DE102017009679B4 - Elastomer-metal bearings - Google Patents

Abstract

Elastomer-metal bearing, with a stable, rigid installation housing with a circular cylindrical installation space (2) which has a connection device (11, 12) for a first component to be supported or which is part of the first component to be supported, with an inner element (5a , 5b), which has a stable, rigid inner part (6a, 6b; 20a, 20b; 23a, 23b) with a connection device (13) for a second component to be stored, which further has at least one shell part (8a, 8b; 26) than Outer part of the inner element (5a, 5b), wherein between the inner part (6a, 6b; 20a, 20; 23a, 23b) and the at least one shell part (8a, 8b; 26) connected to these elastomer packages (7a, 7b; 21a, 21b; 24a, 24b; 29a-29d), characterized in that at least two adjusting elements (3a, 3b) are provided, each of which has an outer tube (4a, 4b) with an outer diameter equal to the inner diameter of the circular-cylindrical installation space (2) that in each of the outer tubes (4a, 4b) ei n inner element (5a, 5b) with a volume reduction of the elastomer packages (7a, 7b; 21 a, 21 b; 24a, 24b; 29a-29d) is pressed in in comparison to the unloaded production state and with a pressure preload, so that the adjusting elements (3a, 3b) with their outer tubes (4a, 4b) lie next to one another in the axial direction and are each rotatable about the bearing cylinder axis in the installation space (2), and that an adjusting and fixing device (14; 31) is provided for setting a relative rotational position between the adjusting elements (3a, 3b) and with respect to the installation space (2) and for fixing the rotational positions that have been set.

Description

The invention relates to an elastomer-metal bearing according to the preamble of claim 1, in particular in the form of a so-called O-bearing. The term O-bearing is usually understood to mean an elastomer-metal bearing which, viewed in the axial direction, has a circular diameter of a built-in housing as a receiving eye in the manner of a bushing bearing, with an inner element with a stable, rigid inner part, with between the inner part and Receiving eye differently designed and differently arranged elastomer packages are arranged.

Generally known special embodiments are, for example, so-called OX bearings, in which four elastomer packages are arranged crosswise, or so-called OV bearings, in which two elastomer packages are arranged in a V shape on a wedge-shaped inner part.

Such a generally known, generic elastomer-metal bearing as an O-bearing has a stable, rigid installation housing with a circular cylindrical installation space that has a connection device for a first component to be supported or that is part of the first component to be supported. A generally known connection device can consist, for example, of an end connection plate or a radially protruding pin. A built-in housing can also be, for example, a receiving eye as part of a handlebar.

The generic elastomer-metal bearing also has an inner element with a stable, rigid inner part with a connection device for a second component to be mounted. The connection device on the inner part can be a known bore, a cone or a pin connection. The inner element further has at least one shell part as the outer part of the inner element, with elastomer packets connected to the inner part and the at least one shell part being arranged therewith.

In the term “elastomer-metal bearing”, the word “metal” is to be interpreted broadly in the customary manner, so that in addition to rigid, largely non-deformable metal materials, comparable other materials, in particular non-deformable rigid plastic materials, should also be included. The term “elastomer” is usually understood to mean “rubber”, although rubber substitutes should also be included. When using "rubber" as an elastomer, rubber packages and their connections are usually produced and adhered by vulcanization.

In the case of a generic elastomer-metal bearing, an inner element is pressed directly into the installation space of the installation housing with a volume reduction of the elastomer packages compared to the unloaded production state and with the application of a compressive preload. The shell part of the inner element can be created in the manner of a generally known slotted bushing from two half-shells which are spaced apart by gaps in the manufacturing state, which are closed with a diameter reduction in the pressed-in state.

A generic elastomer-metal bearing has a certain spring constant due to its fixed bearing geometry in connection with the rubber hardness used, in particular in the radial direction, without this being able to be changed on the elastomer-metal bearing. For bearing requirements with different spring constants, on the other hand, only another elastomer-metal bearing can be used that is designed and dimensioned for this. The use of separate, differently dimensioned elastomer-metal bearings is time-consuming and costly, especially when there are positional conditions in which spring constants only have to be changed and adapted in certain areas. Keeping a large number of elastomer-metal bearings in stock with different spring constants for bearing inserts that are not yet specifically available is also practically impossible for reasons of cost.

