Abstract:
A suspension device of an agricultural machine is intended for the mounting and elastic bearing of an implement, with a pivot arm carrying the implement, which pivot arm is elastically or pivotably mounted by means of at least one bearing section at a flange tube, which flange tube extends transversely to the work direction, with the bearing section surrounding the flange tube circumferentially and approximately coaxially, and with at least one elastic bearing element positioned between the bearing section and the section of the flange tube surrounded thereby, which elastic bearing element extends with its longitudinal axis essentially parallel to the pivoting axis of the pivot arm and to the longitudinal axis of the flange tube. Lateral support of the suspension device is provided by a guide element is on the suspension device having at least one guide surface for the lateral support and guidance of the implement.

Description:
CROSS-REFERENCE TO RELATED APPLICATION 
       [0001]    This application claims priority from German Application No. DE 10 2014 111 136.2 filed Aug. 5, 2014, the contents of which are incorporated herein by this reference. 
       BACKGROUND 
       [0002]    The present invention relates to a suspension device of an agricultural machine with the features of the independent claim  1 . 
         [0003]    Such suspension devices or, as the case may be, agricultural machines with such suspension devices, are known from EP 1 060 649 B1 or from EP 1 880 590 A1, for example. In these devices known from the prior art, various tillage implements and sowing implements are attached to pivot arms such that the result is a suitable implement arrangement for the respectively intended use. The pivot arms are pivotably mounted on so-called flange tubes, and they have bearing sections, which surround the flange tube, with elastic bearing elements or squeeze bearing elements or rubber elements being arranged in each case between the mentioned bearing sections and the sections of the flange tube surrounded thereby. 
         [0004]    The bearing sections of the pivot arms together with the flange tube accommodated therein as a rule have a square contour, and in their initial position they are rotated by approximately 45 degrees relative to each other, resulting in four triangle-shaped reception chambers for one bearing element each. Other combinations of flange tube and bearing section, such as for instance triangle-shaped contours, are, however, also possible and known. 
         [0005]    One problem with such suspension devices frequently lies in stabilizing them and in the guidance between the bearing sections and the flange tube. An asymmetric arrangement of the tillage implements or the sowing implements at the pivot arm, such as for example, an inclined position of the coulter disks in relation to the driving direction or in relation to a perpendicular plane thereto, will cause transverse and lateral forces to build up, which partly become so great as to lead to substantial tilting moments, which in turn result in laterally tilting or twisting of the suspension devices or the pivot arms, as the case may be. By this tilting or by this inclined position, as the case may be, the pivot arm will moreover tend to shift transversely to the driving direction or along the flange tube parallelly thereto, as the case may be. Furthermore, the elastic bearing elements tend to become dislocated from the bearing sections. 
         [0006]    EP 1 880 590 A1 already proposes a solution for solving the above-mentioned problems. For this purpose, the elastic bearing elements do not have the usual cylindrical design, but are rather designed to have a truncated cone form, at least partly and, in particular, at their end sections. This results in greater preload forces in the respective end sections of the bearing section, which is intended to lead not only to an improved lateral support, but also to prevent a dislocation of the bearing elements. A disadvantage of such a design, however, is that while the lateral support is improved, the possibility of twisting still remains. It is also possible that the force for the lateral support is insufficient due to the material quality of the bearing elements. This can be counteracted by increasing the material quality or the material hardness, leading, however, in turn to the risk that the preload forces become too great so that it can no longer be ensured that the suspension device can perform a sufficient pivoting motion in relation to the flange tube. 
         [0007]    Disclosed in EP 1 541 003 A1 is moreover an overload protection, in particular for a soil working implement, with an elastic bearing, which consists of elastic bearing elements and two bearing shells, and, attached to the lower bearing shell, a shaft with a disk for tilling. In an unmounted state, the elastic bearing elements have an essentially round cross section with at least one longitudinally flattened portion. This flattened portion is intended to improve the elastic material characteristics of the bearing elements; the lateral support is likewise intended to be improved by such a design of the bearing elements. 
