Patent Description:
Usually, when joining two elements, such as two rods or tubes, inner threads within the two elements are used which are joined by a bolt having outer threads. In applications where elongated elements are to be joined along a straight line, however, it is oftentimes necessary to adjust distances between the single elements, which is usually achieved by using washers and spacers to fix the threads in a certain position with regard to each other. To remove a single element of such a structure, the threads need to be fully unscrewed, which is time consuming and oftentimes requires specialized tooling.

In aircraft applications in particular, suspension structures are oftentimes used to mount certain equipment within the aircraft. Overhead compartments, for example, can be fixed to the fuselage of the aircraft by means of a truss structure which consists of multiple rods or tubes that are connected to each other in a certain pattern. The truss structure is fixed to primary components of the fuselage, such as to the frames or stringers. The overhead compartments may then be mounted onto the truss structure. Because of the truss structure and the large longitudinal extension of a passenger cabin, it is particularly important to be able to adjust distances between two tubes running along the longitudinal direction of the aircraft because otherwise a desirable flush mounting of the ceiling components may not be ensured.

Further, in order to be able to quickly and easily replace single tubes within the truss structure, for example for maintenance purposes, it is undesirable to have to unscrew regular threaded bolts because of the required time for such procedures. In order to account for manufacturing tolerances of the tubes and for keeping a flush arrangement, it may also be necessary to use different spacers during replacement, adding additional time delays and difficulties. The time needed for such procedures may be particularly disruptive when a component of the truss structure needs to be replaced in a relatively short time.

Also, because the truss structure is directly connected to primary components of the fuselage, mechanical vibrations from the fuselage are transferred into the structure and, therefore, into the components mounted onto the structure. In order to damp such vibrations, usually separate damper components are used to vibrationally isolate the components mounted onto the truss structure from the truss structure.

<CIT> describes a fixation assembly for affixing a first object to and variably spaced from a second object. The fixation assembly comprises a male fastener and a female fastener. The male fastener comprises a bolt-shaped part having a circumferential outer surface, wherein the circumferential outer surface includes alternately at least one ridged section and at least one plain section. The female fastener comprises a circumferential inner surface including alternately at least one ridged section and at least one plain section. The male fastener is insertable into the female fastener in a state where its at least one ridged section coincides with the at least one plain section of the female fastener, the respective ridges of the ridged sections of the male fastener and the female fastener engaging each other after relative rotation of the male fastener and the female fastener.

<CIT> describes a mechanical junction for facilitating the rapid attachment and removal of ultrasonic surgical components for the transfer of ultrasonic energy across the junction from an ultrasonic transducer to an ultrasonically activated tool bit. The junction achieves a high, evenly distributed compressive force to optimize propagation of the ultrasonic energy from the transducer to a tool bit, while maintaining a relatively small outside diameter of the ultrasonic tool.

<CIT> describes a connector component for assembly into a torch. The connector component comprises a body that includes a proximal end and a distal end disposed along a longitudinal axis. At least two thread regions are disposed radially about the longitudinal axis on a surface of the body near the proximal end. Each thread region includes at least two parallel threads disposed on the surface of the body. In addition, at least two smooth regions are each disposed radially about the longitudinal axis between a pair of thread regions on the surface of the body.

<CIT> describes a fastener composed of a male member and a female member, and more particularly, to a simple fastener capable of inserting a male member into a female member and fastening the female member by approximately <NUM> degrees.

<CIT> describes a piering device that includes a shaft having interspaced threaded portions and unthreaded portions extending axially along at least a portion of its length. The unthreaded portions of the shaft are radially recessed with respect to the threaded portions. A helical plate with a threaded passageway can engage the threaded portions of the shaft at any desired location along the shaft. A key is then inserted into the passageway between the helical plate and an unthreaded portion of the shaft to hold the helical plate at the desired location on the shaft.

It is an objective to provide a connection assembly which allows for easy replacement of single elements within a larger structure of elements without the need to disassemble the whole structure. It is a further objective to provide such an assembly with integrated vibration damping capabilities.