A well-known elastomer-metal bearing with an adjustable spring constant ( DE 10 2015 215 426 A1 , 7th ) uses an eccentric adjustment, the eccentric axis of rotation being offset to the cylinder axis of a receiving eye. The elastomer elements are designed eccentrically here, so that a rotation of the respective elastomer element leads to its radial compression and to a direction-dependent increase in the pretensioning force.

Another well-known elastomer-metal bearing ( DE 10 2005 054 625 A1 ) has no setting option for the spring constant with a similar bearing structure.

The object of the invention is to develop a generic elastomer-metal bearing in such a way that its spring constant, in particular the spring constant in the radial direction, can be changed and adjusted in a certain range without affecting the geometry of bearing components and / or the elastomer hardness of the elastomer material of the elastomer packages needs to be changed and adapted.

This object is achieved with the features of claim 1.

The generic elastomer-metal bearing is developed according to the invention in such a way that at least two adjusting elements are provided, each of which has an outer tube with an outer diameter equal to the inner diameter of the circular cylindrical installation space.

An inner element is pressed into each of the outer tubes of the two adjusting elements with a volume reduction of the elastomer packages compared to the unloaded production state and with a compressive preload and, if necessary, with a compression of the at least one shell part. Thus, here an inner element is pressed into the outer tubes of the actuating elements and not directly into the installation space, as in the case of the generic elastomer-metal bearing.

The adjusting elements are located in the installation space so that they can each be rotated about the bearing cylinder axis, whereby they are arranged next to one another in the axial direction.

In addition, an adjusting and fixing device is provided for setting a relative rotational position between the adjusting elements and with respect to the installation space and for fixing the rotational positions that have been set. Such setting and fixing devices can typically be designed in different designs, in particular by means of clamps and / or via fixing pins and / or screw connections, and possibly also by means of spaced-apart adjusting devices, in particular as actuators by means of adjusting levers.

Depending on the set, relative rotational position of the adjusting elements to each other and possibly with respect to an installation space, the elastomer packages of the adjusting elements are also brought into different positions relative to one another, so that differently adjustable supports result from more or less large elastomer package arrangements, especially for radial loads. As a result, an elastomer-metal bearing is advantageously obtained in a relatively simple and inexpensive manner, the spring constant of which can be changed and adjusted in a certain range, in particular in the radial direction, so that it can be easily adapted to different bearing conditions. When such adjustable elastomer-metal bearings are kept in stock, many cases of different storage tasks can be solved quickly and easily.

In a specific development, it is proposed that two identical adjusting elements are provided, which are arranged in the installation space with their outer tubes so that they can be rotated against one another, the axial length of the installation space being equal to the sum of the axial lengths of the two adjusting elements. A simple, compact elastomer bearing is thus achieved, with the adjusting elements also being identical parts. In principle, however, more than two adjusting elements can optionally also be combined with differently designed inner elements. The length of the installation space can also be chosen to be greater than the sum of the axial lengths of the adjusting elements in the case of special storage conditions.

In a preferred, specific embodiment of an elastomer-metal bearing, an inner element of an O-bearing has a cylindrical inner part with two opposing elastomer packages or four elastomer packages arranged crosswise as OX bearings, which are offset from one another in the circumferential direction with recesses in between. In addition, the shell part of the inner element is formed here by two half-shell parts which, in the manufacturing state of the inner element, are spaced apart by gaps which, in the pressed-in state, are almost closed with a reduction in the diameter of the inner element. The cylindrical inner part can have a central bore for connecting a component to be supported or it can be designed as a pin.

In a further alternative preferred embodiment, the elastomer-metal bearing is designed as a so-called OH bearing, with an inner element in each case having a cuboid inner part. On the inner part, elastomer layers, which are connected to an associated half-shell part, are applied as elastomer packages in each case on a wide parallelepipedic longitudinal surface opposite one another.
In the manufacturing state of the inner element, the two half-shell parts are also spaced apart by gaps which, in the pressed-in state, are closed with a reduction in the diameter of the inner element. In addition, an elastomer stop can be attached to one or both of the narrow longitudinal parallelepiped surfaces at a distance as a free spring travel to the half-shell parts, which stop only comes into contact with extreme loads.

