link 1.

The connecting element 1 according to FIG. 2 has at least one spring arm (not shown here) which, due to its spring action, reaches a first functional position when it is not subjected to a force. In this position, he can determine the pivot members 5 and 5 'releasably on the base body 3. It can be provided on each of the pivot members 5 and 5 ', a spring arm which cooperates via a first locking portion with a second locking portion on the base body 3 and the determination of the pivot members 5, 5' on the base body 3 is used. However, it is also conceivable that the base body 3, as in the embodiment according to FIG. 1, has a spring arm which here has two first locking sections, one of which interacts with at least one second locking section on the pivoting member 5 or on the pivoting member 5 ' so that the pivoting members 5 and 5 'can be releasably fixed there in their pivoted to the base body 3 position. It is also possible that the base body comprises at least two spring arms, of which one each cooperates with a respective pivoting member 5, 5 '.

Figure 3 shows the connecting member 1, as shown in Figure 2, but in plan view. Here, the two pivoting members 5, 5 'are shown in their unfolded position, so that the basic body 3 is also clearly visible.

The main body 3 has a curved base element 33, wherein the curvature of Figure 2 can be seen. FIG. 3 shows the plan view on this base element 33, namely on its upper boundary surface 29. The base element 33 is substantially rectangular. It has a central part 35 which extends continuously from one end 9, in Figure 3 right, to the opposite end 9 '. Along the middle part 35 run - in Figure 3 above and below - slots 37 and 39, which expire shortly before the ends 9, 9 ', preferably arcuately. The upper slot 37 is bounded above by a spring arm 41, according to the lower slot 39 is limited by a spring arm 43. The two spring arms 41 and 43 are connected to the ends 9 and 9 'of the base body 3. The connection can be made in any way, for example by screwing, riveting, welding, soldering or the like. Preferably, the base member 33 is integrally formed, so that the central part 35 and the spring arms 41 and 43 together with the ends 9 and 9 'consist of a single part. The slots 37 and 39 can be machined out of the base element 33 by machining, for example by milling, or by non-machining, for example by laser or wire erosion. It is essential that the spring arms 41 and 43 are only firmly connected to the ends 9 and 9 'and otherwise movable. Through the slots 37 and 39 in particular the possibility is created that the spring arms 41 and 43 in the direction of the central part 35 - against their spring force - are movable. The two spring arms 41 and 43 are formed symmetrically with respect to an imaginary center line S running perpendicularly from top to bottom in FIG. 3 and each have a left section 41 I or 43 I connected to the left end 9 'of the base element 33. In contrast, the symmetrical to the center line S trained right portion 41 r of the spring arm 41 connected to the right end 9 and corresponding to the right portion 43 r of the lower spring arm 43 in Figure 3 also with the right end 9 of the base member 33. The spring arms 41 and 43 each have an actuating portion 41 B and 43 B, which is arranged centrally here, preferably symmetrically to the center line S. Looking at the outer contour of the base member 33, it can be seen that the actuating portion 41 B projects beyond the upper edge 41 R of the spring arm 41. Accordingly, the operating portion 43 B projects laterally beyond the lower edge 43 R. The operating portions 41 B and 43 B are in the same plane as the rest of the base member 33, the upper boundary surface 29 of the body 3 is thus also in the operating range 41 B and 43 B continues. The plan view of the base member 33 shows that the right and left portions 41 r and 41 I of the spring arm 41 each pass over an arc portion in the operating portion 41 B, wherein the arc portions are formed symmetrically to the center line S and the left portion 41 I of the spring arm 41 passes over a counterclockwise curved portion in the operating portion 41 B, while correspondingly the right portion 41 r of the spring arm 41 passes over a clockwise curved portion in the operating portion 41 B. The arc sections in the transition region to the actuating region 41 reduce the loading forces in the spring arm 41 when it is deflected in the direction of the middle part 35, so that material fatigue is greatly reduced. The lower spring arm 43 in FIG. 3 is symmetrical to a horizontal line H and to the center line S and thus point-symmetrical to the spring arm 41. The right and left partial regions 43 r and 43 I thus pass over corresponding arc sections into the actuation region 43 B, as this has already been explained with reference to the upper spring arm 41.