         [0008]    DE 10 2009 058 342 A1 discloses a suspension device of an agricultural machine, which suspension device is particularly suited for tillage implements. The device comprises at least a pivot part carrying the machine part and a pivot part carrier, on which the pivot part is pivotably mounted. With a bearing section, the pivot part can surround the pivot part carrier in such a manner that bearing chambers are formed between the bearing section of the pivot part and the pivot part carrier. Elastic bearing elements can be associated with the bearing chambers, which bearing elements undergo an at least partial elastic deformation when the pivot part is pivoted. This known suspension, however, has the disadvantage that the forces of the lateral support depend on the material quality or on the Shore hardness of the bearing elements. This means that although a greater Shore hardness could improve the lateral support, this would, however, in this instance lead to decreasing the pivoting possibilities because greater preload forces also go along with a greater Shore hardness. 
         [0009]    Also known are suspension devices, in which the flange tube and the inner surface of the bearing shells have the same cross section such that the inner surface of the bearing shell can pivot radially about the flange tube and is thus laterally supported. The suspension device in such a design, however, can also shift axially; and in addition, the dimensions of the flange tube and of the bearing shells must be adhered to very precisely, making this a very elaborate and costly approach. 
       SUMMARY 
       [0010]    With regard to the known prior art, the object of the invention is to create a simply structured suspension device of an agricultural machine, the suspension device having elastic bearing elements, for which suspension device a sufficient lateral guidance or, as the case may be, support can be ensured even if great transverse and lateral forces prevail, for which a lateral shifting on a machine frame or, as the case may be, on a flange tube is prevented, and for which a dislocation of the bearing elements from the bearing sections is suppressed. 
         [0011]    The objects of the invention are achieved by the subject matter of independent claim  1 . Features of advantageous developments of the invention are specified in the dependent claims. In order to solve the stated object, the invention proposes a suspension device with at least one additional guide element assigned to it, which guide element is formed as a single part or in multiple parts and which has at least one guide surface and/or slide surface for the lateral support and/or guidance of the implement arrangement. 
         [0012]    The invention relates to a suspension device of an agricultural machine, the suspension device being intended for the mounting and the elastic bearing of an implement arrangement for tilling and/or sowing, with at least one pivot arm carrying the implement arrangement, which pivot arm is elastically and/or pivotably mounted by means of at least one bearing section at a carrier tube or flange tube of the agricultural machine, which carrier tube or flange tube extends preferably transversely to the work direction. The bearing section surrounds the carrier tube or flange tube around its periphery and in an approximately coaxial alignment with the carrier tube or flange tube. At least one elastic bearing element is provided between the bearing section and the section of the carrier tube or flange tube surrounded thereby, which elastic bearing element extends with its longitudinal axis essentially parallel to the pivoting axis of the pivot arm and to the longitudinal axis of the carrier tube or flange tube, and which elastic bearing element undergoes an at least partial deformation by pivoting motions of the pivot arm. At least one additional guide element is associated with the suspension device, which guide element is formed in a single part or in multiple parts and has at least one guide surface and/or slide surface. If the guide element is formed in a single part, for example as a ring element, its inner contour or its guide surface, as the case may be, at least sectionally has a contour that is essentially the same as that of the flange surface of the flange tube and/or a cross section that is essentially the same as that of the flange surface of the flange tube. Optionally, the outer contour or, as the case may be, the guide surface of the guide element at least sectionally has a contour that is essentially the same as that of the bearing surface of the bearing sections and/or a cross section that is essentially the same as that of the of the bearing surface of the bearing sections. The inner contour and/or the outer contour thus in each case serve as guide surfaces or slide surfaces, respectively. The at least one guide element is thus designed in such a manner that it largely suppresses the axial shifting or twisting, as the case may be, which occurs due to the transverse or lateral forces, as the case may be, and forms a plain bearing, for example. The suspension device and/or the guide element can furthermore have attaching means associated with it by means of which an axial shifting is suppressed, and the guide element and the attaching means can in turn form a unit. A plain bearing preferably results by way of the contour and/or cross section of the flange surface being essentially the same as that of the flange tube, or by way of the contour and/or cross section of the guide surface being essentially the same as that of the bearing sections of the guide element. The transverse forces or, as the case may be, the tilting forces acting on the implement arrangement can be absorbed by the guide element or by the plain bearing, as the case may be. For this purpose, the guide element preferably has a greater hardness than the elastic rubber elements. 
