DE19525334A1 - Construction kit for erection of angled frame structure, e.g. for banisters, balustrades and room stands - Google Patents

Abstract

The kit comprises a round rod (10) which determines the curvature in the round structure (68) and has a hemi-spherical end (15) at one rod end which has the same radius (16) as the round rod (17). A cylindrical recess (20) is let into the rod end having the hemi-spherical end which extends into the adjacent circular profile cover surface (18). The cylinder radius (27) of the recess is equal to the radius of the round rod, and the cylinder axis (23) intersects the rod axis (13).

Description

The invention relates to a kit in the preamble of claim ches 1 mentioned. With a kit of different round rods, which have the same circular profile to each other, it is possible, accordingly the respective needs, a cranked train for different applications to create applications. The individual round bars are connected by connecting bolts zen assembled in the area of the rod axis. With such a kit round rod trains can be used for banisters, parapets and wall handrails form fe. But it can also be used for pull handles for doors or frames for furnishing, e.g. B. coat stand, umbrella stand, wall guard robes and the like.

To do justice to all the types of cranking of a round rod train to become a big one with the known kit (DE 34 09 866 A1) Pallet of differently designed round bars required. These are except straight round rods of different lengths, especially one Large number of differently curved round bars required to fit all in to have available the desired angle gradients in practice. For an Abwin In the round bar train, a round bar had to be in addition to the curvature also have a certain minimum length, which is not easily could be undercut. The manufacture and storage of a lot The number of different round bars is costly and confusing.

The invention has for its object a kit for a crank to develop the round rod train in accordance with the preamble of protection claim 1,  that gets by with as little, space-saving round bars as possible and yet a large variety of differently cranked round rod Trains can be created. This is inventively by the in the characteristic Sign of claim 1 listed measures achieved, the following is of particular importance.

With one or two of the spherical round specified in claim 1 A large number of differently cranked assemblies can already be bars create in the round bar train. The ball end with the one embedded in it Cylinder recess ensures an essentially smooth, flush over passage between interconnected round bars according to the invention. The result is a surprisingly space-saving design. From the Unteran sayings, the following description and the drawings are further Measures and advantages of the invention can be seen. In the drawings the invention is shown in several embodiments. Show it:

Fig. 1, in a perspective view a stepped ball rod according to the invention

Fig. 2 is an exploded view of two ball stepped round bars according to Fig. 1, which are preassembled via a connecting bolt and a washer interposed therebetween to form an assembly,

FIGS. 3a to 3c, the assembly of Fig. 2 of two mutually oppositely disposed, inclined stepped ball round bars according to Fig. 1 forming a hinge-couple with two spatially ver mutually adjustable rotation angles,

Fig. 4 shows a longitudinal section through the rotary joint pair in the extended position of Fig. 3b with indicated connection,

Fig. 5 in Fig. 4 corresponding view of a modified embodiment with an adapter for a pipe connection,

Fig. 6 shows the side view of each other on a pair of oppositely disposed, inclined stepped ball round bars with an intermediate rectilinear distance piece,

Fig. 7 in one of the Fig. 6 illustration corresponding to an alternative with a straight line, although also here, but a long spacer,

Fig. 8a, 8b, a preassembled from two mutually the same direction arranged obliquely stepped ball round bars which form a Doppelwin kel-combination in which an angular plane with respect to the other spatially rotatable,

9 to each other in an axial section, two oppositely arranged inclined stepped ball round bars., Which are connected in a comparison with FIG. 2 opposing manner to each other,

Fig. 10 is a side view of a single ball stepped round bar which serves as an angular transition piece for connecting two rods without ball closure,

Drawn, partially broken away side view of Fig. 11, a with the combination of Fig. 9 similar double-goitre-piece, consisting of a one-piece rod which carries at its two rod ends ball degrees with cylindrical recesses,

Fig. 12 is a perspective view of a modified runs compared to FIG. 1 formed ball round rod according to the invention, in which the cylinder recess perpendicular to the rod axis and forms an axially stepped ball rod,

FIG. 13 shows an axial section through the axially stepped spherical round rod from FIG. 12 in an application which is comparable to that of the preceding exemplary embodiment from FIG. 10, FIG.

