DE102014103068B3 - Thermally compensated socket assembly with one or two kraftinvariant held elements - Google Patents

Abstract

Socket assembly with a socket (1), which has a mounting ring (2), in which over at least three connection points (4) a rotationally symmetrical element (5) is held cohesively. The socket (1) furthermore comprises first and second ring-shaped segment bodies (6, 7) in the same number as connection points (4) which are each arranged coaxially with the socket ring (2) and a tube (14) enclosing these. , In each case one of the first and one of the second segment bodies (6, 7) is in each case braced with one another via an expansion body (8), generating an axially acting clamping force (FS) and connected to the mounting ring (2). The socket (1) is dimensioned and the material is selected so that in each case a component of the axially acting clamping forces (FS), which are transmitted to the mounting ring (2) as executives (FF) and in the connection points (4) compensation forces ( FK) compensate for the reaction forces (FR) resulting from the differential expansion of the element (5) and the mounting ring (2).

Description

The invention relates to a thermally compensated socket assembly with a frame having a socket and a kraftinvariant held in this force over several junctions rotationally symmetric element. The invention also relates to a thermally compensated socket assembly having a two frame rings having, in each of which a rotationally symmetric element is held kraftinvariant via a plurality of connection points. Both mounting assemblies consist of the mounting ring or the two mounting rings and the captured element of a material with mutually different expansion coefficients.

The need for such thermally compensated socket assemblies is particularly in the optical device construction, which is why the prior art by genus-identical socket assemblies in which the captured element is an optical element, is determined.

Basically, frames for optical elements are constructed depending on the imaging quality requirements as well as the given transport, storage and use conditions of the optical system in which the captured optical element is a component. In particular, expected shock loads, possible temperature fluctuations during transport, storage and use as well as the energetic and spectral radiation influence during use play a role. Regardless of the stresses mentioned, the optical element in the socket must be kept permanently tension-free in a defined position.

To meet the above requirements, a socket assembly over a predetermined temperature range must allow a radial expansion compensation between the material of the socket and the material of the optical element. Such socket assemblies are referred to as thermally compensated.

It is customary to carry out a socket as a socket element, which is formed by a monolithic rotationally symmetrical basic body, which is divided into a rigid socket ring and a plurality of elastic connecting arms, via which an optical element is connected directly or indirectly via an auxiliary socket with the socket ring. The elastic connecting arms are connected via at least one solid-state joint with the mounting ring and are connected via a free end with the captured element directly or indirectly. They compensate for the radially different expansion of the optical element and the socket by reversibly deforming, causing a deformation-counteracting reaction force acting on the optical element at the junctions between the connection arms and the optical element. By a selective choice of material for the socket element and the structural design of the connecting arms, so that they are radially soft, or by special design measures of the optical element, which are intended to prevent acting reaction forces lead to tension in the optically active areas, attempts in the prior art to minimize the effect of strain differences or to shift the location of their effects.

In the published patent application DE 10 2006 060 088 A1 is an optical assembly with a monolithic rotationally symmetrical socket element, forming a mounting ring (there support) and three on the inner peripheral surface with the mounting ring monolithically connected elastic webs disclosed. The webs are formed as centrally and tangentially to an optical element adjacent bending beam whose ends each pass into the socket ring formed. Due to the radial elastic flexibility of the bending beam thermal expansion differences between the optical element and the socket element can be compensated, and the optical element is kept low in stress and centered within a predetermined temperature range. When the temperature changes, the tension of the bending beams changes, and thus the reaction force acting on the connecting points in the radial direction.

Also from the DE 10 2010 008 756 A1 an optical arrangement is also known with a monolithic socket element and a rotationally symmetrical optical element held therein via three elastic connecting arms (there suspension strut arrangements). The connecting arms are each formed from two parallel spring struts, wherein each one of the ends of both parallel spring legs merges into a socket ring (outer socket area) and the other ends open into a contact foot on which the optical element is fixed by gluing or soldering. The two parallel spring legs also act as a bending beam and are arranged in the direction of their compliance, that is perpendicular to the optical axis of the optical element with a distance to each other, which is small in relation to their length. From the point of view of the optical element, they run along a concave curvature line. With a radial expansion of the optical element this exerts on the contact feet radially acting forces, which leads to the deflection of the parallel spring legs in a plane perpendicular to the optical axis. In contrast to a simple, one-sided fixed strut no bending moment arises in the contact area with the optical Element. This would be explained by the fact that the suspension strut arrangement itself generates a moment in the contact region, which counteracts the torque exerted by the optical element, with the result that the contact foot can only perform a translatory movement.

The parallel spring legs are increasingly stretched with increasing temperature difference from the normal temperature, whereby an increasingly greater reaction force acts on the connection points in the radial direction.

In the not pre-published DE 10 2013 109 185 B3 is an optical assembly, comprising a rotationally symmetrical optical element and a monolithic socket element (there version), consisting of a mounting ring and at least three connection units, via which the optical element is connected to the mounting ring disclosed. The connection units each consist of three coupling, which have certain length ratios to each other and are connected to each other and with the socket ring on solid joints.