In a further alternative specific embodiment, an elastomer-metal bearing is designed as a so-called OV bearing with a wedge-shaped inner part which has an elastomer layer as an elastomer package on opposite wedge surfaces. These elastomer layers are connected to a one-piece shell part, which overlaps the wedge-shaped inner part on a flattened wedge-shaped surface and the two elastomer layers and is wide open in the area of a wedge-head longitudinal surface. If necessary, with the same basic shape, the shell part can also be designed in two parts with a longitudinal gap in the area of the wedge cutting surface.

In the manufacturing state, this shell part has a relatively large opening angle in the area of the longitudinal surface of the wedge head, which, and possibly also the longitudinal gap, is reduced in connection with a reduction in the thickness of the elastomer layers and the application of a compressive prestress in the pressed-in state.

On the flattened wedge cutting surface and / or on the wedge head longitudinal surface, an elastomer stop can be arranged at a free distance from a counter surface.

If necessary, an intermediate plate known per se can be contained in at least one elastomer package, which in particular contributes to equalizing stresses in the elastomer material.

A simple, inexpensive and functional setting and fixing device can be realized in that in an outer wall of the installation space, in particular in a tubular receiving eye, adjusting slots are provided in radial planes in the area of an outer tube of the at least two adjusting elements. In the case of two adjusting elements, these are thus two adjusting slots.

In the area of each adjusting slot, at least one threaded hole is provided in an outer tube assigned to it, an adjusting and fixing screw being screwable through an adjusting slot into a threaded hole of the assigned outer tube.

A setting can then be adjusted and fixed in such a way that when the adjusting and fixing screw is loose, the rotational position of the associated outer tube can be changed and adjusted with respect to the installation space and / or with respect to another outer tube by shifting it in the adjusting slot. Such a shift can be carried out simply by hand or possibly also automatically by means of the adjusting and fixing screws protruding outward from the installation space. After a setting has been carried out, the setting and fixing screws can be screwed tight, preferably in conjunction with a lock nut, whereby the position between the respective outer tube and the installation space and thus the setting made is fixed. Such a fixation can optionally also be carried out by means of other measures known per se, such as by clamping and / or fixing pins, etc., for example.
In a further specification, the installation space can be a circular cylindrical tube as a receiving eye with two adjusting elements contained therein with their two outer tubes. The two adjusting slots assigned to the two outer tubes are offset in the axial direction and should both begin at an axial plane, one adjusting slot extending counterclockwise and one adjusting slot extending clockwise. In addition, the two adjusting slots should have the same length and extend over an adjusting angle of a maximum of 90 °. Due to the symmetry in the actuating elements used, all functionally possible different elastomer package arrangements, from the greatest possible stiffness to the lowest possible stiffness with all intermediate values, can usually be set at adjusting angles of a maximum of 90 °. In the case of larger symmetries, for example in the case of an OX bearing, all options can also be covered with shorter adjusting slots.

Furthermore, an alternative setting and fixing device is proposed in which joints with connected control levers are attached to a free end face of two adjusting elements rotatably received in an installation space. Such joints can in particular be angle joints or ball joints. The control levers can be operated externally, for example by an actuator. When using an adjusting and fixing device with adjusting slots in the installation space, the adjusting elements are thus secured against axial migration out of the installation space. In addition to or in conjunction with other embodiments of setting and fixing devices, support elements can also be arranged on the front side of the installation space to prevent the adjusting elements from moving axially out of the installation space.

Exemplary embodiments are explained in more detail with the aid of drawings.