         [0013]    Furthermore, the guide element can be formed in multiple parts and be composed, for example, of an inner guide segment and an outer support segment. In this instance, the guide segment can have an inner contour, which at least sectionally has a contour and/or cross section that is essentially the same as that of the flange surface of the flange tube. The support segment can in turn have an outer contour, which at least sectionally has a contour and/or cross section that is essentially the same as that of the bearing surface of the bearing sections. In addition, the guide segment has an outer contour or a slide surface, as the case may be, and the support segment has an inner contour or a slide surface, as the case may be, which have largely the same contour and/or cross section, whereby a plain bearing results or whereby the guide segment and the support segment can slide upon one another, as the case may be. 
         [0014]    The invention provides a flange tube that is part of a frame construction of an agricultural machine, for example, to which a multitude of suspension devices according to the invention with implement arrangements attached thereto can be mounted, which suspension devices are spaced apart from one another and, as the case may be, offset in relation to one another over several rows. The flange tube can have an essentially square contour and/or cross section, but at least sectionally cylindrical or triangular or such like contours or cross sections or any conceivable form would also be possible, as the case may be. It should be noted in this context that the carrier tube or flange tube can generally also be formed from a solid piece of material or as an open shape (e.g. a T-profile or the like). If the term “tube” is therefore used herein to generally refer to a closed hollow profile, this is by no means intended to be understood in a restrictive sense in the context of the present invention, but rather to the effect that the carrier tube or flange tube can also be formed from a solid piece of material or as an open shape. 
         [0015]    The suspension device consists of an upper and a lower bearing section, for example, which each have a contour that is to the greatest possible extent the same as that of the flange tube. The upper and the lower bearing sections of the suspension device usually have a larger cross section than the flange tube. In addition, a pivot arm is attached to at least one of the bearing sections. According to the desired area of application, the various tillage implements and/or sowing implements are mounted thereto such that various different implement arrangements can result. The implement arrangements can be seed drill coulters, such as for instance single disk coulters or double disk coulters or coulter holders or tooth holders or the like. 
         [0016]    In the basic position, the bearing sections or, as the case may be, the pivot arm, are arranged to be twisted, for example by an angle of approximately 45 degrees, in relation to the flange tube. Inserted into the free or, as the case may be, hollow spaces resulting thereby and extending parallel to the flange tube, are, according to the cross section of the bearing sections, two, three, or more elastic bearing elements, preferably in the form of so-called rubber cord elements. The pivot arm is pivotably movably connected radially to the flange tube by way of these bearing elements. This pivotable movability is influenced by various factors, for example, by the number of bearing elements present or by the material or the degree of hardness of the bearing elements, as the case may be. Furthermore, the bearing elements or, as the case may be, the guide elements can in each case define the preload force of the pivot arm or of the implement arrangement, as the case may be. That is to say that the closer the bearing elements are pressed together, the greater is the preload force. In the instance of the guide elements, the preload force of the bearing elements can be increased or reduced, as the case may be, according to the ratio of the cross sections of inner guide surface to outer guide surface. 
         [0017]    The invention further provides that at least one additional guide element is assigned to the suspension device. This guide element is designed, for example, such that it supports itself and/or such that it slides along with its inner guide surface upon the outer surface or, as the case may be, upon the flange surface of the flange tube, for which purpose both surfaces at least sectionally have contours and/or cross sections that are to the greatest possible extent the same. It can be additionally provided that this suspension device supports itself and/or that it slides along with its outer guide surface upon the inner surface or, as the case may be, upon the bearing surface of the bearing sections. The guide element is thus designed in such a manner it is capable of suppressing the axial shifting or, as the case may be, the twisting, which occurs due to the transverse or lateral forces, as the case may be, and that the implement arrangement can support itself by means of the guide element upon the flange tube and/or upon the bearing sections. For this purpose, the guide element is designed as plain bearing, for example, such that the implement carrier can slide along the guide element and/or along the flange tube and/or along the bearing sections. 
         [0018]    It should already be noted here that the definition of a “contour and/or a cross section that is at least sectionally to the greatest possible extent the same” is to be understood to the effect that the contour or, as the case may be, the cross section of the guide element is designed such that the guide element can support itself or, as the case may be, slide upon the bearing sections or upon the flange tube. This would also already be the case, for example, in a combination of a round and a square cross section at the corners, for example, of the square cross section. In this instance, the wear for such a point bearing can be very high. 