With the deflection of the connecting units, the solid-state joints are elastically deformed, whereby restoring forces are brought about in the solid-state joints, which effect a reaction force by virtue of the force flow in interaction with the optical element.

The solutions of the aforementioned documents have in common that an optical element grasped in a monolithic socket element is connected via elastic connecting arms to a mounting ring in order to be able to compensate for temperature-dependent expansion differences between the material of the optical element and the material of the socket element. Due to the different expansion, however, reaction forces are generated at the joints, which act radially on the optical element. These reaction forces can lead to tension or to the change of stresses in the optical element and thus change the imaging properties of the optical element.

At least partially compensate for these reaction forces occurring at the joints in order to keep the optical image quality constant over a predetermined temperature range, the object of the also not previously published DE 10 2013 110 750 B3 ,

The in the above DE 10 2013 110 750 B3 described thermally compensated socket assembly, there optical assembly, the idea is based, the connection arms, as they were referred to, for example, in the above three writings as webs, connecting arms or connection units, compensation elements assign. These must accordingly be present in the same number as connecting arms are present. Each of the compensation elements consists of an expansion body having a longitudinal axis and a spring element acting in the direction of the longitudinal axis, wherein the longitudinal axes lie in a plane perpendicular to the axis of the socket assembly. The connecting arms and the spring elements are arranged relative to each other so that they are relaxed at one of the limit temperatures of the temperature range, so that the reaction force over the entire temperature range acts in a same direction sense. In this case, the expansion body and the spring elements are designed so that the compensation elements each cause a temperature-dependent compensation force, which in each case causes a counterforce at the connection points between a captured optical element and the connecting arm, which counteracts the reaction force. The socket assembly builds on the linear combination of the various materials, which can result in a significant radial length of the socket assembly.

It is the object of the invention to provide a thermally compensated socket assembly in which a rotationally symmetric element or in two mounting rings two rotationally symmetric elements are held by cohesive connections of the temperature independently with an invariant holding force in a mounting ring.

This object is achieved for a socket assembly with a mounting ring according to claim 1 and for a socket assembly with two mounting rings according to claim 2.

Advantageous embodiments are specified in the subclaims.

Thermally compensated socket assemblies according to the invention will be explained in more detail below with reference to various exemplary embodiments with reference to drawings.

Show:

1a 1 is a first sectional view of a first embodiment of a socket assembly with a mounting ring and monolithic coupling connections,

1b a plan view of the socket assembly according to 1a .

1c a second sectional view of the socket assembly according to 1a .

1d a representation of the transmission of forces in the socket assembly according to 1a .

2a a sectional view of a second embodiment of a socket assembly with a mounting ring and monolithic coupling compounds,

2 B a plan view of the socket assembly according to 2a .

2c a perspective view of the socket assembly according to 2a .

3a a sectional view of a third embodiment of a socket assembly with a mounting ring and monolithic coupling connections,

3b a representation of the transmission of forces in the socket assembly according to 3a .

4 a sectional view of a fourth embodiment of a socket assembly with a mounting ring and immediate wedge connections,

5a a sectional view of a fifth embodiment of a socket assembly with a mounting ring and immediate wedge connections,

5b a representation of the transmission of forces in the socket assembly according to 5a .

6 a sectional view of a sixth embodiment of a socket assembly with a mounting ring and indirect wedge connections,

7 a sectional view of a seventh embodiment of a socket assembly with a mounting ring and indirect wedge connections,

8a a first sectional view of an eighth embodiment of a socket assembly with two mounting rings and monolithic coupling compounds,

8b a plan view of the socket assembly according to 8a .

8c a second sectional view of the socket assembly according to 8a .

8d a representation of the transmission of forces in the socket assembly according to 8a ,

9 a sectional view of a ninth embodiment of a socket assembly with two mounting rings and immediate wedge connections and

10 a sectional view of a tenth embodiment of a socket assembly with two mounting rings and indirect wedge connections.

The invention relates to two groups of socket assemblies, namely those with a mounting ring and those with two mounting rings, both of which implement the idea to transmit thermally dependent changing axial clamping forces in radial compensation forces. These counteract at connection points between the mounting rings and each held therein element to the resulting thermally dependent reaction forces. For the transmission of forces equally different constructive means can be used for both groups, which, however, bring about a similar effect based on the power transmission.

The elements are at the joints preferably cohesively in each case with the mounting ring in connection. Alternatively, they could be frictionally locked by e.g. axially acting clamping forces are maintained.

The first seven embodiments relate to socket assemblies of the first group, while the last three embodiments relate to the second group.

All embodiments of the first group of a socket assembly according to the invention basically comprise a socket 1 containing a mounting ring 2 with a symmetry axis 3 , a number of first annularly arranged segment body 6 , a number of second annularly arranged segment body 7 and a tube 14 , as well as one in the version 1 captured rotationally symmetric element 5 , The element 5 is in the mounting ring 2 over at least three connection points 4 preferably cohesively fixed by means of adhesive. It has an expansion coefficient α ₁ , which is not equal to a coefficient of expansion α ₂ , the mounting ring 2 having. The connection points 4 are preferably arranged at equal angular intervals from one another.