• 1 einen teilweisen Längsschnitt durch eine Ausführungsform eines Elastomer-Metall-Lagers in der Art eines OH-Lagers mit einer ersten Ausführungsform einer Einstell- und Fixiereinrichtung,
• 2 einen Querschnitt entlang der Linie A-A aus 1,
• 3 eine perspektivische Ansicht des Elastomer-Metall-Lagers nach 1,
• 4 eine perspektivische Ansicht eines Innenelements des Lagers nach 1,
• 5 ein Elastomer-Metall-Lager in der Ausführungsform eines reinen O-Lagers mit zylindrischem Innenteil,
• 6 einen Querschnitt entlang der Linie A-A aus 5,
• 7 eine perspektivische Explosionsdarstellung des Lagers nach 5 mit einem separat abgesetzten Stellelement,
• 8 eine perspektivische Darstellung des Lagers nach 5,
• 9 eine axiale Draufsicht auf ein Elastomer-Metall-Lager in der Art eines OV-Lagers,
• 10 eine perspektivische Explosionsdarstellung des Lagers nach 9 mit einem vom Lager abgesetzten Innenelement,
• 11 eine perspektivische Darstellung des Lagers nach 9,
• 12 einen teilweisen Längsschnitt durch ein Elastomer-Metall-Lager in der Art eines OX-Lagers,
• 13 einen Schnitt entlang der Linie A-A aus 12,
• 14 eine perspektivische Ansicht des Lagers nach 12,
• 15 ein Elastomer-Metall-Lager als OH-Lager entsprechend 1, jedoch mit einer alternativen zweiten Ausführungsform einer Einstell- und Fixiereinrichtung,
• 16 einen Querschnitt entlang der Linie A-A aus 15, und
• 17 eine perspektivische Ansicht des Lagers nach 15.

Show it:

• 1 a partial longitudinal section through an embodiment of an elastomer-metal bearing in the manner of an OH bearing with a first embodiment of an adjusting and fixing device,
• 2 a cross section along the line AA 1 ,
• 3rd a perspective view of the elastomer-metal bearing according to 1 ,
• 4th a perspective view of an inner member of the bearing according to FIG 1 ,
• 5 an elastomer-metal bearing in the form of a pure O-bearing with a cylindrical inner part,
• 6th a cross section along the line AA 5 ,
• 7th an exploded perspective view of the bearing according to 5 with a separately detached control element,
• 8th a perspective view of the bearing according to 5 ,
• 9 an axial plan view of an elastomer-metal bearing in the manner of an OV bearing,
• 10 an exploded perspective view of the bearing according to 9 with an inner element separated from the bearing,
• 11 a perspective view of the bearing according to 9 ,
• 12th a partial longitudinal section through an elastomer-metal bearing in the manner of an OX bearing,
• 13th a section along the line AA 12th ,
• 14th a perspective view of the bearing according to 12th ,
• 15th an elastomer-metal-bearing as an OH-bearing accordingly 1 , but with an alternative second embodiment of an adjusting and fixing device,
• 16 a cross section along the line AA 15th , and
• 17th a perspective view of the bearing according to 15th .

The 1 to 4th represent an elastomer-metal bearing in the form of an OH bearing in different views and sections 1 This bearing has an installation space radially on the outside 2 as a circular cylindrical tube of a receiving eye, in which two identical adjusting elements 3a , 3b are arranged adjacent to one another so as to be rotatable. The adjusting elements 3a , 3b each have an outer tube 4a , 4b with an outer diameter equal to the inner diameter of the circular cylindrical installation space 2 .

In each of the outer tubes 4a , 4b is an interior element 5a , 5b pressed in, each of which has a stable inner part 6a , 6b has, on each of which is an elastomer layer on a wide longitudinal parallelepiped surface 7a , 7b is applied, each with a half-shell part 8a , 8b connected is. The half-shell parts 8a , 8b for this purpose have straight surfaces which are formed by longitudinal cylinder sections of the half-shell parts 8a , 8b are formed. There is also an elastomer stop on each of the two narrow parallelepiped surfaces 9a , 9b attached with a free spring path to the half-shell parts.

In 4th is an interior element 5a shown separately in the manufacturing state. Out 4th it can be seen that the two half-shell parts 8a , 8b in the manufacturing state of the inner element 5a by column 10a , 10b are spaced apart, which in the pressed-in state in the respective associated outer tube 4a with a diameter reduction of the inner element 5a and with the application of a pretension in the elastomer layers 7a , 7b are closed.

The installation space 2 is connected to a first component to be stored in specific applications, with in 2 for example a connected handlebar 11 and in 3rd a connection plate 12th are shown. The inner parts 6a , 6b each have a connection hole 13th to connect a second component to be stored. In the other figures, connection elements and / or components to be stored are omitted for reasons of clarity, since they are not directly relevant for the bearing adjustability according to the invention.