This objective is solved by the subject matter of the independent claims. Further embodiments are described in the dependent claims as well as in the following description.

According to a first aspect of the invention, a connection assembly for connecting a first element to a second element according to claim <NUM> is provided. The connection assembly comprises a male element and a female element. The female element comprises a barrel nut and the barrel nut comprises a conical inner portion positioned at a first longitudinal region and a cylindrical inner portion positioned at a second longitudinal region. The barrel nut comprises at least one first engaging element portion and at least one first plain portion arranged alternatingly around a circumferential direction of the barrel nut. The male element has a cylindrical bolt-like shape and comprises at least one second engaging element portion and at least one second plain portion arranged alternatingly around a circumferential direction of the male element. The male element further comprises flattened sides at the at least one second plain portion. Each of the at least one second engaging element portions of the male element is configured to engage with a respective one of the at least one first engaging element portion of the barrel nut.

Such a connection assembly may, for example, be useful to connect a first tube to a second tube, in particular in a straight line. However, other use cases are conceivable, too. For example, at an intersection point of two or more tubes, multiple of the male elements, as further described below, may project from a central element of the intersection point in different directions, and the corresponding female elements may be connected to or integrated into end sections of the tubes, so that a defined grid of tubes may be established using the connection assembly. However, the first element and the second element may also be any other component, that is to be joined to another component.

The barrel nut may, for example, be a bush-like element having a generally tubular form. The circumferential direction of the barrel nut may be described as the direction around the inner wall of the generally tubular form, i.e., the circular path along the inner wall of a tubular base of the barrel nut. At the inner surface of the barrel nut and around the circumferential direction are the first engaging element portions arranged in an alternating order with at least one first plain portion.

A plain portion in this sense, however, does not necessarily describe a planar portion without any curvature. The term "plain" refers to a portion where no protrusions or recesses, such as at the engaging element portions, are provided to engage with the male element. Preferably, the first plain portions have a curved but homogeneous surface.

The first plain portions and the first engaging element portions are separated and distinct along the circumferential direction of the barrel nut and extend each along a longitudinal axis of the generally tubular form of the barrel nut. The longitudinal axis of the barrel nut preferably is a symmetry axis that indicates a rotational symmetry.

The first longitudinal region and the second longitudinal region correspond to regions at different longitudinal positions or sections along the longitudinal axis of the generally tubular form of the barrel nut. The barrel nut comprises two opposite openings and the first longitudinal region is arranged at one of the openings while the other opening is arranged at the opposite opening. One of the openings may also be referred to as an insert opening, as described further below.

The conical inner portion corresponds to a portion of each of the first plain portions, which does not have a constant diameter but is tapered from the insert opening towards regions further inward of the barrel nut towards the cylindrical portion, so that the diameter of the conical inner portion becomes smaller when going further to the inside of the barrel nut. Preferably, the conical inner portion has a tapering shape only in regards of the plain portions of the first longitudinal region while the inner surface of the barrel nut does not taper where the first engaging element is located. For example, when the conical inner portion has two plain portions and two engaging element portions which are arranged opposite to each other, respectively, so that the respective plain portions are arranged opposite to one another and the respective engaging element portions are arranged opposite to one another, the distance between the plain portions increases when starting at the cylindrical portion and moving towards the insert opening while the radial distance between each of the engaging elements within an engaging element portion with respect to its corresponding engaging element of the opposite engaging element portion may be constant along the longitudinal direction of the conical region. For example, the cross section of the conical inner portion may be oval. This shape may be implemented by reducing the wall thickness of the barrel nut at the plain portions in a direction from the cylindrical portion towards the insert opening.

The cylindrical inner portion, on the other hand, does comprise a constant diameter over the full longitudinal length of the second longitudinal region.

In other words, each first plain portion extends along the full longitudinal length of the barrel nut but is limited in the circumferential direction to certain regions of the barrel nut. The first plain portions extend along the conical inner portion and the cylindrical inner portion along the longitudinal direction of the barrel nut, so that each first plain portion comprises a cylindrical inner portion and a conical inner portion.