Fig. 14 shows a further embodiment of the rod according to the invention where a cylindrical recess in the central region of the round rod is angeord net, thereby forming a T-connection-piece for three adjacent round rods,

Fig. 15 in a side view to Fig. 5 where the comparable axially stepped ball round bar of Fig. 12 is used with an adapter for a conduit connecting type,

Fig. 16 in plan view an example of a from different round bars according to the invention formed round rod-train,

Fig. 17 is a plan view of a right-angle cranked portion of a round rod-train according to the prior art,

Shows a corresponding rectangular cranked portion in a first embodiment of the invention, where used rods in the manner of Fig. 6. 18,

Fig. 19 shows a further alternative for a right-angled cranking according to the invention with round rods which are designed according to Fig. 8a.

The stepped spherical rod 10 shown in FIG. 1 according to the invention can be described in terms of space as follows. The starting point is a cylindrical rod 11 with a circular profile 12 , which will hereinafter be referred to as "round rod". The rod axis 13 is shown in dash-dot lines. While in this case an end surface 14 extending vertically to the rod axis 13 is provided at one end of the rod, there is a spherical cap-shaped end 15 at the opposite end of the rod, which is to be referred to below as "spherical end" and the outline of which is dash-dotted in FIG is. The spherical radius 16 is preferably formed equal to the circular profile radius 17 .

On the side having the ball end 15 , a circular-cylindrical recess 20 , shown in dash-dotted lines in FIG. 1, is let in, which in the following is to be called "cylinder recess" for short. In this case, the associated cylinder axis 23 runs at an angle of inclination, the inner angle 21 of which is highlighted in FIG. 1. The cylinder radius 27 is the same as the aforementioned circular profile radius 17 . The rod axis 13 and the cylinder axis 23 intersect at a point 22 , which also marks the transition between the ball end 15 and the round rod 11 . The cylinder recess 20 extends into the lateral surface 18 , which, as already mentioned, has a circular profile 12 .

This results physically at the inner end of the cylinder recess 20 first of all a circular end face 24 on the spherical rod 10 , which is hereinafter to be referred to as "circular end face", and on the other hand a sickle-shaped segment 25 to be described in more detail below, which is hereinafter referred to as "sickle segment" should. This sickle segment lies in the area of the mentioned inner angle 21 between the rod axis 13 and the cylinder axis 23 and delimits the circular end face 24 on this side. The center of the circular end face 24 is again the intersection point 22 of the rod axis 13 . The sickle segment 25 is determined by two surfaces, namely on the one hand the already mentioned convex lateral surface 18 of the round rod 11 and on the other hand the concave hollow cylinder surface 28 of the penetrating cylinder recess 20 .

In the exemplary embodiment shown in FIG. 1, the inside angle 21 is 45 °, as a result of which an inclined step is generated by the circular end face 24 from the spherical round rod described above. Therefore, this element 10 can be referred to as an "inclined stepped spherical rod". The bolts 30 and 35 , which are described in more detail in the following figures, serve to connect adjacent elements. For a recognizable in Fig. 2 connec tion bolt 30 , the circular end face 24 has at its center 22 a best seen in Fig. 1 receiving hole 29 , the z. B. can be designed as a threaded hole for a corresponding external thread of the Verbindungsbol zens 30 . This receiving bore 29 extends in the direction of the cylinder axis 23 , into which, as shown in FIG. 2, the pin axis 33 is then directed. As can be seen from FIG. 1, the opposite end face 14 of the spherical rod 10 also has an analog receiving bore 19 into which a further connecting bolt 35 , which can best be seen from FIG. 4, can be mounted. This further Verbindungsbol zen 35 then extends, like the receiving bore 19 , in the direction of the rod axis 13th

In the embodiment of FIG. 2, two stepped spherical rods 10 , 10 'are joined together to form a swivel pair 40 via the connecting bolt 30 . This is done by these spherical rods 10 , 10 'facing each other in opposite directions, with their two recessed end regions to be directed towards each other. Between the two circular end faces 24 , 24 ', a disc 31 can be arranged, which has a central hole 32 for the passage of the connecting bolt 30 . The completed assembly of the swivel pair 40 is shown in Fig. 4. In the case of assembly, the ball ends 15 , 15 'remaining on the round rod each engage in the described concave hollow cylindrical surface of the opposite sickle segment 25 , 25 ' and thus ensure a largely smooth transition.

As shown in FIG. 4, one spherical rod 10 'is spatially freely adjustable relative to the other spherical rod 10 around the bolt axis 33 in the direction of the arrow 26 of FIG. 4. This makes it possible to transfer the Drehge steering pair 40 with its two rod axes 13 , 13 'from the visible in Fig. 3b he stretching position in different, mutually mirror-image Win cell positions according to Fig. 3a and 3c. The extent of the possible rotation 26 is essentially limited by the circumferential length of the sickle segments 25 , 25 'on both sides. In Fig. 3a and 3c the two extreme positions are shown, which are approximately + 30 ° and -30 ° compared to the extended position of Fig. 3b.