In the embodiment of the connecting member 1 shown here, the two pivot members 5, 5 'are identical and articulated symmetrically to the center line S on the base body 3 at its ends 9 and 9' pivotally. Incidentally, they are formed symmetrically with respect to the horizontal line H. In the following, therefore, the right pivot member 5 is discussed in more detail. Everything said also applies to the left pivot member 5 '.

The pivot member 5 has a base portion 45 which is formed substantially rectangular, wherein the longitudinal axis in the direction of the horizontal line H and the shorter transverse axis parallel to the center line S. The pivot member 5, as shown in Figure 2, formed arched. Figure 3 shows the lower boundary surface 25. The pivot member 5 comprises a spring element 47 which is connected to the base part 45 with its one end such that the other end can be moved against its spring force. In the embodiment shown here, the spring element 47 is connected with its left end portion 49 with the end 7 of the pivot member 5. It extends from there - to the right in FIG. 3 - and is pivotable relative to the base part 45 because it is surrounded by a U-shaped slot 51. That the end portion 49 opposite free end 53 of the spring element 47 is thus perpendicular to the image plane 3 movable. The free end 53 is pre-bent in the plan view according to FIG. 3 from the image plane in the direction of the observer, so that the free end 53 projects beyond the lower boundary surface 25, while the end section 49 projects into the lower boundary surface 25 and into the end 7 passes.

If the pivoting member 5 is pivoted to the base body 3, then in principle its lower boundary surface 25 would rest against the upper boundary surface 29 of the base body 3 or the base element 33 or have a minimum distance. However, since the free end 53 of the spring element 47 with respect to the lower boundary surface 25 - in the position shown in Figure 3 in the direction of the viewer - protrudes, the pivot member 5 can only abut against the base body 3, when it is acted upon by a force, is greater than the spring force of the spring element 47. Thus, if the pivot member 5 is pivoted to the main body 3 and pressed, the spring element 47 is pushed back, so due to the spring property of the spring member 47, a restoring force arises, which pushes the pivot member 5 of the main body 3.

The pivot member 5 is formed at its upper edge 5 o and at its lower edge 5 u with a web 55, 57 which extends from the lower boundary surface 25 and protrudes in the direction of the viewer in Figure 3. At the webs 55 and 57 second locking portions are provided, wherein on the upper web 55, a second locking portion 59 and the lower web 57, a second locking portion 61 is provided. The second locking portions 59 and 61 are supported by the Webs 55 and 57 outgoing projections realized, which are aligned at a distance from the lower boundary surface 25 in the direction of the horizontal line H, so that here quasi hooks are realized. The webs 55, 57 may extend over the entire length of the pivot members 5, 5 '. In any case, they are provided in the area of the locking sections 59, 61. The distance of the webs 55, 57 is chosen so that in the pivoted state, the base part 33 of the base body 3 comes to lie between them. In Figure 2, the webs are omitted so that the spring element 21 is visible.

If the pivot member 5 is pressed against the spring force of the spring element 47 completely against the base body 3, then the spring arms 41 and 43 are guided around by the formed in the second locking portions 59 and 61 projections laterally around the base body 3 and hold on - in Figure 3 facing away from the viewer - lower boundary surface 31 of the base body 3 fixed so that on the base body 3 here corresponding first locking sections are given.