Regardless of how the socket assembly is executed concretely constructive, all items are the version 1 as well as the composed element 5 depending on the coefficients of expansion of the respective materials of the items concerned and the element 5 dimensioned so that within a predetermined temperature range in the joints 4 resulting tensile or compressive forces (reaction forces) due to differential radial expansion of the element 5 and the mounting ring 2 with train or Pressure forces (compensation forces) cancel, in particular by the expansion of the expansion body 8th be effected.

At a temperature range of z. B. 40 Kelvin is formed in a mounting ring 2 , z. As steel, and an element 5 , z. B. of quartz glass, at the connection points 4 on a circular line with a diameter of z. B. 30 mm, an expansion difference of about 10 microns. To counteract this expansion difference, is the mounting ring 2 slightly elastic, which by the selection of materials and / or by a suitable structural design, for. B. through slots.

The first segment body 6 with an expansion coefficient α ₃ and the second segment body 7 with an expansion coefficient α ₄ are each in an equal number as joints 4 present and annular coaxial with the mounting ring 2 arranged. The tube 14 encloses the segment body 6 . 7 radial clearance, so that they have only one degree of freedom in the axial direction of the axis of symmetry 3 remains with what the tube 14 acts as a radial abutment.

Each one of the first segment body 6 is each with one of the second segment body 7 via a respective expansion body 8th , which is a longitudinal axis 8.0 has, clamped. The longitudinal axes 8.0 are each parallel to the axis of symmetry 3 of the mounting ring 2 and each with one of the connection points 4 in a plane 9 arranged horizontally.

By the tension of the segment body 6 . 7 are temperature-dependent axially acting clamping forces F _S in the form of tensile forces or compressive forces in the direction of the longitudinal axes 8.0 generated. Components of these clamping forces F _S are on the mounting ring 2 transferred and cause on the one hand the axial bearing of the mounting ring 2 and on the other hand, a radial, partial displacement, which expresses itself in a deformation. At least about the between the first segment bodies 6 and the mounting ring 2 existing connections will each along one axis of symmetry 3 and one of the longitudinal axes 8.0 cutting line of action W, which is an angle β not equal to 90 ° with the axis of symmetry 3 includes, the transmission of a guide force F _F , which is a component of the axially acting clamping force F _S , on the mounting ring 2 causes. This calls one radially on one of the connection points 4 acting compensating force F _K , which is a component of the guide F _F , out. The first segment body 6 , the second segment body 7 , the expansion body 8th and the tube 14 each have expansion coefficients α ₃ , α ₄ , α ₅ , α ₆ , which are chosen so and the version 1 is dimensioned so that the compensation forces F _K in the joints 4 caused reaction forces F _R due to differences in expansion between the socket ring 2 and the element 5 compensate.

The angle β is advantageously greater than 30 ° and less than 60 °. The closer the angle β is to 45 °, the better the conditions for the power transmission. Accordingly, this is best at an angle β of 45 °.

According to a first embodiment of a socket assembly with only one mounting ring 2 , shown in the 1a to 1d , are the connections between the first segment bodies 6 and the mounting ring 2 each by a coupling 11 formed with the mounting ring 2 and one of the first segment bodies 6 each connected via a solid-state joint monolithic. The solid joints are designed to be stiff along the line of action W and soft to other directions of force.

The paddocks 11 each have a longitudinal axis 11.0 on which one of the lines of action W embodies. This type of connection has the particular advantage that it is frictionless. The first segment body 6 form here as in 1c can be seen, together monolithically connected together a closed ring body. By constructive measures, such as slots, which act as joints, the necessary axial freedom of movement of the first segment body 6 inside the closed ring body, outside the first segment body 6 on the second segment bodies 7 rests, preserved. At least about directly to the first segment body 6 Adjacent areas of the annular body are the first segment body 6 axially supported. To a comparison with described below embodiments of the first segment body 6 To facilitate, these are referred to as support areas.

Each in the direction of the longitudinal axes 11.0 the coupling 11 acting component of the clamping forces F _S , the leader F _F , is in the socket ring 2 introduced while a perpendicular thereto component for the deflection of the coupling 11 with the first segment body 6 connecting solid body joints leads.

The second segment body 7 are here with the tube 14 firmly connected or trained on this. They can be areas of a complete ring or just ring segments. The connection between the second segment bodies 7 and the mounting ring 2 Here is a frictional surface pairing of two perpendicular to the axis of symmetry 3 arranged surfaces.

The in the mounting ring 2 each via one of the coupling 11 introduced guide forces F _F have a radial component, hereinafter compensation force F _K , and an axial component, subsequent pressing force F _A , on.

With the pressure force F _A , the mounting ring 2 against the second segment body 7 pressed, which act here as an axial abutment.

With the compensation force F _K becomes the mounting ring 2 radially deformed and thus at least partially on the second segment bodies 7 postponed.