At the OH warehouse 1 is also an adjusting and fixing device 14th arranged, wherein in the wall of the tubular installation space 2 the control elements 3a , 3b associated adjustment slots 15a , 15b are arranged in radial planes. The adjustment slots 15a , 15b are according to the axial position of the adjusting elements 3a , 3b offset in the axial direction and both start on an axial plane 16 , with an adjusting slot 15a counterclockwise and the other adjusting slot 15b clockwise over an adjustment angle of 90 °.

The adjusting and fixing device 14th each one an adjusting slot 15a , 15b assigned adjusting and fixing screw 17a , 17b each through an adjusting slot 15a , 15b through into a threaded hole 18a , 18b of the assigned outer tube 4a , 4b can be screwed in such that when the adjusting and fixing screw is loose 17a , 17b by moving it in the adjusting slot 15a , 15b the rotary position of the associated outer tube 4a , 4b regarding the installation space 2 and the relative rotational position of the two outer tubes 4a , 4b is changeable and adjustable. By tightening the adjusting and fixing screw 17a , 17b , if necessary in connection with a lock nut, the set rotary position can be fixed.

• Auch dieses O-Lager 19 weist einen rohrförmigen Einbauraum 2 auf, in dem zwei Stellelemente 3a, 3b mit ihren Außenrohren 4a, 4b aneinanderliegend aufgenommen sind. Die Innenelemente 5a, 5b sind hier unterschiedlich ausgeführt, dergestalt, dass die Innenteile 20a, 20b hier im Vergleich zur vorstehenden Ausführungsform als zylindrische zentrale Rohrstücke ausgebildet sind, an denen jeweils zwei gegenüberliegende Elastomerpakete mit Verbindung zu den zugeordneten Halbschalenteilen 8a, 8b angebracht sind.

In the 5 to 8th is a further embodiment of an elastomer-metal bearing as a pure O-bearing in different sections and perspective representations 19th shown that in terms of its adjustment function largely with the embodiment according to the 1 to 4th corresponds, so that the same reference numerals are used for identical parts and the differences are explained below:

• This O-camp too 19th has a tubular installation space 2 on, in which two control elements 3a , 3b with their outer tubes 4a , 4b are recorded adjacent to one another. The interior elements 5a , 5b are executed differently here, in such a way that the inner parts 20a , 20b Here, in comparison to the previous embodiment, they are designed as cylindrical central pipe sections, on each of which two opposing elastomer packages are connected to the associated half-shell parts 8a , 8b are appropriate.

From the exploded view of 7th is clearly the axially adjacent arrangement of the adjusting elements 3a , 3b in the installation space 2 evident. That from the installation space 2 lifted control element 3a clearly shows this already in the outer tube 4a pressed-in inner element 5a with the half-shell parts 8a , 8b with closed columns 10a , 10b . There is also a threaded hole here 18a for an adjusting and fixing screw 17a on the circumference of the outer tube 4a recognizable.

The adjusting and fixing device 14th corresponds to that in the with the same function 1 to 3rd .

• Auch das OV-Lager 22 weist einen rohrförmigen Einbauraum 2 auf, in dem zwei Stellelemente 3a, 3b mit ihren Außenrohren 4a, 4b verdrehbar aufgenommen sind und mit einer gleichen Einstell- und Fixiereinrichtung 14 zur Einstellung einer Federkonstante verstellbar und fixierbar sind.

In the 9 to 11 an embodiment of an elastomer-metal bearing in the manner of an OV bearing is shown in a front view and perspective representations. This embodiment differs essentially only in the structure of the inner elements 5a , 5b from the above embodiments, so that the same reference numerals are used for the same parts:

• Also the OV warehouse 22nd has a tubular installation space 2 on, in which two control elements 3a , 3b with their outer tubes 4a , 4b are rotatably received and with the same adjusting and fixing device 14th are adjustable and fixable for setting a spring constant.

The interior elements 5a , 5b are different in this embodiment, as wedge-shaped inner parts 23a , 23b are used, which each have an elastomer layer on opposite partial surfaces 24a , 24b as well as other elastomer packages 25a , 25b as cylinder longitudinal sections, all of which have a shell part 26th are connected.