In order to facilitate the fixing of the pivoting member 5 on the base body 3, run-on slopes 63, 65 are provided in the areas in which the second locking portion 59, 61 of the pivoting member 5 contacts the base body 3. Here, the upper edge 41 r and the lower edge 43 r of the spring arms 41 and 43 are not perpendicular to the image plane of Figure 3 from. Rather, ramps are formed whose edge lying in the region of the upper boundary surface 29 is closer to the horizontal line H than its edge located in the region of the lower boundary surface 31. When the pivot member 5 is folded up against the base body 3 so that its lower boundary surface 25 is located near the upper boundary surface 29 of the base body 3, the projections Jn the second locking portions 59 and 61 with the chamfers 63 and 65 in operative connection and slide along this. During the application of the pivot member 5 to the base body 3 forces acting through the projections of the second locking portion 59 and 61 in the region of the chamfers 63 and 65 in the direction of the horizontal line H are constructed. In the region of the upper and lower edges 41 r and 43 r, the spring arms 41 and 43 are provided. Accordingly, the run-on slopes 63 and 65 are formed on these spring arms. If the spring arms are acted upon in the region of the chamfers 63 and 65 with forces acting in the direction of the horizontal line H, they deviate in the direction of the horizontal line H, because the elastic opposing forces of the spring arms 41 and 43 are designed so that upon application of the pivot member 5 acting on the body 3 forces sufficient to trigger this evasive movement of the spring arms 41 and 43. The projections provided on the webs 55 and 57 in the region of the second locking sections 59 and 61 surround the spring arms 41 and 43 as soon as the pivoting member 5 is fully seated against the base body 3, counter to the spring force of the spring element 47. The region in which the projections engage around the spring arms 41 and 43 is referred to as the first locking portion. The spring arms 41 and 43 are urged behind the projections of the second locking portions, so that the pivot member 5 is fixed to the base body 3 and despite the through the pushed back spring element 47 can not swing back acting forces.

From Figure 3, the following can be seen:

The pivot member 5 may be provided with an outgoing from the lower boundary surface 25 web 66 which is centrally located and formed so that the pivot member 5 rests in its pivoted to the base body 3 state with this on the upper boundary surface 29 of the base member 3 on its central part 35. This central part does not move relative to the web 66 when, as will be explained below, the connecting link 1 is unlocked and the spring arms 41 and 43 are deflected. This results in no frictional forces between the central part 35 and the web 66, so that actuating forces for opening the connecting member 1 is reduced to a minimum and wear and deterioration of the optical surface properties are avoided.

FIG. 4 shows a section through the end region of the pivoting member 5 opposite the end 7, wherein the sectional plane extends through the second locking sections 59 and 61. Like parts are given the same reference numbers, so reference is made to the description above.

The pivoting member 5 thus has a base part 45, on whose upper edge 5 o a web 55 springs, which has a first locking portion 59 in the region of the cutting plane selected here. This is realized by the web 55, an inwardly directed projection 67 goes out, which is aligned with the opposite web 57. The web 57 has a corresponding second locking portion 61, which summarizes a projection 69. This points in the direction of the web 55, so that 59 and 61 U-shaped portions are formed on both sides of the pivot member 5 in the region of the second locking portions, which include the spring arms 41 and 43 of the main body 3 in pivoted state of the pivot member. Due to their spring properties, the spring arms 41 and 43 are urged outwards, in FIG. 4 thus to the right and left, so that they are pressed under the projections 67 and 69. Thus, the pivot member 5 is fixed in its pivoted state on the base body 3, so that it can not pivot back from the main body away in spite of acting in the opening direction spring force of the spring member 47.

Figure 5 shows a schematic diagram of a part of a modified link. The same parts are provided with the same reference numerals, so that reference is made to the preceding description.

In the exemplary embodiment according to FIG. 4, it has been assumed that projections 67 and 69 on a pivoting member 5 surround laterally a base element 33 of a base body 3 in order to realize a releasable attachment of the pivoting member 5 to the base body 3. It is also conceivable deviating solution in which a substantially mushroom-shaped locking body 71 is provided on the pivot member 5 or on the base body 3, which has a head 73 and a shaft 75 which is attached to the base body 3 or the pivot member 5. The outer diameter of the head 73 is greater than that of the shaft 75, so that a first locking portion is formed by the head 73. He is preferably ke- formed gelförmig, wherein it widens in the direction of shaft 75, so that a run-on slope is formed.