The respective rotational position of the two spherical rods 10 , 10 'in the swivel pair 40 can be fixed by grub screws 36 , 36 '. This can be done invisibly from the outside by the measures shown in the sectional view of FIG. 4. Because this is realized in a mirror image in the same way in both spherical rods 10 , 10 ', it is sufficient to describe the fixation only in the spherical rod 10 on the left in FIG. 4.

The connecting bolt 35 is screwed into a threaded hole 19 in FIG. 4 and comes with a collar suitable for the attachment of a turning tool at the end 14 located there. The threaded hole is, however, continuously formed and stepped axially in and has at its inner end a shouldered threaded receptacle 39 into which the threaded pin 36 engages in the mounting case. This grub screw 36 can be screwed through the enlarged threaded bore 19 via a suitable plug-in tool when the connecting bolt 35 is disassembled. The grub screw 36 moves with its pin tip into a circumferential groove 37 of the connecting bolt acting as a pivot joint 30 and thus fixes the given rotational position between the spherical rod 10 and the connecting bolt 30 at this point. The corresponding set screw 36 'of the other spherical rod 10 ' drawn on the right in FIG. 4 is moved in a corresponding manner. This also results in a rotational fixation of the respectively selected angle of rotation 26 of the spherical rod 10 'there with respect to the connecting bolt 30 . The two rod axes 13 , 13 'thereby assume a defined spatial angular position to each other, which can be changed at any time by appropriate loosening of the set screw 36 ' and rotation of the spherical rod 10 'in the direction of the arrow 26 .

Fig. 4 also shows that two further straight round rods 41 , 41 'can be coupled via the two end connecting bolts 35 ' of the swivel pair 40 . This is shown for example in the right round rod 41 'in Fig. 4. The round rod 41 'there can z. B. consist of a tube which is drilled transversely, and receives a threaded sleeve 42 , in which a further set screw 43 can be screwed. In the tube interior of the round rod 41 , a transversely perforated bushing 44 can be inserted, into which the spherical rod 10 'projecting end of the connecting bolt 35 ' is inserted axially. By screwing the setscrew 43 , its sharpened inner end moves into a circumferential groove 38 of the connecting bolt 35 , where it ensures a connection that is both non-rotatable and axially fixed.

In the exemplary embodiment of FIG. 5, the connection of a tube 45 , indicated by dash-dotted lines, is illustrated on the basis of a pair of swivel joints 40 of the type described, which is done via a suitable adapter 46 . To connect this adapter 46 , a cylindrical axial shoulder 47 can sit on the end face 14 of the spherical round rod 10 there, expediently with the interposition of a further disk 34 . The projection 47 forms a plug-in part for a corresponding cylindrical receptacle 48 in the adapter 46 . The adapter 46 has at its end opposite the receptacle 48 a cylindrical recess 49 corresponding to the outline of the tube 45 , in which the tube 45 by a screw, for. B. an Allen screw 59 is held. The head area of the hexagon socket screw engages in a central recess in the projection 47 located on the spherical rod 10 and can be fixed there by an indicated threaded screw 57 . The extension 47 is in turn also provided with a circumferential groove 58 , in which the sharpened end of a further set screw 56 engages. This grub screw 56 can be screwed into a transversely directed threaded bore in the socket-shaped end of the adapter 46 . When the threaded pin 56 is loosened, the adapter 46 can be adjusted about the rod axis 13 in the direction of the arrow 66 and fixed in the selected rotational position by tightening the threaded pin 56 . This makes it possible to bring the tube 45 into different angular positions.

In the embodiment of Fig. 6, a pair of swivel 40 'from two spherical rods 10 , 10 ' of the type described in Fig. 2 to 3b is shown, which differs only in that a spacer 50 between the two end faces 24 , 24 ' the common connecting bolt 30 sits. The spacer 50 is formed in a straight line in the present case, but could also be curved in itself, especially if it has a longer length 51 'shown in FIG. 7' of the spacer 50 'shown there. The latter is generally no longer necessary because of the surprising possible rotatability 26 'of FIG. 6, because the following special conditions already exist there.