In 1d the force flow is shown in a socket assembly according to the first embodiment.

A second embodiment, a socket assembly with only one mounting ring 2 , shown in the 2a to 2c , differs from the first embodiment substantially in the embodiment of the first segment body 6 and the connection of the mounting ring 2 with the second segment bodies 7 ,

The first segment body 6 are here via support areas relative to the second segment bodies 7 axially supported, not with each other, as in the first embodiment, but on the mounting ring 2 are connected. It is important that these connections far enough away from the connection points 4 on the mounting ring 2 are formed so that a power transmission via these connections no influence on the balance of power in the connection points 4 entails. At the same time, these connections are axially stiff, bringing them for the mounting ring 2 a suitable indirect connection to the second segment bodies 7 represent.

The power flow, as in 1d shown, also corresponds to the power flow in the second embodiment.

A third embodiment, a socket assembly with only one mounting ring 2 , shown in the 3a and 3b , differs from the first embodiment substantially in the embodiment of the connections between the second segment bodies 7 and the mounting ring 2 ,

These are mirror-symmetrical to a radial axis of symmetry 3 extending symmetry plane S, equal to the connections between the first segment bodies 6 and the mounting ring 2 , as explained in detail in the first embodiment, formed. Advantageously, the plane of symmetry S passes through the connection points 4 ,

Either the first or the second segment body 6 . 7 are on one at the tube 14 trained paragraph 16 axially supported.

In 3b the force flow is shown in a socket assembly according to the third embodiment.

A fourth embodiment, a socket assembly with only one mounting ring 2 , shown in 4 , differs from the first embodiment substantially in the embodiment of the connections between the first segment bodies 6 and the mounting ring 2 , They each provide a frictional connection between at one of the first segment body 6 and the mounting ring 2 trained chamfer 12 One each on the two paired bevels 12 standing surface normals 12.0 each represents one of the lines of action W. In comparison to all the aforementioned embodiments, in which at least the mounting ring 2 and the first segment body 6 monolithically connected to each other, so that they are made of a same material and correspondingly have an equal expansion coefficient α ₃ equal to α ₂ , different materials with different expansion coefficients α ₃ , α ₂ can be used for this purpose.

The power flow, as in 1d shown, also corresponds to the power flow in the fourth embodiment, in which case the line of action W with the surface normal 12.0 coincides.

A fifth embodiment, a socket assembly with only one mounting ring 2 , shown in 5a , differs from the fourth embodiment substantially in the embodiment of the connections between the second segment bodies 7 and the mounting ring 2 ,

These are here, comparable to the third embodiment, mirror-symmetrical to a radial axis of symmetry 3 extending symmetry plane S, equal to the connections between the first segment bodies 6 and the mounting ring 2 , as explained in the fourth embodiment, formed. Advantageously, the plane of symmetry S passes through the connection points 4 , The connection points 4 are not beneficial to one at the element here 5 formed trained face, as shown in the previous embodiments, but on the peripheral surface of the element 5 ,

The connection points 4 can for all, including for the following embodiments, both on an end face and on a peripheral surface of the element 5 be arranged. In the former case is particularly favorable if over the connection points 4 also the weight of the element 5 should be included.

Either the first or the second segment body 6 . 7 are on one at the tube 14 trained paragraph 16 axially supported.

In 5b the force flow is shown in a socket assembly according to the fifth embodiment.

A sixth embodiment, a socket assembly with only one mounting ring 2 , shown in 6 , differs from the fourth embodiment only in that the connection between the chamfers 12 There is no direct connection, which can lead to sliding friction and thus to a stick-slip effect, but an indirect connection via at least one rolling element 13 is.

The power flow, as in 5b shown, also corresponds to the power flow in the sixth embodiment, in which case the line of action W with the surface normal 12.0 coincides.

A seventh embodiment, a socket assembly with only one mounting ring 2 , shown in 7 , differs from the sixth embodiment substantially in the embodiment of the connections between the second segment bodies 7 and the mounting ring 2 ,

These are here, comparable to the third and the fifth embodiment, mirror-symmetrical to a radial axis of symmetry 3 extending symmetry plane S, equal to the connections between the first segment bodies 6 and the mounting ring 2 , as explained in the sixth embodiment, formed. Advantageously, the plane of symmetry S passes through the connection points 4 , The connection points 4 are not beneficial to one at the element here 5 trained end face provided, but on the peripheral surface of the element 5 ,

The power flow, as in 3b also corresponds to the power flow in the seventh embodiment, in which case the line of action W with the surface normal 12.0 coincides. The on the connection points 4 acting axial components cancel (not shown), which is why the mounting ring 2 is held axially stable, without being axially applied.