With the spring arms, not shown here, which are provided in Figure 3 by the reference numerals 41 and 43, hooks H1 and H2 act together, which are L-shaped. The hook H1 has a second locking portion Va. Accordingly, the hook H2 has a second locking portion Vb. The L-shaped hooks H1 and H2 are oppositely oriented, so that the locking portion Va of the hook H1 partially surrounds the shaft 75 of the locking body 71 from the right, while the locking portion Vb of the hook H2 comprises the shaft 75 of the locking body 71 from the left. If the hooks H1 and H2 are pulled apart by the biasing force of spring arms, ie H1 corresponding to the arrow to the left and H2 corresponding to the arrow to the right, then the locking portions Va and Vb are biased against the shaft 75. When a force is applied to the spring arms, the hooks H1 and H2 are moved towards each other, so that the distance between the locking portions Va and Vb increases. If this distance is so great that the head 73 of the locking body can pass between the locking portions Va and Vb, the fixing of a pivoting member 5 to a base body 3 can be canceled so that the pivoting member 5 can pivot freely away from the base body 3. When swiveling the pivoting member 5 to the base body 3, the head 73 urges the hooks H1 and H2 apart until they can engage the shaft 75.

The embodiment shown in Figure 5 can still be modified as follows. The L-shaped hooks can be 90 ° be rotated and engage in a hole which is provided in the base body 3 or in the pivot member 5. If the hooks H1 and H2 are acted upon by forces acting in the opposite direction, as indicated by the arrows in FIG. 5, the locking portions Va and Vb of the hooks H1 and H2 engage in the edge of a hole and hold on to it. For a pivoting movement between pivot member 5 and body 3 is prevented. In order to increase the holding forces, the ends of the hooks H1 and H2 may also be curved in a U-shape in order to better hold on to the edge of the hole.

If the hooks are moved towards one another, ie opposite to the direction of the arrows in FIG. 5, the locking sections Va and Vb of the second locking section release the edges of the hole, so that the fixing of the pivoting element 5 on the main body 3 is lifted and the pivoting element 5 in FIG its open position can swing away from the base body 3. The hole in this case forms the first locking portion.

In the following, the function of the connecting member is described in more detail: The connecting member 1 serves to hold a string-shaped piece of jewelry, for example an arm chain, securely on the arm of a user or a user. The locking member has a base body 3 and at least one pivot member 5. In the closed state, the pivot member 5 is located on the base body 3. In the open state, the pivot member 5 is pivoted away from the base body 3. In particular, it can also be provided that the pivoting member 5 and the base body 3 are completely unfolded are and practically aligned with each other. The pivot member 5 is thereby pivoted about 180 ° relative to the base body 3 from its closed position into the open position.

In the embodiment according to FIG. 1, the base body 3 and the pivoting element 5 have coupling elements 15 and 19 at their ends, which in the closed state of the connecting element lie in the immediate vicinity of one another. If the connecting member 1 is completely unfolded, the two coupling elements 15 and 19 are at a distance which substantially corresponds to the length of the basic body 3 and additionally to the length of the pivoting member 5. If the two elements, pivot member 5 and body 3, as shown in Figure 1, approximately the same length, there is a maximum distance of the coupling elements 15 and 19, which corresponds to twice the length of the body or of the pivot member. In the embodiment shown in Figure 2, two symmetrically arranged pivot members 5 and 5 'are attached to a base body 3 and pivot to close the connecting member to each other until both bear against the base body. At the articulation points 11, 11 'of the pivot members 5, 5' at the base body opposite ends of the pivot members coupling members 15 and 15 'are provided here, which are arranged in the closed state of the connecting member 1 in close proximity to each other. In the opened state of the connecting member 1 according to FIG. 2, the pivoting members 5 and 5 'pivot away from the main body in the opposite direction, with the coupling elements 15 and 15' being at the greatest distance from each other when the pivoting members 15 each pivot 180 ° outwards become. The distance of the coupling elements 15 and 15 ' corresponds to the sum of the length of both pivot members 5, 5 'and the length of the main body. 3