The spacer 50 ensures in Fig. 6 such a distance 51 between the two-sided circular end faces 24 , 24 'that the areas around bordering sickle segments 25 , 25 ' no longer in the adjacent Kugelab connections 15 , 15 'of the two spherical rods 10 , 10th 'Intervene. The result of this is that a full rotary rotation in the sense of the rotation arrow 26 'of the spherical rod 10 ' around the bolt axis 33 of the connecting bolt 30, which is also indicated by dash-dotted lines in FIG. 6, is possible. As a result, as shown in FIG. 6, the ball rod 10 'having its rod axis 13' in the recognizable right angle 21 'relative to the other rod axis 13 are brought. By the described grub screws or other means, such as adhesives, any chosen spatial angle between the two rod axes 13 , 13 'can be fixed. Although a spacer 50 in the middle of the swivel pair 40 'is used, there is a more compact structure compared to the prior art, as a comparison between FIGS. 17 and 18 illustrates.

In Fig. 17 is a modified compared to the actual state of the art, which shows the theoretically smallest possible dimension of a manifold 60 , the two end surfaces 61 , 61 'are brought together as close as possible. The two planes of the two end surfaces 61 , 61 'illustrated by auxiliary lines 62 , 62 ' in FIG. 17 intersect at an intersection S, which is also the point of curvature for the outer and inner circular surface line of the bend 60 . In the illustrated embodiment, it is a 90 ° elbow 60 , which is intended to ensure a right-angled offset between two round rods 41 , 41 'to be closed, which are illustrated by dash-dotted lines in FIG. 17. Connection bolts 30 , 30 'are also to be used for connection. In the actual state of the art, at least 90 ° circular bends are followed by at least short straight leg pieces, which is why the two end faces 61 , 61 'of the elbow 60 are normally further apart. Fig. 17 thus shows a favorable situation for comparison with the invention, where the straight leg ends are missing and therefore the aforementioned shortest possible dimension between the end surfaces 61 , 61 'is present. This 90 ° elbow 60 of Fig. 17 can be created with great material and labor effort as a quarter-circle segment of a round bar annulus. Without the straight leg extensions mentioned, a manifold in the prior art cannot be produced without further res by a bending process of an initially straight round rod.

However, even with these theoretically most favorable conditions of the manifold shown in FIG. 17, which can be derived from the prior art, the plane 62 'of one end surface 61 ' is at a relatively large distance D from the innermost one shown in dash-dot lines in FIG Surface line 63 of the round rod 41 to be connected at the other end 61 . Comparing this situation with the Drehge steering pair shown in Fig. 18 40 'of Fig. 6 according to the invention, there are already more favorable conditions, although in this case the spacer 50 increases the dimension. The following should be noted:

In the embodiment of FIG. 18 according to the invention, the intersection S to be compared with FIG. 17 results from an extension of the bilateral planes of the end faces 14 , 14 'of the two spherical rods 10 , 10 ', between which the spacer 50 is still located. However, the intersection point S is located in Fig. 18 closer to the respective surface line 63 of the connecting rod on the opposite ball 10 round rod 41st There is a significantly smaller distance d compared to FIG. 17. In the invention, it is therefore possible to produce a right-angled offset, in which the two-sided connection points 14 , 14 'for the other round rods 41 , 41 ' are substantially closer to each other. Even more favorable conditions result from the further embodiment of the invention illustrated in FIG. 19, the details of which are shown in more detail in FIGS. 8a and 8b.

Also in the case of Fig. 8a two of the inclined stepped spherical rods 10 , 10 'of the same type described in connection with Fig. 1 are used, but in an opposite assembly to the swivel pair 40 of Fig. 2 to 4. In Fig. 8a, the two spherical rods 10 , 10 'are joined together in the same direction by the end face 14 ' of the other rod 10 'is placed on the circular end face 24 of one rod 10 ; expediently again with the interposition of the circular disk 31 already mentioned. In this case, a full rotary rotation 26 'of a spherical rod 10 ' about the pin axis 33 of the common connecting bolt 30 is also possible. Starting from the 90 ° position between the two-sided rod axes 13 , 13 'of Fig. 8a, the rod axis 13 ' z. B. in their from Fig. 8b apparent 180 ° parallel position to the rod axis 13 .