The first engaging element portions may each comprise any suitable engaging structure to allow the second engaging element portions of the male element to come into engagement with it. For example, the first engaging element portions may comprise one or more grooves or protruding structures which allow corresponding structures of the male element to engage, such that the male element is connected to the female element, when the first engaging element portions and the second engaging element portions as in contact with each other. The first engaging element portions may for example also be inner thread portions of the barrel nut, which are interrupted by the first plain portions in the circumferential direction of the barrel nut. In contrast to the first plain portions, the smallest diameter of the engaging element portions may be constant over the full longitudinal length of the barrel nut, to allow the male element and the female element to be locked together in any relative longitudinal arrangement.

In particular, the engaging element portions may include multiple similar or identical and repeating structures along the longitudinal direction, so that the male element and the female element may be connected with each other in different longitudinal positions with respect to each other. This allows for length adjustments of the full assembled structure. For example, when two tubes are connected with each other, the full length of the assembly of the two tubes may be adjusted in that the male element may be inserted into the female element only for the desired length or at the desired relative position.

The number of the second engaging element portions of the male element may correspond to the number of first engaging element portions of the female element. Also, the number of first plain portions of the female element may be the same as the number of second plain portions of the male element.

The second engaging element portions of the male element are designed to match the first engaging element portions of the barrel nut and are, just as the first engaging element portions of the female element are separated by the first plain portions, separated by the second plain portions of the male element.

The second plain portions comprise flattened sides. The male element has a generally bolt-like shape, such as a screw, where the grooves or threads are separated by the second plain portions. In particular, a cross section of the male element may be that of a screw or screw-like element, where sides of the screw-like element have been cut off along the longitudinal direction.

For both the female element and the male element, the circumferential extensions of the engaging element portions are smaller or the same as the circumferential extensions of the plain portions. This allows for freely inserting the male element into the female element when the second plain portions of the male element face the first engaging element portions of the female element. The male element may be inserted into the female element as far as desired. Afterwards, the male element and the female element may be rotated with respect to each other, so that the first engaging element portions come into contact with the second engaging element portions, thereby connecting the male element and the female element and locking longitudinal movement of the male element with respect to the female element in the desired position.

The conical inner portion at the first longitudinal region allows for slightly tilting the male element with respect to the female element when the male element is not inserted up until the cylindrical portion. When the male element, however, is inserted up until the cylindrical portion, the cylindrical portion leads the male element with respect to the female element, so that both elements are aligned in a straight line, before bringing the engaging element portions into engagement. This avoids jamming of the engaging element portions while locking. The possibility to tilt the male element and the female element with respect to each other, on the other hand, allows for easy removal of a component, such as a tube in a truss structure, without having to disassemble the full structure. Such a tube may first be unlocked by rotating the female element with respect to the male element into the unlocked position, shifting the tube to one side, and simultaneously tilting and shifting the tube to the other side. The conical inner portion thereby allows slight tilting of the tube out of the straight position. The provision of the conical inner portion therefore allows for easy removal and replacement of the component from the assembled structure.

According to an embodiment, the connection assembly further comprises a clamp. The male element further comprises a first locking groove running along a longitudinal direction and arranged within one of the second engaging element portions. The barrel nut further comprises a second locking groove running along a longitudinal direction of the barrel nut and arranged within one of the first engaging element portions. The clamp is configured to engage with the first locking groove and the second locking groove, when the male element is connected to the female element, thereby locking rotational movement of the male element with respect to the female element.

The first locking groove and the second locking groove may both be recesses formed within at least one of the first engaging element portions and the second engaging element portions, respectively. The locking grooves may for example be formed as elongated grooves arranged in the center (with respect to the circumferential direction of the female element and the male element) of the corresponding engaging element portion and running along the full longitudinal extension of the female element and the male element. In particular, the locking grooves are dimensioned to receive the clamp. When the male element is inserted into the female element and when both elements are in the locked position, the first locking groove and the second locking groove are aligned with each other and build a common longitudinal channel to receive the clamp. By inserting the clamp into this channel, rotational movement of the male element with respect to the female element is blocked because the engaging element portions cannot move rotationally anymore. This avoids inadvertently releasing the connection assembly, e.g., by vibrations or other external disturbances.