The shell part 26th overlaps the wedge-shaped inner part at the bottom 23a , 23b as well as the respective elastomer layers 24a , 24b and is in the upper area of the wedge-shaped inner part 23a , 23b each open, as shown in the manufacturing state of the inner element 5a in 10 can be seen, the inner element here 5a not yet in the assigned outer tube 4a is pressed in. The relatively large opening angle of the shell part becomes during the press-in process 26th reduced together with a volume reduction of the elastomer elements with the application of a compressive prestress.

On the inner parts 23a , 23b are elastomer stops on a flattened wedge cutting edge and on the longitudinal surface of the wedge head 27a , 27b attached with free spaces to opposing surfaces.

In the 12th to 14th is as a further embodiment an elastomer-metal bearing in the manner of an OX bearing 28 shown. This OX warehouse 28 is in terms of installation space 2 , the two adjusting elements received therein 3a , 3b and their associated outer tubes 4a , 4b as well as the tubular inner parts 20a , 20b , the half-shell parts 8a , 8b and the adjusting and fixing device 14th same with the embodiment according to the 5 to 8th so that the corresponding reference symbols are still used here. The difference here is that in each case between an inner part 20a , 20b and the half-shells 8a , 8b four elastomer packages 29a , 29b , 29c , 29d are spaced apart in an X shape. In the elastomer packages 29a to 29d are each intermediate sheets 30th molded.

The angular positions of the adjusting elements 3a , 3b can thus in this OX camp according to the embodiment according to the 5 to 8th adjusted and fixed.

The embodiment of an OH bearing 1 in the 15th to 17th corresponds to the embodiment according to 1 to 4th except for the setting and fixing device 14th , which is carried out differently here. To implement an alternative setting and fixing device 31 are here on the free end faces 32a , 32b the control elements 3a , 3b Joints 33a , 33b with connected levers 34a , 34b provided, which both manually and via actuators to change the angular position of the adjusting elements 3a , 3b are operable. The joints 33a , 33b are here on the half-shell parts 8a or 8b the control elements 3a , 3b arranged. The joints could, however, also be arranged on the end face of the outer tubes 4a , 4b or possibly also on the inner parts 6a , 6b take place as long as there is a possibility of rotation and adjustment of the two adjusting elements 3a , 3b is created.

In all of the embodiments explained above, by changing the rotational positions of the adjusting elements 3a , 3b a change and adjustment of the spring constant, in particular the radial spring constant, can be achieved.

Claims (11)