In Fig. 8a and 8b there is a unit 55 from the same spherical rods 10 , 10 'above the connecting bolt 30 , which can be referred to as a "double angle combination". This combination 55 can be spatially adjusted with its angle and fix by the recognizable from Fig. 8a and 8b ble and already described in connection with Fig. 4 set screws 36 , 36 '. It is useful for the consideration to distinguish two angular planes, one of which is determined by the bolt axis 33 and the rod plane 13 'of the spherical rod 10 ' and the other also by the bolt axis 33 and the rod plane 13 of the opposite spherical rod 10 . In the rectangular cranked portion of Fig. 8 these two angular planes coincide and lie in the plane of FIG. 8a. These two angular planes are also in the drawing plane even with a 180 ° rotation according to FIG. 8b, but in all other angular positions they are spatially rotated relative to one another. In the case of Fig. 8b, the two straight round rods 41 , 41 'to be connected at the end to the combination 55 run parallel to one another, but the axes 13 , 13 ', the position of which is determined by the spherical round rods 10 , 10 ', are at a parallel distance 54 from one another .

With regard to the spatial dimension of this double-angle combination 55 from FIGS. 8a and 8b, the particularly favorable conditions explained in FIG. 19 result. Referring to FIG. 19, the one exposed circular end face 24 'to the terminal of a straight round rod 41' is used. Extends the level of this connection level 24 'towards the connection to the other straight round rod 41 serving opposing end surface 14 of this combination 55 , so there is an intersection point S, which even comes to lie inside the circular profile 12 to be connected there . Relative to the inner surface line 63 is now a negative distance "-d", which reduces the distance between the two round rod connecting surfaces 14 on the one hand and 24 'on the other hand to a minimum. This results in a particularly space-saving construction.

The already mentioned embodiment of a further pair of swivel 40 '' of Fig. 7 differs from the case previously described in Fig. 6 only in that the spacer shown in Fig. 7 50 'has a greater axial length 51 '. In this case, it is advisable to use two axially aligned connecting bolts 30 , 30 'instead of a common connecting bolt in order to create the desired connection to the two round spherical rods 10 and 10 '. Of course, the spatial rotation adjustment 26 'of a spherical rod 10 ' relative to the other 10 , which has already been described in connection with FIG. 6, is also possible here.

In Fig. 9, finally, a third embodiment is shown, which also makes do with two spherical rods 10 , 10 'of the type described in Fig. 1 and is used to build a structural unit 53 , which acts as a double cranked transition between two straight round rods 41 , 41 ' can be used. Therefore, this unit 53 can be briefly referred to as a "double head combination". Again, the spherical rods 10 , 10 'to each other in opposite directions via a common connecting bolt 30 ''mounted, but they are now with their two end surfaces 14 , 14 ' to each other. Your two circular end faces 24 , 24 'are directed away from each other and serve as contact surfaces for the two round rods 41 , 41 ' to be connected.

Also in this embodiment of Fig. 9, the round rod 10 'of the combination 53 with its rod axis 13 ' relative to the axis 13 of the other round spherical rod 10 in the sense of arrow 26 'rotatable about the pin axis 33 ''. In the illustrated embodiment of Fig. 9, all axes 13 , 13 ', 33 ''lie in a common plane, namely the plane of the drawing, but can be rotated out of the plane of the drawing by the rotation 26 ' determined by the rod axis 13 'determined cranking plane . In Fig. 9, the cranking angle 21 '' between the two rod axes 13 , 13 'is 90 °. After a 180 ° rotation in the direction of arrow 26 'come with this combination 53, the two rod axes 13 , 13 ' to each other in a parallel position.

In Fig. 11 a with the cranked transition between two to be closed straight round rods 41 , 41 'of Fig. 8a comparable embodiment is shown, for which a double spherical rod 52 is used. This ball round rod 52 generates a fixed crank angle 64 and arises, in which ball ends 15 , 15 'are provided with respective cylinder recesses at each of its two rod ends, which face away from each other circular end faces 24 , 24 '. In each case to the cranking angle 64 , the two circular end faces 24 , 24 'are delimited by two sickle segments 25 , 25 '. As can be seen from the lateral outbreak, the straight round rods 41 , 41 'to be connected engage in the sickle segments 25 , 25 ' and are each flush with the two opposite the ball ends 15 , 15 '. In the illustrated embodiment, the cylinder recesses are inserted at both ends in the same, mutually mirror image angle in these spherical ends 15 , 15 ', which is why the Darge presented symmetrical structure results. The two rod axes 13 , 13 ', which determine the crank angle 64 , determine in the present case a 120 ° crank between the two cylinder recess axes 23 , 23 '.

In the exemplary embodiment of FIG. 10, only a single spherical round rod 10 according to FIG. 1 is used as an angle transition piece between two straight basic rods 41 , 41 'indicated by dash-dotted lines. Because of the already described 45 ° inner angle 21 , the axis 13 of the one round rod 41 therefore extends at an angle of 45 ° to the axis of the other round rod 41 'determined by the cylinder axis 23 of the recess. One round rod 41 lies on the end face 14 and the other round rod 41 'on the circular end face 24 of this spherical rod 10 .