According to another embodiment, an inner diameter of the cylindrical inner portion of the female element at the first plain portions is the same in size as an outer diameter of the second engaging element portions of the male element.

As described above, the cylindrical inner portion builds a tubular section in the inside of the barrel nut with acts to align the male element with the female element in a straight. By dimensioning the outer diameter of the second engaging element portions in the same size as the inner diameter of the cylindrical inner portion, the male element can only move in the longitudinal direction once inserted into the cylindrical inner portion, such as is the case with a dowel pin.

However, it may also be conceivable to dimension the outer diameter of the second engaging element portions slightly smaller, to facilitate rotational movement of the male element with respect to the female element during assembly of the elements to be connected with the connection assembly.

According to another embodiment, the female element comprises an insert opening. The conical inner portion is arranged immediately at the insert opening. The cylindrical inner portion is arranged adjacent the conical inner portion opposite the insert opening, such that the conical inner portion is arranged between the insert opening and the cylindrical inner portion.

As already described above, the barrel nut has two openings at the sides. The barrel nut may for example be mounted inside a side end of a tube to be connected, such that one of the two openings faces the opening of the tube and flushes with the face of the tube. This opening is defined as the insert opening. The male element may be inserted into the female element at the insert opening. When the male element is not fully inserted into the barrel nut, in particular not inserted as far as to contact the cylindrical inner portion, the conical inner portion allows for slight tilting of the male element with respect to the female element. In particular, the further the male element is removed from the female element, the more tilting is possible because of the conical structure of the conical inner portion. Therefore, when simultaneously shifting and tilting, e.g., such a tube, it may be easily removed from the full structure.

According to another embodiment, an inner diameter of the conical inner portion at the insert opening is larger than an inner diameter of the conical inner portion at the cylindrical inner portion, such that the diameter of the conical inner portion is tapered from the insert opening in the direction of the cylindrical inner portion.

Therefore, the diameter of the conical inner potion approaches the diameter of the cylindrical inner portion when going further inside the barrel nut.

According to another embodiment, the conical inner portion merges directly into the cylindrical inner portion.

According to another embodiment, each one of the at least one first engaging element portion has at least one groove, wherein the at least one groove runs along the circumferential direction of the barrel nut. Each one of the at least one second engaging element portion has at least one engaging member that is configured to engage with the at least one groove of the at least one first engaging element portion.

The grooves in the first engaging element portions may, for example, be recesses in the engaging element portions that run along the circumferential direction. In particular, the grooves may run at a fixed longitudinal position around the circumferential direction. If more than one groove is employed, recesses and protrusions alternate with each other along the longitudinal direction.

The engaging members of the second engaging element portions are designed to correspond with the grooves of the first engaging element portions. Therefore, the second engaging element portions of the male element may have protrusions which correspond to grooves of the first engaging element portions, such that the protrusions fit into the grooves. Therefore, when rotated with respect to each other after insertion, longitudinal movement of the male element with respect to the female element is blocked.

According to another embodiment, each one of the at least one first engaging element portion includes multiple thread-like grooves.

Such thread like grooves may be similar to the threads of a screw and may in particular comprise a screw-like pitch, so that the grooves are twisted along the longitudinal direction. This introduces a tension into the first engaging element portions and the second engaging element portions, when the male element is rotated with regard to the female element while bringing them into the locked position after insertion of the male element. This further secures the male and female elements with each other. In particular, inadvertently rotating the male element with regard to the female element into the unlocked position is avoided.

According to another embodiment, a tapering angle of the conical inner portion is dimensioned to allow a tilting of the male element with regard to the female element between <NUM> degree and <NUM> degree when the male element is inserted in the conical inner portion.

Such a tilting angle may allow to tilt an element in a greater structure, e.g., a tube in a truss structure, far enough out of the straight line in order to remove the element without having to disassemble the full structure. Usually, in such structures, the tube is mounted between fixes connection points, which may each employ a male element of the connection assembly. In order to remove a single tube from the structure, the tube may be unlocked by rotation, a described above, shifted towards one of the male elements, and then simultaneously tilted and shifted towards the opposite male element.