All versions of the second group of a socket assembly according to the invention basically comprise a socket 1 comprising a first mounting ring 2.1 with a first axis of symmetry 3.1 , a second mounting ring 2.2 with a second axis of symmetry 3.2 , a number of first annularly arranged segment body 6 , a number of second annularly arranged segment body 7 a tube 14 , at the firmly connected, preferably monolithically connected, a plane plate 15 is arranged, as well as two in the version 1 collected rotationally symmetric element 5.1 . 5.2 , The first element 5.1 is in the first mounting ring 2.1 and the second element 5.2 is in the second frame 2.2 over at least three connection points 4 preferably cohesively fixed by means of adhesive. The first element 5.1 has an expansion coefficient α _1.1 , the unequal to an expansion coefficient α _{2.1 of} the first mounting ring 2.1 is, and the second element 5.2 has an expansion coefficient α _1.2 , which is not equal to an expansion coefficient α _{2.2 of} the second mounting ring 2.2 is, wherein the expansion coefficients α _1.1 , α _{1.2 of} the elements 5.1 . 5.2 and the expansion coefficients α _2.1 , α _{2.2 of} the mounting rings 2.1 . 2.2 may be the same, but also different. The connection points 4 are preferably arranged at equal angular intervals from one another. The first and the second symmetry axis 3.1 . 3.2 are arranged in alignment with each other.

The number of connection points 4 in the first setting ring 2.1 is equal to the number of joints 4 in the second frame 2.2 , in each case two of the connection points 4 in one the symmetry axes 3.1 . 3.2 inclusive level 9 lie, which include mutually equal angular distances.

Regardless of how the socket assembly is executed concretely constructive, all items are the version 1 as well as the two composed element 5.1 . 5.2 depending on the coefficients of expansion of the respective materials of the items concerned as well as the elements 5.1 . 5.2 dimensioned so that, despite different radial extent of the elements 5.1 . 5.2 and the mounting rings 2.1 . 2.2 within a given temperature range, the mounting rings 2.1 . 2.2 be so reversibly deformed that affect the joints 4 cancel acting tensile or compressive forces.

At a temperature range of z. B. 40 Kelvin is formed at a first mounting ring 2.1 , z. B. steel, and a first element 5.1 , z. B. of quartz glass, at the connection points 4 on a circular line with a diameter of z. B. 30 mm, an expansion difference of about 10 microns.

With an equal second mounting ring 2.2 , z. B. aluminum, and a second element 5.2 , z. B. also made of quartz glass, arises at the connection points 4 an expansion difference of approx. 13 μm. In order to compensate for different expansion differences, it is preferred a different angle β realized over the connections. In the following embodiments, and correspondingly in the in this 8d shown flow of forces, is to be assumed simplified that the mounting rings 2.1 . 2.2 and the elements 5.1 . 5.2 made of the same material and the same dimensions. To counteract the expansion differences, the mounting rings 2.1 . 2.2 slightly elastic, which by the selection of materials and / or by a suitable structural design, for. B. through slots.

The first annularly arranged segment body 6 and second annularly arranged segment body 7 as well as the tube 14 are to the symmetry axes 3.1 . 3.2 the two mounting rings 2.1 . 2.2 arranged coaxially and in the same number as joints 4 available. The tube 14 serves as a radial abutment for the first and second annularly arranged segment bodies 6 . 7 and encloses these without play.

Each one of the first segment body 6 is each with one of the second segment body 7 via a respective expansion body 8th , which is a longitudinal axis 8.0 has, an axially acting clamping force F _S in the direction of the longitudinal axis 8.0 generating, braced. The longitudinal axes 8.0 are each parallel to the symmetry axes 3.1 ; 3.2 and with two of the connection points 4 in a plane 9 arranged horizontally. Between the first segment bodies 6 and the first mounting ring 2.1 there is one connection each. This connection is designed so that each along a the first axis of symmetry 3.1 and one of the longitudinal axes 8.0 cutting line W, which is an angle β not equal to 90 ° with the first axis of symmetry 3.1 includes, the transmission of a guide force F _F , which is a component of the axially acting clamping force F _S , on the first mounting ring 2.1 is effected.

The leader F _F calls within the first mounting ring 2.1 a radial on one of the connection points 4 acting component, hereinafter compensation force F _K , and one axially on a plane plate 15 acting component, hereinafter pressing force F _A , forth.

Between the second segment bodies 7 and the second mounting ring 2.2 There are connections that lead to one between the socket rings 2.1 ; 2.2 radially symmetrical plane S mirror symmetry to the connections between the first segment bodies 6 and the first mounting ring 2.1 are formed so that mirror-symmetrical an equal power flow takes place as described.

In the symmetry plane S is the with the tube 14 rigidly connected plane plate 15 arranged. On both sides are the mounting rings 2.1 . 2.2 at.

The expansion coefficients α ₃ , α ₄ , α ₅ , α _{6 of} the first segment body 6 , the second segment body 7 , the stretch body 8th and the tube 14 are so chosen and the version 1 with all their individual parts, including the first segment body 6 , the second segment body 7 , the stretch body 8th and the tube 14 , is dimensioned such that the compensation forces F _K , due to differences in expansion between the first mounting ring 1.1 and the first element 5.1 or the second mounting ring 2.1 and the second element 5.2 , in the joints 4 compensate for the reaction forces F _R.