In the embodiment of Fig. 12 is a similar to the embodiment of Fig. 1 stepped spherical rod 10 '' shown in perspective, which is why the same reference numerals Chen as in the first embodiment are used for the designation of corresponding components, but to distinguish these reference numerals with a double line ('′) Have been provided. In this respect, the previous description applies. It is sufficient to only consider the differences. In this case, too, the one end face 14 of the spherical rod 10 '' is cut at right angles to the rod axis 13 and only a ball end 15 is provided at the opposite end of the rod.

The most important difference of the spherical rod 10 '' compared to the exemplary embodiment 10 from Fig. 1 is that in Fig. 12, the axis 23 '' of the cylinder recess, not shown, is perpendicular to the rod axis 13 ''. As a result, the circular end face 24 '' generated by it extends parallel to the rod axis 13 ''. In the illustrated exemplary embodiment of FIG. 12, the rod plane 13 '' extends in this circular end face 24 '', which intersects it diametrically. The result is an axially stepped ball rod 10 '' with a particularly solid crescent segment 25 ''. Its concave hollow cylindrical surface 28 '' extends vertically to the rod axis 13 '', as can best be seen from the embodiment of Fig. 13.

In Fig. 13 a comparable with Fig. 10 application of the axially stepped spherical rod 10 '' of Fig. 9 is illustrated. The course of the two round rods 41 , 41 'is determined by the rectangular position of the rod axis 13 ''and the cylinder axis 23 ''.

In Fig. 14 a designed as a "branch piece" round rod 65 is shown. In the present case, three adjacent round bars 41 , 41 ', 41 ''zueinan to be connected at right angles. In the present case, it is a T-connector 65 . The two rod ends are provided with right-angled lig to the rod axis 13 extending end faces 14 , 14 '', on which the described connecting bolts 35 , 35 '' are. A cylinder ausausung, whose position in Fig. 14 speaks the rod 41 'to be connected, is in this case embedded in the middle of the round rod in the outer surface 18 . The circular end face 24 '' of this recess comes to lie in the continuous rod axis. The situation here is similar to that which has already been described in connection with FIG. 13. You can see the T-connector 65 of Fig. 14 as two mirror-image arranged, merging round rods 10 '' according to Fig. 13, in which the bilateral ball ends 15 '' of Fig. 13 have been omitted. Thus, in Fig. 14 two diametrically opposed sickle segments 25 '' with vertical to the continuous rod axis 13 extending hollow cylindrical surfaces 28 ''. In a central bore of the circular end face 24 '' sits the connecting bolt 30 '' for the branched third round rod 41 '.

The embodiment of Fig. 15 shows the described axially stepped spherical rod 10 '', which, similar to the embodiment of Fig. 5, via an adapter 46 'for connecting a perpendicular to the rod axis 13 ''pipe 45 ' is used. The adapter 46 'sits on the circular end face 24 ''and can be rotated about the vertical to the rod axis 13 ''extending cylinder axis 23 '', similar to Fig. 5, in the sense of the rotation arrow 66 '. This rotates the corresponding cylindrical Ausneh mung 49 'in the adapter 46 ', which is why the tube 45 'can be brought into selectable angular positions with respect to the rod axis 13 ''. To connect the tube 45 'with the spherical rod 10 ''here is a threaded screw 67 , whose head, as can be seen, is embedded in a stepped transverse bore in the ball end 15 ''of the spherical rod 10 ''and passes through the adapter 46 '. The end of the screw engages in a threaded bore of a 45 'seated inside the tube two-leaf holder 69 .

An exemplary embodiment of a round rod train 68 is shown in FIG. 16. There are various spherical rods 10 , 10 '', a swivel pair 40 , a T-connector 65 and a family of other straight round rods 41 , 41 ', 41 ''is provided.