All exemplary embodiments of the connecting element addressed here have at least one spring arm 41, 43 with a first locking section on the base body 3 or on the pivoting member 5. Accordingly, a second locking portion 59, 61 is then provided on the other part, ie on the pivoting member 5 or on the main body 3. In each case, two mutually cooperating locking sections are each on a part of the Grundkör- pers 3 or pivot member 5 of the connecting member 1. If according to Figure 2, a connecting member 1 has two pivot members 5, 5 ', each of the pivot members each at least one connecting portion, which with a corresponding connection portion on the main body 3 cooperates. This becomes clearer from the illustration according to FIG. 3, which shows the connecting member 1 shown in FIG. 2 in the unfolded state: A second locking section 59 and a second locking section 61 are provided on the pivoting member 5, whereby one of the two could be dispensed with. The here mentioned second locking portion 59 and 61 cooperate with locking portions on the base body 3, which are hidden in the representation of Figure 3 and are provided on the lower boundary surface 31 of the base body 3. In this case, it is possible for the first locking section to be formed by the intact lower boundary surface 31 of the base element 33 of the base body 3. It is also conceivable, however, to introduce depressions into the lower boundary surface 31 at corresponding positions, so that the projections 67 and 69, when the pivot member 5 is fixed to the base body 3, lie flat in the lower boundary surface 31. are not there, so do not protrude there. Since the lower boundary surface 31 abuts the body of a user, the wearing comfort is particularly high when the lower boundary surface 31 has no projections or the like. In derrijn Figures 2 and 3 illustrated embodiment, the spring arms 41 and 43 are urged by the projections 67 and 69, which preferably cooperate with run-on slopes 63 and 65, in the direction of the horizontal line H when creating the pivot body 5 to the main body 3, ie deflected against their spring force until they come to lie in the U-shaped space between the projections 67 and 69 and the lower boundary surface 25 and are urged outwards according to FIG. This outward movement corresponds to a movement upwards and downwards in the illustration according to FIG. 3. A pivoting member 5 pivoted to the main body 3 is therefore fixed to the main body 3 and held securely in the pivoted position by the spring arms 41 and 43, in which the spring element 47 of FIG Swivel member 5 pushed back and thus biased. This bias can also be achieved if, unlike shown in Figure 3, the spring element is rotated by 180 °, as is the associated U-shaped slot. In principle, it is additionally or alternatively also possible to provide a spring element of the type mentioned here on the main body 3. The decisive factor is that, when the pivoting member 5 pivots toward the base body 3, a spring element is urged which forces the two parts apart in the pivoted-up position. It is precisely this aspect is a key idea of the link 1 described here: If the determination of lifted at least one pivot member 5, 5 'on the base body 3, the connecting member 1 automatically jumps and relieves the piece of jewelry, so that it can be easily removed: A bracelet or an arm chain can be easily stripped off, the lock of a chain can in relaxed Condition easier to open.

The cancellation of the determination of a pivoted pivot member 5, 5 'on a base body 3 is achieved in that the interaction of a first locking portion is lifted with a second locking portion. This can best be explained with reference to FIG. 3: in the case of a connecting member 1, the pivot member 5, as in the exemplary embodiment in FIG. 1, or the two pivot members 5, 5 ', according to the exemplary embodiment according to FIGS pivoted and fixed there by the interplay of the two locking sections, the connecting member 1 can be unlocked in a simple manner that the at least one spring arm, in Figure 3, the two spring arms 41 and 43, are displaced in the direction of the horizontal line H. FIG. 3 shows that this displacement can be effected very simply by exerting a pressure force on the actuating regions 41 B and 43 B from above and below during the alignment of the locking element 1 according to FIG. 3. By the pressure forces from above and below the slot 37 is narrowed between the middle part 35 and the upper spring arm 41. Accordingly, the width of the slot 39 is reduced between the middle part 35 and the lower spring arm 43. In the embodiment shown in FIG. 3, the connecting member 1 is formed with abutments W, W formed on the main body 3, which in this case move in the direction of the actuating lever. rich 41 B and 43B. They limit the movement path of the operating portions 41 B, 43 B in the direction of the horizontal line H. The fact that the abutment W and W over the horizontal line H project up and down, they serve as a stop for the spring arms 41 and 43. This leads to avoid premature fatigue of the spring arms 41 and 41 '.