The angle β is advantageously greater than 30 ° and less than 60 °. The closer the angle β is to 45 °, the better the conditions for the power transmission. Accordingly, this is best at an angle β of 45 °.

An eighth embodiment, a socket assembly with two mounting rings 2.1 . 2.2 , is in the 8a to 8d shown.

The connections between the first segment bodies 6 and the first mounting ring 2.1 and between the second segment bodies 7 and the second mounting ring 2.2 are each through a paddock 11 formed with the mounting ring 2.1 . 2.2 and one of the first and second segment bodies 6 . 7 each connected via a solid-state joint monolithic. The solid joints are designed to be stiff along the line of action W and soft to other directions of force.

The paddocks 11 each have a longitudinal axis 11.0 on which one of the lines of action W embodies. This type of connection has the particular advantage that it is frictionless. The first segment body 6 and the second segment body 7 form here as in 8c can be seen, each connected monolithically together in each case a closed ring body. By constructive measures, such as slots, which act as joints, the necessary axial freedom of movement of the first and second segment body 6 . 7 each within the closed ring body, outside the segment body 6 . 7 at least partially on the plane plate 15 abutment, preserved. At least about the directly to the segment body 6 . 7 Adjacent areas of the annular body are the segment body 6 . 7 axially supported. Each in the direction of the longitudinal axes 11.0 the coupling 11 acting component of one of the clamping forces F _S , an executive F _F , is in the mounting rings 2.1 . 2.2 introduced while a perpendicular component for deflection the paddocks 11 with the segment bodies 6 . 7 connecting solid body joints leads.

The initiated managers F _F each have a radial component, subsequently compensating force F _K, and an axial component, following pressing force F _A on.

With the pressure force F _A , the mounting rings 2.1 . 2.2 against the plane plate 15 pressed, which acts here as an axial abutment.

With the compensation forces F _K become the mounting rings 2.1 . 2.2 locally radially deformed and thus at least partially on the plane plate 15 adjoining moved.

In 8d the force flow is shown in a socket assembly according to the eighth embodiment.

Opposite duplicating versions 1 with only one mounting ring 2 and accordingly only one composed element 5 has a version 1 with two mounting rings 2.1 . 2.2 and accordingly two composed elements 5.1 . 5.2 some advantages. Thus, the necessary axial space can be shortened, as in contrast to a double version of a version with only one mounting ring 2 the first segment body 6 the first version 1 as second segment body 7 the second version 1 act and vice versa. In addition, there is a self-contained force flow and a thermally and mechanically symmetrical behavior of the two mounting rings 2.1 . 2.2 ,

A ninth embodiment, a socket assembly with two mounting rings 2.1 . 2.2 , shown in 9 , differs from the eighth embodiment in the embodiment of the connections between the segment bodies 6 . 7 and the mounting rings 2.1 . 2.2 ,

They each provide a non-positive connection between each one of the segment body 6 . 7 and the mounting rings 2.1 . 2.2 trained chamfer 12 One each on the two paired bevels 12 standing surface normals 12.0 each represents one of the lines of action W. In comparison to the aforementioned embodiment, in which the mounting ring 2.1 . 2.2 and the segment body 6 . 7 are each monolithically connected to each other, so that they consist of a same material and correspondingly have an equal expansion coefficient α ₃ equal to α ₂ , here different materials with different expansion coefficients α ₃ , α ₂ can be selectively used here. Such a connection can also be understood as a wedge connection.

The connection points 4 can also in the embodiments with two mounting rings 2.1 . 2.2 both on an end face and on a peripheral surface of the elements 5.1 . 5.2 be arranged.

The power flow, as in 8d is shown, also corresponds to the power flow in the ninth embodiment, in which case the lines of action W with the surface normal 12.0 coincide.

A tenth embodiment, a socket assembly with two mounting rings 2.1 . 2.2 , shown in 10 , differs from the ninth embodiment only in that the connections between the chamfers 12 are no direct connections, which can lead to sliding friction and thus to a stick-slip effect, but indirect connections in each case via at least one rolling element 13 ,

The power flow, as in 8d is shown, also corresponds to the power flow in the tenth embodiment, in which case the lines of action W with the surface normal 12.0 coincide. The number of connection points 4 is in all embodiments, for the sake of clarity in the figures, three, with these at an angular distance of 120 ° to each other evenly around the axis of symmetry 3 respectively. 3.1 . 3.2 at the element 5 respectively. 5.1 . 5.2 are distributed. There may also be more connection points 4 be provided, which then also advantageous about the axis of symmetry 3 respectively. 3.1 . 3.2 are arranged evenly distributed.

In the illustrations of the power flow in the different embodiments, for the sake of simplicity, only the transfer of the clamping force F _S to a joint 4 considered. This representation comes closest to a version in which the mounting ring 2 or the mounting rings 2.1 . 2.2 , the segment body 6 . 7 and the tube 14 are made of a same material, so that the compensation of the reaction force F _R is caused in the connections substantially only through the axially acting clamping force F _S.