However, other tilting angles may also be implemented, depending on the desired application. In particular, when using the connection assembly to connect rods or tubes, the shorter the tubes, the bigger the tilting angle must be, as will be readily apparent to one of ordinary skill in the art.

According to another embodiment, the barrel nut comprises two first engaging element portions spaced from each other by <NUM> degrees about the circumferential direction of the barrel nut. The male element comprises two second engaging element portions spaced from each other by <NUM> degrees about the circumferential direction of the male element.

The male element and the female element are configured to be connected by inserting the male element into the female element and turning both elements by <NUM> degrees around a common longitudinal axis.

By employing two first engaging element portions and two second engaging element portions spaced by <NUM> degrees, the circumference of the male element and of the female element each are divided into four regularly arranged sections, two plain portions and two engaging element portions. The male element may be inserted into the female element, such that the second engaging element portions of the male element each face a corresponding plain portion between the first engaging element portions of the female element. By turning the female element and the male element by a ¼ rotation, i.e., by <NUM> degrees, the engaging element portions of the male element and the female elements come into engagement and lock the male element to the female element.

Other amounts of engaging element portions are also conceivable. For example, the female element and the male element may employ multiples of two engaging element portions, such as four, eight, etc., engaging element portions. If, for example, four engaging element portions are employed, rotation of <NUM> degrees locks the male element to the female element, and so on.

According to the invention, the female element further comprises a shock absorbing element and the shock absorbing element surrounds the barrel nut around its outer circumferential direction.

As described above, the female element is a bush-like element which has a circular outer diameter. The shock absorbing element may be a shell or envelop made from a flexible material that is wrapped around the barrel nut and encloses the barrel nut. Therefore, when the female element is inserted into, e.g., a tube or other element that is to be connected to a second element, the shock absorbing element connects the barrel nut with the tube or other element. Therefore, vibrational loads coupled into the barrel nut, for example via a male element from a junction point of a truss structure, are absorbed by the shock absorbing element and isolated from the tube or other element. Hence, vibrations, e.g., from a fuselage, are not propagated into the truss structure or other structure, avoiding vibrations and other mechanical loads, e.g., in an overhead compartment.

According to another embodiment, the shock absorbing element is made from a rubber material.

According to another aspect of the invention, a system is provided. The system comprises a first element, a second element, a first connection assembly, and a second connection assembly. The first connection assembly and the second connection assembly may be designed according to any one of the embodiments described above. The first element is a first tube, and the second element is a second tube. The female element of the first connection assembly is dimensioned to match the inner diameter of the first tube and is arranged within an end section of the first tube. The female element of the second connection assembly is dimensioned to match the inner diameter of the second tube and is arranged within an end section of the second tube. The male elements of the first connection assembly and the second connection assembly are joined with each other so as to project at an angle to each other.

The male elements of the first and second connection assemblies may, for example, be connected to each other such that they project <NUM> degree from each other in opposite directions. The female elements of the first connection assembly and the second connection assembly are arranged inside end sections of the first tube and the second tube, respectively, such that the insert opening, as described above, are flush with the opening of the end sections of the tubes. The first and second male elements may for example be joined at a junction point of a truss structure, so as to allow two tubes to be connected to the junction point in the manner described above with regard to the connection assembly.

The male element of the first connection assembly and the male element of the second connection assembly may, however, also project from each other in angles different from <NUM> degrees, so that a desired grid of tubes may be established, for example, in order to build a truss structure for an aircraft.

If the male elements of the first connection assembly and the second connection assembly project by <NUM> degrees from each other, they connect the first tube and the second tube with each other in a straight line, when locked with the female elements of the first connection assembly and the second connection assembly, respectively.

In summary, the present disclosure provides a connection assembly for connecting a first element to a second element. The connection assembly may, for example, be employed to connect single tubes of a truss structure within an aircraft and provides for easy removal and replacement of single tubes of such a truss structure, without the need for specialized tooling, thereby reducing maintenance time. The connection assembly further provides integrated shock absorbing capabilities, so that vibrational loads from a surrounding structure, such as the aircraft fuselage, are absorbed and not transferred to the tubes of the truss structure.