         [0019]    In order to counteract axial shifting of the suspension device along the pivot arm carrier, at least one attaching means can be associated with the suspension device and/or to the guide element. The attaching means can form a fixedly connected part together with the guide element. Alternatively, the attaching means could also be designed such that it is attached to the flange tube by means of screws or welding, for example. Any type of detachable and undetachable connections are possible and conceivable in this context. The attaching means could also be formed by a screw connection, which is present in or at the guide element, for example. 
         [0020]    The guide element can be attached to the suspension device in various different places. It is conceivable to arrange a guide element centrally and the bearing elements both on the left side and on the right side next to it. The guide element could likewise be arranged on the left and/or on the right side at the edge sections of the suspension device. In a preferred embodiment, these guide elements are attached on the left and on the right side of the edge sections of the suspension device in order to thus achieve a large support distance and thereby strongly reduce the forces acting on the guide elements. This is particularly important with regard to selecting the material for the guide elements, as the surface pressure and thus the wear can be greatly minimized thereby. A further advantage in such an arrangement is that a lateral dislocation of the elastic bearing elements is prevented or suppressed, as the case may be. 
         [0021]    A further development of the invention provides that the at least one guide element has at least one contour as a guide surface and/or slide surface, which contour is to the greatest possible extent circular. The circular contour is not intended to be understood in a restrictive sense; any other forms of embodiments are also conceivable. The guide element serves to suppress the axial shifting or, as the case may be, the twisting, which occurs due to the transverse or lateral forces, as the case may be. In addition, the bearing sections can support themselves by means of the guide element upon the flange tube. 
         [0022]    In order to ensure easy mounting, the guide element can be formed in two parts or also in multiple parts. The guide element can moreover be composed of an inner guide segment and an outer support segment, where these can in turn also be formed in two parts or in multiple parts. If the flange surface of the flange tube has an angular form, for example, then the inner contour of the inner guide segment and of the outer guide segment can be correspondingly formed. The same applies to a cylindrical and to any other embodiment forms of the flange tube. Furthermore, the inner guide segment can have an inner contour, which at least sectionally has a contour and/or cross section that is to the greatest possible extent the same as that of the flange surface of the flange tube. In this context, the outer support segment has an outer contour, for example, which at least sectionally has a contour and/or cross section that is to the greatest possible extent the same as that of the inner bearing surface of the upper and lower bearing section. Both segments are moreover designed such that they in turn have a slide surface or a cross section, as the case may be, upon which they can mutually support themselves or upon which they can slide in relation to one another, as the case may be. That is to say, the inner guide segment has an outer contour that is to the greatest possible extent identical with the inner contour of the outer support segment. In order to ensure pivotability and/or sliding, these contours are preferably formed to be largely circular. The guide segment is connected to the flange tube in this instance, and the support segment to the bearing sections. 
         [0023]    It can further be provided that at least one shoulder is associated with the guide element and/or to the inner guide segment and/or to the outer support segment. The shoulder serves for preventing, where applicable, an axial shifting of the guide element, which consists of two segments. It can thereby also be ensured that the two segments of the guide element are always in a correct position in relation to each other. The shoulder can in addition suppress an axial shifting of the suspension device on the flange tube. 
         [0024]    The two segments or, as the case may be, the guide element and/or the flange tube or, as the case may be, the bearing sections, can moreover be made from different materials. The materials used can be metals and non-metal materials. Other materials, in particular such with good guiding characteristics, are also conceivable in this context. It is also conceivable that the materials have different degrees of hardness, thereby further increasing the guiding characteristics or the durability, as the case may be. The guide element and/or the bearing sections and/or the flange tube can be provided to be composed of a material combination, which requires no lubrication. Such material combinations could be preferentially used. Preferably, the material of the guide element has a greater degree of hardness than that of the elastic bearing elements, whereby the elastic characteristics of the bearing are optimized on the one hand, and the guidance is sufficiently stable on the other hand. 
         [0025]    As already mentioned above, the support distance is greatly increased by an arrangement of two guide elements at the edge sections of the suspension device, whereby the forces or, as the case may be, the surface pressure acting on the guide elements can be reduced. This is likewise achieved by a large cross section of the flange tube or of the guide element or of the bearing sections, as the case may be, whereby the wear can also be strongly minimized, thus in turn making it possible to reduce the demands on the material combinations. 