LIST OF REFERENCE NUMBERS

1

version

2

mounting ring

2.1

first mounting ring

2.2

second mounting ring

3

Symmetry axis of the mounting ring 2

3.1

first axis of symmetry (of the first mounting ring 2.1 )

3.2

second axis of symmetry (of the second mounting ring 2.2 )

4

junction

5

element

5.1

first element

5.2

second element

6

first segment body

7

second segment body

8th

expansion body

8.0

Longitudinal axis (of the expansion body 8th )

9

level

11

paddock

11.0

Longitudinal axis (the coupling 11 )

12

chamfer

12.0

Surface normal (the chamfer 12 )

13

rolling elements

14

tube

15

Planplatte

16

paragraph

F _S

tension

F _F

executive

F _K

compensation force

F _A

pressure force

F _R

reaction force

W

line of action

S

plane of symmetry

α _1.1

Coefficient of expansion of the element 5

α ₁

Expansion coefficient of the first element 5.1

α _1.2

Expansion coefficient of the second element 5.2

α ₂

Expansion coefficient of the mounting ring 2

α _2.1

Expansion coefficient of the first mounting ring 2.1

α _2.2

Expansion coefficient of the second mounting ring 2.2

α ₃

Expansion coefficient of one of the first segment body 6

α ₄

Expansion coefficient of one of the second segment body 7

α ₅

Expansion coefficient of one of the expansion bodies 8th

α ₆

Coefficient of expansion of the tube 14

β

 angle

Claims (13)