Although the present disclosure is described with regard to aircraft applications, it should be appreciated that the disclosed connection assembly may be applied to any suitable application, such as other vehicle applications (trains, cars, trucks, etc.) or for applications in buildings, as will be readily apparent to one of ordinary skill in the art.

In the following, exemplary embodiments are described in more detail having regard to the attached figures. The illustrations are schematic and not to scale. Identical reference signs refer to identical or similar elements. The figures show:.

<FIG> schematically shows a truss structure <NUM> within an aircraft fuselage <NUM>. The truss structure <NUM> comprises multiple first tubes <NUM> and second tubes <NUM> which are connected by means of multiple connection assemblies <NUM> according to the present disclosure. Male elements <NUM> of the multiple connection assemblies <NUM> are integrally connected to multiple junction points <NUM>. In <FIG>, two first tubes <NUM> are connected to a second tube <NUM>. The second tube <NUM> is arranged between two junction points <NUM> which connect the tubes <NUM>, <NUM> and between two first tubes <NUM>. Each of the tubes <NUM>, <NUM> comprises a female element <NUM> (see <FIG>, not shown in <FIG>) inside each end section of the tubes <NUM>, <NUM>. The connection assemblies <NUM> allow for easy removal and replacement of single tubes <NUM>, <NUM> from the truss structure <NUM>, e.g., for maintenance work without the need for specialized tooling, as will be described with regard to <FIG>. Further, the connection assemblies provide integrated shock absorbing capabilities, as also described below.

<FIG> shows a male element <NUM> of the connection assembly <NUM> of <FIG>. The male element <NUM> has a generally bolt-like shape and extends in a longitudinal direction <NUM>. The male element <NUM> comprises two second engaging element portions <NUM> and two second plain portions <NUM>. The second plain portions <NUM> and the second engaging element portions <NUM> are arranged around a circumferential direction <NUM> in an alternating order. Although shown as extending only over a part of the longitudinal direction <NUM>, the second engaging element portions <NUM> and the second plain portions <NUM> may also extend over the full length of the male element <NUM>. The male element <NUM> further comprises two first locking grooves <NUM>.

The second plain portions <NUM> are designed as flattened sides <NUM>, such as is the case with a flat bolt. The second engaging element portions <NUM> are illustrated as being a plurality of grooves along the longitudinal direction <NUM>. However, it should be appreciated that the second engaging element portions may be any suitable structure for connecting the second engaging element portions <NUM> with corresponding first engaging element portions <NUM> (<FIG>). For example, the second engaging element portions <NUM> may also be thread-like structures having a pitch, such as with a screw thread. The second engaging element portions <NUM> may also comprise one or more pins, such as with a bayonet locking mechanism.

The first locking grooves <NUM> run along the longitudinal direction <NUM> in the center of each second engaging element portion <NUM>. The first locking grooves <NUM> may be designed to receive a clamp <NUM> (<FIG>) to lock circumferential movement of the male element <NUM> with respect to the female element <NUM> (<FIG>), as will be described further below.

<FIG> shows a detailed cut-view of a female element <NUM> of the connection assembly <NUM> of <FIG> which is mounted inside a first or second tube <NUM>, <NUM>. The female element <NUM> is configured to be connected to the male element <NUM> of <FIG> and comprises a barrel nut <NUM> and a shock absorbing element <NUM>. The shock absorbing element <NUM> surrounds the barrel nut <NUM> and connects it to the tube <NUM>, <NUM>. The tube <NUM>, <NUM> comprises a clamp hole <NUM> for fixing a clamp <NUM> (<FIG>), which will be described further below.