         [0026]    Furthermore conceivable is also a guide element that is formed to be ring-shaped, for instance, such that it only sectionally has a contour and/or cross section that is essentially the same as that of the flange surface of the flange tube and/or as that of the bearing surface of the bearing sections, for example, although, due to the small guide surfaces and/or slide surfaces such a design would be subject to considerable wear and durability could thus possibly not be ensured. 
         [0027]    The bearing elements in the present invention are formed to be elastic. Preferably, the bearing elements take the form of so-called rubber cord elements, which are inserted such that the pivot arm is pivotably movably connected radially to the flange tube by way of these bearing elements. As already mentioned above, the bearing elements can in each case define the preload force of the pivot arm or of the implement arrangement, as the case may be; that is, the closer they are pressed together, the greater is the preload force. When using guide elements, these can define the preload force; that is, the preload force of the bearing elements can be increased or reduced, as the case may be, according to the ratio of the cross sections of inner guide surface to outer guide surface. 
         [0028]    It should further be noted here that, beyond the previously described plain bearings, it is also possible to use rolling bearings or ball bearings or the like. In such an instance, these in turn have an inner contour, which at least sectionally has a contour and/or cross section that is essentially the same as that of the flange surface of the flange tube, and/or they have an outer contour, which at least sectionally has a contour and/or cross section that is essentially the same as that of the bearing surface of the bearing sections. Ball elements, for example, then serve as guide surface or slide surface, as the case may be. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0029]    In the following passages, the attached figures further illustrate exemplary embodiments of the invention and its advantages. The size ratios of the individual elements in the figures do not necessarily reflect the real size ratios. It is to be understood that in some instances various aspects of the invention may be shown exaggerated or enlarged in relation to other elements to facilitate an understanding of the invention. The figures show as follows 
           [0030]      FIG. 1A : a schematic perspective view of a suspension device with bearing section and pivot arm, and arranged thereat tillage and sowing implements in the form of a so-called single disk coulter; 
           [0031]      FIG. 1B : a schematic exploded view of a suspension device according to  FIG. 1A ; 
           [0032]      FIG. 2 : a schematic detailed view of the suspension device with a further embodiment variant of the guide elements and of the attaching means; 
           [0033]      FIG. 3 : a sectional, schematic detailed view of the suspension device according to the  FIGS. 1A, 1B, and 2 ; and 
           [0034]      FIGS. 4A to 4D : various further alternative embodiments and arrangements of the guide elements. 
       
    
    
     DETAILED DESCRIPTION 
       [0035]    The same or equivalent elements of the invention are each designated by identical reference characters in the  FIGS. 1A to 4D . Furthermore and for the sake of clarity, only the reference characters relevant for describing the respective figure are provided. It should be understood that the detailed description and specific examples of the device according to the invention, while indicating preferred embodiments, are intended for purposes of illustration only and are not intended to limit the scope of the invention. 
         [0036]      FIGS. 1A and 1B  show a schematic perspective view ( FIG. 1A ) and a schematic exploded view ( FIG. 1B ) of a suspension device  10  with a lower and an upper bearing section  12 ,  14 , and also with a pivot arm  16 , which is connected to the lower bearing section  12 . The suspension device  10  is attached to a flange tube  20 , which is aligned transversely to the driving direction  18 . This flange tube  20  can be, for example, part of an agricultural machine, which is not illustrated here, to which a multitude of such suspension devices  10  can be mounted laterally offset in relation to each other. 
         [0037]    Attached to the rear end of the pivot arm  16  by means of bearing elements not illustrated here are a cutting disk or, as the case may be, a coulter disk  22  and also a depth guidance wheel  24 . The cutting disk  22  and the depth guidance wheel  24  are in this context arranged at an angle in relation to the driving direction  18  and in relation to a perpendicular plane thereto. A seed tube  26  extends laterally along the cutting disk  22 . By means of this seed tube  26 , the respective seeds or the like to be distributed can be supplied to the furrow cut by the cutting disk  22 . Arranged downstream from the depth guidance wheel  24  by means of a swing arm  28  are further two pressure rollers  30  positioned at an angle to each other for the purpose of closing the groove or furrow, as the case may be, which was cut by the cutting disk  22 . The thus resulting implement arrangement  32  is generally referred to as single disk coulter. It should also be noted here, however, that the suspension device according to the invention can also be used with other agricultural implement arrangements, for example, with so-called double disk coulters, with disk harrows and/or spike tooth harrows, or the like. 