Elastomer-metal bearing, with a stable, rigid installation housing with a circular cylindrical installation space (2) which has a connection device (11, 12) for a first component to be supported or which is part of the first component to be supported, with an inner element (5a , 5b), which has a stable, rigid inner part (6a, 6b; 20a, 20b; 23a, 23b) with a connection device (13) for a second component to be stored, which further has at least one shell part (8a, 8b; 26) than Outer part of the Inner element (5a, 5b), wherein between the inner part (6a, 6b; 20a, 20; 23a, 23b) and the at least one shell part (8a, 8b; 26), elastomer packages (7a, 7b; 21a, 21b; 24a, 24b; 29a-29d), characterized in that at least two adjusting elements (3a, 3b) are provided, each of which has an outer tube (4a, 4b) with an outer diameter equal to the inner diameter of the circular-cylindrical installation space (2), that In each of the outer tubes (4a, 4b) an inner element (5a, 5b) with a volume reduction of the elastomer packages (7a, 7b; 21a, 21b; 24a, 24b; 29a-29d) compared to the unloaded production state and with a compressive preload pressed is that the adjusting elements (3a, 3b) with their outer tubes (4a, 4b) lie next to one another in the axial direction and each rotatable about the bearing cylinder axis in the installation space (2), and that an adjusting and fixing device (14; 31) for adjusting a relative rotational position between d en adjusting elements (3a, 3b) and with respect to the installation space (2) and for fixing set rotational positions. Elastomer-metal bearings according to Claim 1 , characterized in that two identical adjusting elements (3a, 3b) are provided, which are arranged in the installation space (2) with their outer tubes (4a, 4b) so that they can rotate against one another, the axial length of the installation space (2) being equal to the sum of the axial lengths of the two adjusting elements (3a, 3b). Elastomer-metal bearings according to Claim 1 or Claim 2 , characterized in that each inner element (5a, 5b) of an O-bearing (10) has a cylindrical inner part (20a, 20b), with two opposing elastomer packages (21a, 21b) or four crosswise arranged elastomer packages (29a, 29d) as OX bearings (28) which are arranged offset in the circumferential direction with recesses in between, and that the inner element (5a, 5b) has two half-shell parts (8a, 8b) which, in the manufacturing state of the inner element (5a, 5b), are separated by gaps (10a , 10b), which are closed in the pressed-in state with a reduction in diameter. Elastomer-metal bearings according to Claim 1 or Claim 2 , characterized in that each inner element (5a, 5b) of an OH bearing (1) has a cuboid inner part (6a, 6b), which with one of two opposing elastomer layers (7a, 7b) on each of a wide cuboid longitudinal surface with a associated half-shell part (8a, 8b) is connected, that the two half-shell parts (8a, 8b) in the manufacturing state of the inner element (5a, 5b) are spaced apart by gaps (10a, 10b) which are closed with a diameter reduction in the pressed-in state, and that an elastomer stop (9a, 9b) is attached to one or both of the narrow parallelepipedic longitudinal surfaces at a distance from the half-shell parts (8a, 8b) as free spring travel. Elastomer-metal bearings according to Claim 1 or Claim 2 , characterized in that an inner part of an OV bearing (22) has a wedge-shaped inner part (23a, 23b) which has an elastomer layer (24a, 24b) on opposite wedge surfaces, each of which is connected to a one-piece shell part (26), which each overlaps the wedge-shaped inner part (23a, 23b) on a flattened wedge edge surface and the two elastomer layers (24a, 24b) and is open in the area of a wedge head longitudinal surface, or that the shell part is made in two parts with the same basic shape with a longitudinal gap in the area of the wedge edge surface, that the shell part (26) is wide open in the manufacturing state with an opening angle and the opening angle and, if necessary, also the longitudinal gap is reduced with a volume reduction of the elastomer layers and application of a compressive preload in the pressed-in state, and that on the flattened wedge cutting surface and / or on the wedge head longitudinal surface Elastomer connector g (27a, 27b) is attached at a free distance from an opposing surface. Elastomer-metal bearings according to one of the Claims 1 to 5 , characterized in that an intermediate plate (30) is arranged in at least one elastomer package (29a-29d). Elastomer-metal bearings according to one of the Claims 1 to 6th , characterized in that, in order to implement the adjusting and fixing device (14) in an outer wall of the installation space (2), adjusting slots (15a, 15b) in radial planes each in the area of an outer tube (4a, 4b) of the at least two adjusting elements (3a, 3b) are attached that in the area of an adjusting slot (15a, 15b) in the associated outer tube (4a, 4b) at least one threaded hole (18a, 18b) is attached, and that an adjusting and fixing screw (17a, 17b) each through an adjusting slot ( 15a, 15b) can be screwed through into a threaded bore (18a, 18b) of the associated outer tube (4a, 4b), in such a way that when the adjusting and fixing screw (17a, 17b) is moved in the adjusting slot (15a, 15b) the rotational position of the associated outer tube (4a, 4b) can be changed and adjusted with respect to the installation space (2) and / or with respect to another outer tube (4a, 4b), and that by tightening the adjusting and fixing screw (17a, 17b) the set Rotation position is fixable. Elastomer-metal bearings according to Claim 7 , characterized in that the installation space (2) is a circular cylindrical tube as a receiving eye with two adjusting elements (3a, 3b) contained therein with their two that the two outer tubes (4a, 4b) assigned to the two outer tubes (4a, 4b), adjusting slots ( 15a, 15b) both start at an axial plane (16) offset in the axial direction and one adjusting slot (15a) extends counter-clockwise and one adjusting slot (15b) extends clockwise. Elastomer-metal bearings according to Claim 8 , characterized in that both adjusting slots (15a, 15b) extend with the same length over an adjusting angle of a maximum of 90 °. Elastomer-metal bearings according to one of the Claims 1 to 5 , characterized in that as the setting and fixing device (31) on a free end face (32a, 32b) of two adjusting elements (3a, 3b) rotatably received in an installation space (2), joints (33a, 33b) with connected adjusting levers (34a , 34b) are attached. Elastomer-metal bearings according to one of the Claims 1 to 9 , characterized in that support elements are arranged on the front side of the installation space to prevent the adjusting elements from moving axially out of the installation space.

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