Thus, if a compressive force is exerted on said operating areas 41 B, 43 B, the spring arms 41 and 43 are pivoted inwards in the direction of the line H. The displacement of the spring arms and the extent of the projections 67 and 69 is selected so that at a pressure force - from top and bottom in Figure 3 - on the spring arms 41 these out of the range of action of the second locking portion 59, 61 and the pivot member 5 into his open position.

The determination of the pivot members 5 in Figure 1 or 5 and 5 'in Figures 2 and 3 is very easy. They are pivoted in the direction of the base body 3 and pressed against the upper boundary surface 69 with a slight compressive force, which counteracts the spring force of the spring element 47. As a result, the spring element 47 is deflected, resulting in a biasing force. In addition, finally, the two locking portions come into operative contact with each other and put the pivot members 5, 5 'on the base body 3 fixed. Particularly preferred are locking members 1, in which the spring arms and the spring elements are formed integrally with the base body 3 and the pivot member 5. It is at- For example, it is possible to punch the slots in the parts or to produce them by machining or non-machining production methods. In this way, on the one hand, the spring arms 41 and 43 are created, which are movable in Figure 3 practically in the image plane up and down, on the other hand, the spring element 47 is provided, which is pre-bent so that its free end 53 on the lower boundary surface 25 of Pan member 5 protrudes.

If connecting members 1 of the type mentioned here are equipped with coupling elements 15 and 19 or 15 and 15 ', which protrude opposite the associated parts, ends of jewelry pieces can be readily attached here, so that in the closed state, the connecting member 1 is completely covered by this. The embodiment of the connecting member 1 with the coupling elements shown in Figures 1 and 2 is characterized in that the connecting member is easily interchangeable and combined with different pieces of jewelry. But it is also conceivable that both the at least one pivot member 5 and the base body 3 of the connecting member 1 is already part of the piece of jewelry, so it is not realized as a separate replaceable part.

The connecting member 1 described here is relatively inexpensive to produce, in particular when the at least one spring arm 41, 43 'and / or the spring element 47 is formed integrally with the associated part of the connecting member 1. It then accounts in the production of the link or soldering and / or welding work to their attachment. From the explanations to the figures 1 to 5 is also clear that it is irrelevant for the function of the connecting member 1, whether it has one or more spring arms, and whether only one spring arm on the base body 3 or the pivot member 5 is provided. It is also conceivable, as explained with reference to Figure 3, a base body 3 with two spring arms 41, 43 form. It is also possible to provide a respective spring arm on the base body and the pivot member.

It is still clear from FIG. 3 that the connecting member 1 described here is particularly secure: If a user with the piece of jewelry encounters a fixed object at the side, only one of the actuating elements 41 B or 43 B can be pressed, which results in unlocking only the associated connection sections can lead. The other Verbindungsabschnit- continue to act together so that the pivot members 5, 5 'remain applied to the body. Thus, the link 1 remains closed, because the interaction of the other associated connecting portions is adversely affected by a lateral impact in any way. The connection member 1 described here is therefore also very little susceptible to interference, because the spring arms and the spring element are integrally formed with the associated part of the connecting member. So it lacks separate spring elements, such as spiral or coil springs that can slip, pollute, break or bent, which would possibly lead to a total failure of the function. The spring arms are designed so long that they are loaded so little during a normal period of use that fatigue fractures are ruled out. The functional reliability is also supported by the fact that, for example, the ends of Slots are rounded in both the body and in the pivot member, so here the material fatigue is reduced to a minimum. The connection of the spring sections 41 r and 411 on the actuating region 41 B also takes place such that forces occurring upon actuation of the connecting element can be absorbed in a spring-elastic manner. The two sections go over an arc section in the operating area. The same naturally applies to the connection of the spring arm 43 on the actuating portion 43B.