         [0038]    The flange tube  20  illustrated in the presented example has a square contour with rounded corners; cylindrical or triangular or other such contours are, however, also possible in this context. The upper and the lower bearing section  12 ,  14  both likewise have a square contour, and as with the flange tube  20 , other contours are again also conceivable. The bearing sections  12 ,  14  are, however, slightly larger in cross section than the flange tube  20 . The bearing sections  12 ,  14  or the pivot arm  16 , as the case may be, are arranged at an angle rotated approximately 45 degrees in relation to the flange tube  20 . Inserted into the thus resulting free spaces extending parallel to the flange tube  20  are four elastic bearing elements  34 , preferably in the form of so-called rubber cord elements. The pivot arm  16  is connected radially to the flange tube  20  to be pivotably movable in relation thereto by way of these bearing elements  34 . This pivotable movability is influenced by various factors, for example, by the number of bearing elements  34  present or by the material or the degree of hardness of the bearing elements  34 , as the case may be, with the bearing elements  34  being deformed or, as the case may be, pressed together to a certain degree in a pivoting motion, as is in each case indicated in the  FIGS. 1A to 4D . In addition, the bearing elements  34  or their elasticities and/or their dimensions, as the case may be, can each define the preload force of the pivot arm  16  or of the implement arrangement  32 , as the case may be, that is, the closer they are pressed together, the greater is the preload force. When using additional guide elements  40 , these can define the preload force; that is, the preload force of the bearing elements  34  can be increased or reduced, as the case may be, according to the ratio of the cross sections of inner guide surface  42  to outer guide surface  44 . 
         [0039]    Due to the inclined arrangement  32  of the implements at the pivot arm  16 , relatively large transverse or, as the case may be, lateral forces occur in practice, which act upon the suspension and contribute to the tendency of the suspension device  10  to shift or twist, as the case may be, in an axial direction on the flange tube  20 . This can particularly negatively affect implement arrangements  32  forming a seed drill coulter, as it is thus no longer possible to ensure a desired constant depth guidance and lateral guidance, if such is required. 
         [0040]    In order to counteract this negative effect, at least one additional guide element  40  is associated with the suspension device  10 , which guide element  40  is formed in multiple parts in the present exemplary embodiment of the  FIGS. 1A to 3 , and which is preferably arranged at the edge section  36  of the suspension device  10 . This additional guide element  40  is preferably designed such that it supports itself at least sectionally with its inner contour  42  upon the outer surface  46  of the flange tube  20  and/or such that it supports itself at least sectionally with its outer contour  44  upon the bearing surface  48  of the bearing sections  12 ,  14 . The inner contour  42  and/or the outer contour  44  thus each serve as guide surface or slide surface, as the case may be. The at least one guide element  40  is thus designed in such a manner that it largely suppresses the axial shifting or twisting, as the case may be, which occurs due to the transverse or lateral forces, as the case may be, and forms a plain bearing in the exemplary embodiment. 
         [0041]    As is discernible in particular from the  FIGS. 1B and 2 , the guide element  40  is formed from two segments, namely from an inner guide segment  50  and from an outer support segment  56 , with these in turn being formed in two parts in order to thus enable an easier mounting. The guide element  40  is in this instance designed such that the guide segment  50  supports itself with its inner contour  52  upon the flange surface of the flange tube  20 , and also such that the support segment supports itself with its outer contour  60  upon the bearing surface  48  of the upper and the lower bearing sections  12 ,  14 . The guide segment and the support segment  50 ,  56  are, again, designed such that they have a slide surface  54 ,  58 , respectively, so that they can mutually support themselves, and precisely in such a manner that the outer contour  54  of the guide segment  50  supports itself upon the inner contour  58  of the support segment. 
         [0042]    The guide elements  40  or the guide segment and the support segment  50 ,  56 , as the case may be, and the flange tube  20 , and also the bearing sections  12 ,  14 , are preferably made from different materials, such as, for example, from metals and from non-metal materials. In a preferred embodiment, the guide element  40  or the material combination, as the case may be, between the guide elements  40  and the flange tube  20  and/or the bearing sections  12 ,  14 , is formed from such a material combination that no additional lubrication is required. 