The barrel nut <NUM> has a generally tubular form and comprises an insert opening <NUM>, which is flush with an opening of the tube <NUM>, <NUM>. The barrel nut <NUM> further comprises two first engaging element portions <NUM> and two first plain portions <NUM> (only one shown, <FIG> shows a symmetric cut-view of the female element <NUM>) which are arranged around the circumferential direction <NUM> in an alternating order. Further, the barrel nut <NUM> comprises two second locking grooves <NUM> which are running along the longitudinal direction <NUM> inside the first engaging element portions <NUM>. The second locking grooves <NUM> are designed to build a common channel for a clamp <NUM> (<FIG>) to lock circumferential movement of the female element <NUM> with respect to the male element <NUM> when the female element <NUM> and the male element <NUM> are rotated into the locked position.

The first engaging element portions <NUM> are designed complementary to the second engaging element portions <NUM> of the male element of <FIG>. In particular, the first engaging element portions <NUM> extend along the longitudinal direction <NUM> over the full length of the barrel nut <NUM> and comprise a multitude of protrusions, which are designed to engage with the grooves of the second engaging element portions <NUM> of <FIG>. The smallest diameter of the barrel nut <NUM>, i.e., the distance between two opposite protrusions of the first engaging element portions <NUM>, is constant over the full length of the barrel nut <NUM> along the longitudinal direction <NUM>.

The first plain portions <NUM> also extend over the full length of the barrel nut <NUM> along the longitudinal direction <NUM> and each comprise a conical inner portion <NUM> and a cylindrical inner portion <NUM>. The conical inner portion <NUM> is arranged immediately at the insert opening <NUM> in a first longitudinal region <NUM>. The cylindrical inner portion <NUM> is arranged adjacent the conical inner portion <NUM> in a second longitudinal region <NUM>.

The cylindrical inner portion <NUM> has a constant diameter over the full extension of the cylindrical inner portion along the longitudinal direction <NUM>. The conical inner portion <NUM>, however, has a conical shape having a larger diameter at the insert opening <NUM> than at the transition to the cylindrical inner portion <NUM>. The inner diameter of the barrel nut <NUM> at the cylindrical inner portion <NUM> is substantially the same as the outer diameter of the second engaging element portions <NUM> of the male element <NUM>.

When connecting the male element <NUM> with the female element <NUM>, the male element <NUM> is first inserted into the barrel nut <NUM> such that the second engaging element portions <NUM> are facing the first plain portions <NUM>. The conical shape of the conical inner portion <NUM> allows the male element <NUM> to tilt out of the longitudinal direction <NUM> with respect to the barrel nut <NUM>. Because of the substantially same diameter of the second engaging element <NUM> and the cylindrical inner portion <NUM>, when the male element <NUM> is inserted far enough to reach the cylindrical inner portion <NUM>, the male element <NUM> and the female element <NUM> are aligned along the longitudinal direction <NUM>. The male element <NUM> may then be connected with the female element <NUM> by rotating the female element <NUM> around the longitudinal direction <NUM> with respect to the male element <NUM>. This brings the first engaging element portions <NUM> and the second engaging element portions <NUM> in engagement and locks further longitudinal movement of the male element <NUM> with respect to the female element <NUM>.

Aligning the male element <NUM> and the female element <NUM> by means of the cylindrical inner portion <NUM> helps to avoid jamming of the engaging elements <NUM>, <NUM>. On the other hand, allowing the male element <NUM> to tilt out of the longitudinal alignment when the male element <NUM> is only inserted into the conical inner portion <NUM> but not into the cylindrical inner portion <NUM> allows to easily remove and replace a tube <NUM>, <NUM> from a truss structure <NUM> (<FIG>), without having to disassemble the full truss structure <NUM>.

The shock absorbing element <NUM> is made from a flexible material, such as a rubber material, that absorbs vibrational loads transmitted between the connection assembly <NUM> and the tube <NUM>, <NUM>.