Reference list

d distance between 63 and 14 '( Fig. 18)
D distance between 61, 61 '( Fig. 17)
S intersection of planes 62, 62 'or 14, 14 ' or 14, 24 '( Fig. 17 to 19)
10 , 10 ' inclined stepped round rod
10 '' axially stepped spherical rod
11 round bar
12 circular profile
13 , 13 ′ , 13 ′ ′ rod axis of 10, 10 ′ and 10 ′ ′
14 , 14 ′ , 14 ′ ′ end faces of 10, 10 ′ and 10 ′ ′
15 , 15 ′ , 15 ′ ′ ball end at 10, 10 ′ or 10 ′ ′
16 ball radius ( Fig. 1)
17 circular profile radius ( FIG. 1)
18 convex lateral surface of 11
19 , 19 ' location hole in 14 , threaded hole ( Fig. 1, 4)
20 cylinder recess ( Fig. 1)
21 interior angles between 13, 23
21 ' right angle between 13, 13 ' ( Fig. 6)
21 ′ ′ offset angle at 53 ( Fig. 9)
22 intersection between 13, 23
23 , 23 '' cylinder axis
24 , 24 ′ , 24 ′ ′ circular end face
25 , 25 ' , 25'' sickle segment
26 arrow ( Fig. 4, 8a)
26 ′ rotation arrow ( Fig. 6)
27 cylinder radius of 20 ( Fig. 1)
28 , 28 '' concave hollow cylindrical surface of 20 ( Fig. 1 and Fig. 12, 14)
29 mounting hole in 24 ( FIG. 1)
30 , 30 ' , 30'' connecting bolts
31 disc
32 central hole in 31
33 , 33 '' pin axis of 30 or 30 ''
34 further disk ( Fig. 5)
35 , 35 ′ , 35 ′ ′ connecting bolts at 14, 14 ′, 14 ′ ′
36 , 36 'set screw ( Fig. 4)
37 circumferential groove of 30
38 circumferential groove of 35, 35 ′
39 thread mounting ( Fig. 4)
40 , 40 ' , 40'' swivel pair ( Fig. 2, 6 and 7)
41 , 41 ' , 41'' straight round rod ( Fig. 4 and 14)
42 threaded sleeve ( Fig. 4)
43 grub screw ( Fig. 4)
44 socket ( Fig. 4)
45 , 45 ' tube ( Fig. 5 and 15)
46 , 46 ' adapter ( Fig. 5 and 15)
47 cylindrical extension (plug-in part) ( FIG. 5)
48 cylindrical receptacle, socket part ( Fig. 5)
49 , 49 ' cylindrical recess in 46 or 46 ' ( Fig. 5, 15)
50 , 50 ' spacer ( Fig. 6 and 7)
51 distance between 24, 24 '( Fig. 6)
51 ′ length of 50 ′ ( Fig. 7)
52 double round rod ( Fig. 11)
53 double head combination ( FIG. 9)
54 parallel distance between 13, 13 '( Fig. 8b)
55 double-angle combination ( FIGS. 8a, 8d)
56 grub screw at 46 ( Fig. 5)
57 threaded screw ( Fig. 5)
58 circumferential groove of 47 ( Fig. 5)
59 Allen screw ( Fig. 5)
60 manifolds according to the prior art ( Fig. 17)
61 , 61 ′ end face of 60
62 , 62 ′ extended level from 61, 61 ′
63 inner surface line of 41 ( Fig. 17, 18, 19)
64 offset angle between 23, 23 '( Fig. 11)
65 branch piece, T-connector ( Fig. 14)
66 , 66 ' rotation arrow of 45 or 45 ' ( Fig. 5 or 15)
67 threaded screw
68 round rod train
69 holder

Claims (13)