Claims

claims

1. connecting member (1) of a strand-like piece of jewelry with

a base body (3),

- At least one on the base body (3) pivotally hinged pivot member (5, 5 '), in the on the main body

(3) pivoting position is detachably fixable thereto,

- At least one spring arm (41, 43) which has at least one first locking portion and which is displaceable against its spring force in an unlocking position, and due to its spring force arrives in a locking position,

- At least a second locking portion which cooperates with the first locking portion so that the pivot member (5, 5 ') releasably on the base body (3) can be fixed, wherein

- The at least one spring arm (41, 43) with the first locking portion on the base body (3) or on the pivot member (5, 5 ') is provided, while the second Verriegelungsab- section on the pivot member (5, 5') or on the base body (3 ) is provided, and preferably with

at least one coupling element (15, 19, 15, 15 ') for two ends of the piece of jewelry, characterized in that

- A spring element (47) is provided which can be prestressed by pivoting the pivot member (5, 5 ') to the base body (3), so that the pivot member (5, 5') from the main body (3) is pushed away.

2. Connecting member according to claim 1, characterized in that the at least one spring arm (41) integral with the base body (3) or the pivot member (5, 5 ') is formed.

3. Connecting element according to claim 1 or 2, characterized in that on the base body (3) and / or on the pivot member

(5, 5 ') two counter-movable spring arms (41, 43) are provided, which are mutually displaceable against each other in their transition from the locking position to the unlocking position.

4. Connecting element according to claim 1 or 2, characterized in that on the base body (3) and on the pivot member (5, 5 ') each have a spring arm (41, 43) is provided, wherein the spring arms (41, 43) are movable in opposite directions, so that they are mutually displaceable against each other when passing from the locking position to the unlocking position.

5. Connecting member according to one of the preceding claims, characterized in that the at least one spring arm (41, 43) with both ends on the base body (3) or on the pivot member (5, 5 ') is fixed and an operating region lying between its ends (41 B .43B).

6. Connecting member according to one of the preceding claims, characterized in that a movement region of the at least one spring arm (41, 43) limiting abutment (W, W) is provided.

7. Connecting member according to one of the preceding claims, characterized in that the at least one spring arm (41, 43) is assigned to the base body (3) and the at least one spring element (47) the pivot member (5, 5 '), wherein preferably at least a spring arm (41, 43) and the at least one spring element (47) integral with the base body (3) or pivot member (5, 5 ') is formed.

8. Connecting element according to one of the preceding claims, characterized in that the first connecting portion directly to the at least one spring arm (41, 43) is provided.

9. Connecting member according to one of the preceding claims, characterized in that the base body and / or the pivot member (5, 5 ') are part of the piece of jewelry.

10. Connecting member according to one of the preceding claims, characterized in that the base body (3) and / or the pivot member (5, 5 ') have upper and lower boundary surfaces, which are preferably curved along an extension direction of the main body or pivot member.

11. Connecting link according to one of the preceding claims, characterized in that the at least one spring arm (41, 43) lies between the boundary surfaces and preferably does not protrude beyond the boundary surfaces when it is actuated.

12. Connecting member according to one of the preceding claims, characterized in that the spring element (21) protrudes at least in its unloaded position at least over one of the boundary surfaces.

13. Connecting member according to one of the preceding claims, characterized in that it comprises a base body (3) and two hinged to these pivoting members (5, 5 '), with one end (7, 7') at the ends (9, 9 ') of the base body (3) articulated and are pivotable in opposite directions.

14. Connecting member according to claim 13, characterized in that the two pivot members (5, 5 ') are unlocked when a support arm is displaced with two first locking portions which cooperate with a respective second connecting portion on the pivot members (5, 5'), so Both pivot members (5, 5 ') are preferably unlocked simultaneously upon actuation of the support arm.