<FIG> shows the connection assembly <NUM> in three different states. <FIG> shows the connection assembly <NUM> in an aligned but open state. The sequence of connecting the male element <NUM> with the female element <NUM> is indicated by the arrows on top of <FIG>: first, the tube <NUM>, <NUM> (together with the female element <NUM>) is rotated by <NUM> degree around the longitudinal axis <NUM>, such that the second engaging element portions <NUM> of the male element <NUM> are facing the first plain portions <NUM> of the female element <NUM> ; then, the tube <NUM>, <NUM> is shifted in the direction of the male element <NUM> along the longitudinal axis <NUM> until the male element <NUM> has been inserted into female element <NUM> as desired; then, the tube <NUM>, <NUM> is rotated back into the original position, so that the engaging element portions <NUM>, <NUM> come into engagement and the first locking groove <NUM> and the second locking groove <NUM> are aligned and build a common channel for the clamp <NUM>; finally, the clamp <NUM> is inserted into the common channel and locked in place with the clamp hole <NUM>, to lock circumferential movement of the female element <NUM> with respect to the male element <NUM>.

<FIG> shows the connection assembly <NUM> in the assembled state after the procedure described above with regard to <FIG>.

<FIG> shows the assembled connection assembly <NUM> of <FIG> in a cut view along the longitudinal axis <NUM>. Here, the interlocking of the engaging element portions <NUM>, <NUM> as well as the arrangement of the clamp <NUM> within the locking grooves <NUM>, <NUM> is clearly visible.

<FIG> shows a tube <NUM>, <NUM> which is mounted between two fixed mounting points (male elements <NUM> fixed in place, as is shown in <FIG>) during a removal procedure.

In a first step, shown in <FIG>, the tube <NUM>, <NUM> is rotated by <NUM> degrees around the longitudinal axis <NUM> (or along the circumferential direction <NUM>), in order to unlock the engaging element portions <NUM>, <NUM>. It should be appreciated that the clamp <NUM> (not shown in <FIG>) has been removed first. After that, the tube <NUM>, <NUM> is shifted towards one of the male elements <NUM> (to the left in <FIG>) until the opposite end is free from the other male element <NUM>.

Next, as shown in <FIG>, the tube <NUM>, <NUM> is simultaneously shifted towards the free male element <NUM> (to the right side in <FIG>) and tilted out of the longitudinal axis <NUM>. This tilting is possible because of the conical inner portion <NUM>, as described above. By shifting the tube <NUM>, <NUM> to the right, the left male element <NUM> at some point no more is inside the cylindrical inner portion <NUM> but only inside the conical inner portion <NUM>, which allows tilting of the tube <NUM>, <NUM> with regard to the male element <NUM>. Reassembling, for example with a new tube <NUM>, <NUM>, may take place in the same way but in the opposite order. This procedure does not need any specialized tooling and can be done in a very time efficient manner. Further, the integrated shock absorbing element <NUM> avoids the need for separate shock absorbing structures.

Claim 1:
Connection assembly (<NUM>) for connecting a first element (<NUM>) to a second element (<NUM>), the connection assembly (<NUM>) comprising:
a male element (<NUM>); and
a female element (<NUM>);
wherein the female element (<NUM>) comprises a barrel nut (<NUM>);
wherein the barrel nut (<NUM>) comprises a conical inner portion (<NUM>) positioned at a first longitudinal region (<NUM>) and a cylindrical inner portion (<NUM>) positioned at a second longitudinal region (<NUM>);
wherein the barrel nut (<NUM>) comprises at least one first engaging element portion (<NUM>) and at least one first plain portion (<NUM>) arranged alternatingly around a circumferential direction (<NUM>) of the barrel nut (<NUM>);
wherein the male element (<NUM>) has a cylindrical bolt-like shape and comprises at least one second engaging element portion (<NUM>) and at least one second plain portion (<NUM>) arranged alternatingly around a circumferential direction (<NUM>) of the male element (<NUM>);
wherein the male element (<NUM>) further comprises flattened sides (<NUM>) at the at least one second plain portion (<NUM>); and
wherein each of the at least one second engaging element portions (<NUM>) of the male element (<NUM>) is configured to engage with a respective one of the at least one first engaging element portion (<NUM>) of the barrel nut (<NUM>);
wherein the female element (<NUM>) further comprises a shock absorbing element (<NUM>); and
wherein the shock absorbing element (<NUM>) surrounds the barrel nut (<NUM>) around its outer circumferential direction.