1. kit of different round bars with the same circular profile to build a cranked round bar train,
at least some of which are designed differently in their longitudinal course and determine a curvature in the round rod train,
the individual round rods being connectable by bolts (connecting bolts) acting in the region of their rod axes,
characterized,
that the round rod (stepped spherical round rod 10 ) determining a curvature in the round rod train ( 68 ) has at least at one end of its rod a hemispherical end (spherical end 15 ) which has the same radius ( 16 ) as the round rod ( 17 ),
that in the rod end having the ball end ( 15 ) has a circular cylindrical recess (cylinder recess 20 ) which extends into the adjacent circular profile lateral surface ( 18 ) of the round rod ( 11 ),
wherein the cylinder radius ( 27 ) of the cylinder recess ( 20 ) is equal to the circular profile radius ( 17 ) of the round rod ( 11 ) and the cylinder axis ( 23 ) intersects the rod axis ( 13 ),
that the cylinder recess ( 20 ) forms a circular end face (circular end face 24 ) in the spherical rod ( 10 ), the center ( 22 ) of which lies essentially in the rod axis ( 13 ) of the round rod ( 11 ) and carries the connecting bolt ( 30 ), which extends in the direction of the cylinder axis ( 23 ),
and that a crescent-shaped segment (sickle segment 25 ) remains in the spherical round rod ( 10 ), which is located in the inner angle region ( 21 ) between the cutting rod and cylinder axis ( 13 , 23 ),
wherein the sickle segment ( 25 ) limits the circular end face ( 24 ) on one side and on the one hand consists of the convex lateral surface ( 18 ) of the round rod ( 11 ) and on the other hand consists of the concave hollow cylinder surface ( 28 ) of the cylinder recess ( 20 ). 2. A kit according to claim 1, characterized in that two stepped ball round bars 'are arranged to each other in opposite directions in the round rod train (68) and with their cylindrical recesses gegenein other point, wherein the two rods (10, 10 (10, 10)' preferably) are joined together via a common connecting bolt ( 30 ) to form a pair of swivel joints ( 40 ) whose angle of rotation ( 26 ) is freely adjustable. 3. Kit according to claim 1, characterized in that two stepped spherical rods ( 10 , 10 ') are arranged in the same direction in the round rod train ( 68 ) by the circular end face ( 24 ) of the one rod ( 10 ) the opposite end surface ( 14 ' ) of the other rod ( 10 ') is turned, whereby both rods ( 10 , 10 ') are preferably joined together via a common connecting bolt ( 30 ) to form a double-angle combination ( 55 ), one angular plane of which can be freely adjusted in relation to the other ( 26 ′) is. 4. Kit according to claim 1, characterized in that two stepped spherical rods ( 10 , 10 ') to each other in opposite directions in the round rod train ( 68 ) and with their cylinder recesses th end faces ( 14 , 14 ') face each other,
wherein both rods ( 10 , 10 ') are preferably joined together via a common connecting bolt ( 30 '') to form a double-cranked transition (double cranking combination 53 )
and by twisting ( 26 ') of the two spherical rods ( 10 , 10 ') zueinan one of the cranking plane ( 13 ', 33 '') relative to the other cranking plane ( 13 , 33 '') is spatially adjustable. 5. Kit according to one or more of claims 2 to 4, characterized in that between the mutually facing circular end faces ( 24 , 24 ') and / or end faces ( 14 , 14 ') of the two spherical rods ( 10 , 10 ') one A pair of swivel joints ( 40 ), a double-angle combination ( 55 ) or a double-headed transition ( 53 ) has a disk ( 31 ) which is penetrated by the connecting bolt ( 30 ). 6. Kit according to claim 5, characterized in that between the mutually facing end faces ( 24 , 24 ') and / or Endflä Chen ( 14 , 14 ') of the two spherical rods ( 10 , 10 ') of a swivel pair ( 40 ), a double-angle combination ( 55 ) or a double cranking transition ( 53 ) a spacer ( 50 , 50 ') is arranged with the two spherical rods ( 10 , 10 ') by a common ( 30 ') or by two connecting bolts ( 30 , 30 ') is connected. 7. Kit according to claim 6, characterized in that the spacer ( 50 , 50 ') is formed from a cylindrical portion of a particularly straight round rod, the two ends of which end faces on the two circular faces ( 24 , 24 ') and / or end faces ( 14 , 14 ') of the stepped spherical rods ( 10 , 10 ') abut. 8. Kit according to claim 1, characterized in that a single ner stepped spherical rod ( 10 , 10 '') between two round rods ( 41 , 41 ') is connected without a ball and forms an angular transition piece in the round rod train ( 68 ). 9. Kit according to claim 1, characterized in that the curvature determining round rod on both rod ends carries ball ends ( 15 , 15 ') with cylinder recesses and forms a double round rod ( 52 ) with a fixed offset angle ( 64 ). 10. Kit according to one or more of claims 1 to 9, characterized in that the cylinder axis ( 23 ) of the cylinder recess ( 20 ) inclined to the rod axis ( 13 ) of the round rod ( 11 ). 11. Kit according to one or more of claims 1 to 9, characterized in that the cylinder axis ( 23 ) of the cylinder recess ( 20 ) is substantially perpendicular to the rod axis ( 13 '') of the stepped spherical rod ( 10 ''). 12. Kit according to one or more of claims 1 to 11 with a branch piece ( 65 ) in the round rod train ( 68 ), characterized in that at least one cylinder recess is arranged in the outer surface ( 18 ) of the round rod, which has the same cylinder radius as the round rod . 13. Kit according to claim 12, characterized in that the one-sided cylinder recess has a perpendicular to the rod axis ( 13 ) duri fende cylinder axis ( 23 '') and the round rod as a T-connector ( 65 ) for three adjacent round rods ( 41 , 41 ', 41 '') serves.