Socket assembly with a socket ( 1 ), comprising a mounting ring ( 2 ), an axis of symmetry ( 3 ), and one in the mounting ring ( 2 ) via at least three connection points ( 4 ) fixed rotationally symmetric element ( 5 ), where the element ( 5 ) an expansion coefficient (α ₁ ) not equal to an expansion coefficient (α ₂ ) of the mounting ring ( 2 ), characterized in that the socket ( 1 ) in each case in the same number as connecting points ( 4 ), to the mounting ring ( 2 ) coaxially arranged first annularly arranged segment body ( 6 ) and second annularly arranged segment body ( 7 ) as well as a tube ( 14 ), wherein the first segment body ( 6 ) or the second segment body ( 7 ) on a tube ( 14 ) paragraph ( 16 ) are axially supported and thus act as an axial abutment and the tube ( 14 ) the segment bodies ( 6 ; 7 ) radially surrounds clearance and thus acts as a radial abutment, in each case one of the first segment body ( 6 ) each having one of the second segment bodies ( 7 ) via a respective expansion body ( 8th ), which has a longitudinal axis ( 8.0 ), an axially acting clamping force (F _S ) in the direction of the longitudinal axis ( 8.0 ), is braced, and the longitudinal axes ( 8.0 ) in each case parallel to the axis of symmetry ( 3 ) and with one of the connecting points ( 4 ) in one level ( 9 ) lying between the first segment bodies ( 6 ) and the mounting ring ( 2 ) and the second segment bodies ( 7 ) and the mounting ring ( 2 ) in each case a connection, wherein the connections between the first segment bodies ( 6 ) and the mounting ring ( 2 ) are designed so that in each case along one the axis of symmetry ( 3 ) and one of the longitudinal axes ( 8.0 ) intersecting line of action (W) having an angle (β) not equal to 90 ° with the axis of symmetry ( 3 ), the transmission of a guide force (F _F ), which is a component of the axially acting clamping force (F _S ), on the socket ring ( 2 ) is caused, the one radially to one of the connection points ( 4 ) acting compensating force (F _K ) causes, wherein the first segment body ( 6 ), the second segment body ( 7 ), the expansion bodies ( 8th ) and the tube ( 14 ) each have expansion coefficients (α ₃ , α ₄ , α ₅ , α ₆ ), which are selected so and the version ( 1 ) is dimensioned so that the compensation forces (F _K ) in the connection points ( 4 ) caused reaction forces (F _R ) due to differences in expansion between the socket ring ( 2 ) and the element ( 5 ) compensate. Socket assembly with a socket ( 1 ), comprising a first mounting ring ( 2.1 ), a first axis of symmetry ( 3.1 ) having at least three connection points ( 4 ) in the first mounting ring ( 2.1 ) cohesively fixed first rotationally symmetric element ( 5.1 ) and a second mounting ring ( 2.2 ), a second axis of symmetry ( 3.2 ) having at least three connection points ( 4 ) in the second mounting ring ( 2.2 ) fixed second rotationally symmetric element ( 5.2 ), the elements ( 5.1 . 5.2 ) each have a coefficient of expansion (α _1.1 , α _1.2 ), the unequal each having an expansion coefficient (α _2.1 , α _2.2 ) of the mounting rings ( 2.1 . 2.2 ), and the symmetry axes ( 3.1 . 3.2 ) are arranged in alignment, wherein the socket ( 1 ) in an equal number, such as connection points ( 4 ), to the mounting rings ( 2.1 . 2.2 ) coaxially arranged first annularly arranged segment body ( 6 ) and second annularly arranged segment body ( 7 ) as well as a tube ( 14 ), which the segment body ( 6 . 7 ) radially surrounds clearance and thus acts as a radial abutment, in each case one of the first segment body ( 6 ) each having one of the second segment bodies ( 7 ) via a respective expansion body ( 8th ), which has a longitudinal axis ( 8.0 ), an axially acting clamping force (F _S ) in the direction of the longitudinal axis ( 8.0 ), is braced and the longitudinal axes ( 8.0 ) in each case parallel to the symmetry axes ( 3.1 . 3.2 ) and with two of the connection points ( 4 ) in one level ( 9 ) lying between the first segment bodies ( 6 ) and the first mounting ring ( 2.1 ) in each case a connection, by means of which in each case along one of the first axis of symmetry ( 3.1 ) and one of the longitudinal axes ( 8.0 ) intersecting line of action (W) having an angle (β) not equal to 90 ° with the first axis of symmetry ( 3.1 ), the transmission of a guide force (F _F ), which is a component of the axially acting clamping force (F _S ), on the first mounting ring (F 2.1 ), which within the first frame ( 2.1 ) a radial on one of the connection points ( 4 ) acting compensating force (F _K ), between the second segment bodies ( 7 ) and the second mounting ring ( 2.2 ) There are connections to one between the frame rings ( 2.1 . 2.2 ) lying radially symmetry plane (S) mirror-symmetrical to the connections between the first segment bodies ( 6 ) and the first mounting ring ( 2.1 ) are formed and in the plane of symmetry (S) one with the tube ( 14 ) rigidly connected, acting as an axial abutment plan plate ( 15 ) is arranged, on which the mounting rings ( 2.1 . 2.2 ), wherein the first segment body ( 6 ), the second segment body ( 7 ), the expansion bodies ( 8th ) and the tube ( 14 ) each have expansion coefficients (α ₃ , α ₄ , α ₅ , α ₆ ), which are selected so and the version ( 1 ) is dimensioned so that the compensation forces (F _K ) in the connection points ( 4 ) due to differences in expansion between the first mounting ring ( 1.1 ) and the first element ( 5.1 ) as well as the second mounting ring ( 2.1 ) and the second element ( 5.2 ) compensate for reaction forces (F _R ). Socket assembly according to claim 1, characterized in that the connections between the first segment bodies ( 6 ) and the mounting ring ( 2 ) each by a coupling ( 11 ) formed with the mounting ring ( 2 ) and one of the first segment bodies ( 6 ) is connected monolithically via a solid-state joint, wherein the coupling ( 11 ) each have a longitudinal axis ( 11.0 ), which represents one of the lines of action (W). Socket assembly according to claim 2, characterized in that the connections between the first segment bodies ( 6 ) and the first mounting ring ( 2.1 ) each by a coupling ( 11 ) formed with the first mounting ring ( 2.1 ) and one of the first segment bodies ( 6 ) is connected monolithically via a solid-state joint, wherein the coupling ( 11 ) each have a longitudinal axis ( 11.0 ), which represents one of the lines of action (W). Socket assembly according to claim 3, characterized in that the connections between the second segment bodies ( 7 ) and the mounting ring ( 2 ) mirror-symmetrical to a radial plane of symmetry (S), equal to the connections between the first segment bodies ( 6 ) and the mounting ring ( 2 ), and the plane of symmetry (S) through the connection points ( 4 ) runs. Socket assembly according to claim 1, characterized in that the connections between the first segment bodies ( 6 ) and the mounting ring ( 2 ) in each case a frictional connection between on the mounting ring ( 2 ) and in each case on one of the segment bodies ( 6 ) chamfers ( 12 ) and one on the chamfer ( 12 ) surface normal ( 12.0 ) represents one of the lines of action (W). Socket assembly according to claim 2, characterized in that the connections between the first segment bodies ( 6 ) and the first mounting ring ( 2.1 ) in each case a frictional connection between at one of the first segment body ( 6 ) and the first mounting ring ( 2.1 ) chamfers ( 12 ) and one on the chamfer ( 12 ) surface normal ( 12.0 ) represents one of the lines of action (W). Socket assembly according to claim 6 or 7, characterized in that the compounds of indirect connections in each case via at least one rolling element ( 13 ) are. Socket assembly according to claim 5 or 6, characterized in that the connections between the second segment bodies ( 7 ) and the mounting ring ( 2 ) mirror symmetry to a radial plane of symmetry (S) as the connections between the first segment bodies ( 6 ) and the mounting ring ( 2 ) are formed. Socket assembly according to claim 1, characterized in that the connections between the second segment bodies ( 7 ) and the mounting ring ( 2 ) each non-positive connections between two radially to the axis of symmetry ( 3 ) are extending surfaces and the second segment body ( 7 ) rigid with the tube ( 14 ) are connected. Socket assembly according to claim 1 or 2, characterized in that the angle (β) is equal to 45 °. Socket assembly according to claim 1 or 2, characterized in that the lines of action (W) in each case by one of the connection points ( 4 ). Socket assembly according to claim 1 or 2, characterized in that the segment body ( 6 . 7 ) are integrated in a closed ring body.

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