         [0043]      FIGS. 1A and 1B  further show additional attaching means  62  associated with each of the guide elements  40 . By means of these attaching means  62 , it is possible to suppress the axial shifting of the suspension device  10  on the flange tube  20 . For this purpose, the attaching means  62  can be, for example, immediately connected to the guide element  40  or be part of it, as the case may be (also see  FIG. 2 ). It is likewise conceivable, however, that the attaching means  62  is connected to the flange tube  20 , for example, by way of welding or by means of screws  64  (cf.  FIG. 3 ). 
         [0044]    In this context,  FIG. 2  illustrates a further alternative embodiment in which the axial securing of the suspension device  10  is carried out by means of a screw  64 , by means whereof the guide segment  50  is connected to the flange tube  20 , and where the support segment  56  is likewise connected to the bearing section by means of a further screw  64 . In order to avoid or prevent axial shifting, an outer shoulder  66  is associated with the guide segment  50  in the exemplary embodiment of  FIG. 2 , which shoulder  66  suppresses axial shifting and serves for the guide segment  50  and the support segment  56  to each be precisely positioned in relation to each other. 
         [0045]    In a sectional, schematic detailed view of the suspension device  10  according to the  FIGS. 1A, 1B, and 2 ,  FIG. 3  shows the mode of operation of the at least one additional guide element  40 . In the beginning, one guide element  40  is associated with each of the lateral edge sections  36  of the suspension device  10 . In this context, the guide element  40  is formed in two parts and consists of a guide segment  50  and a support segment  56 . The inner contour  52  of the guide segment  50  here at least sectionally has a contour and/or cross section that is essentially the same as that of the outer surface  46  of the flange tube  20 . Furthermore, the outer contour  60  of the support segment  56  has a contour and/or cross section that is essentially at least sectionally the same as that of the bearing surface  48  of the bearing sections  12 ,  14 , whereby a lateral twisting of the suspension device  10  can be effectively prevented or suppressed, as the case may be. The support segment  56  and the guide segment  50  each in turn have an inner contour  58  or an outer contour  54 , as the case may be, which serve as mutual slide surfaces for each other and which can also be formed such that the two parts can mutually support themselves; in addition this slide surface is in each case formed to be largely circular in order to enable pivoting or sliding, as the case may be. 
         [0046]    The arrangement shown according to  FIG. 3  allows achieving a large support distance between the guide elements  40 . By the large diameter of the guide elements  40 , it is in addition achieved that relatively small surface pressures act on each of the guide elements  40 , thus significantly reducing the wear and the maintenance effort. In addition hereto, it is also conceivable to select the material combinations for the guide elements  40  such that these also do not require any maintenance or, as the case may be, do not require any lubrication, or such that the wear is also minimized hereby, as the case may be. 
         [0047]      FIG. 3  further shows that additional attaching means  62  are associated with each of the guide elements  40 . By means of these attaching means  62 , the axial shifting of the suspension device  10  on the flange tube can be suppressed. For this purpose, the attaching means  62  can be, for example, immediately connected to the guide element  40  or be part of the guide element  40 , or form a unit with the guide element  40 , as the case may be (also see  FIG. 2 ). It is likewise conceivable, however, that the attaching means  62  is connected to the flange tube, for example, by way of welding or again by means of screws. 
         [0048]    Further exemplary embodiments of the suspension device  10  according to the invention follow from  FIG. 4  ( FIGS. 4A to 4D ). First,  FIG. 4A  shows a further embodiment of a suspension device  10 , in which the guide element  40  is formed as a single part and ring-shaped. The inner contour  42  of the guide element  40  again corresponds to the contour and/or cross section that is essentially at least sectionally the same as that of the flange surface  46  of the flange tube  20 . The outer contour  44  of the guide element  40  essentially corresponds to the contour and/or cross section that is at least sectionally the same as that of the bearing surface  48  of the bearing sections  12 ,  14 . In order to enable a movement of the bearing sections  12 ,  14  in relation to the pivot arm carrier, the outer contour  44  is formed as a slide surface and circular. 
         [0049]    For the sake of completeness  FIGS. 4B to 4D  show further arrangement possibilities of the at least one guide element  40  in the suspension device  10  according to the invention and also further variants of the attaching elements  62  that also fall under the scope of protection of this invention.  FIG. 4C  further shows another design variant of the guide element  40 , where this has an inner contour  42  as guide surface or slide surface, as the case may be, which has an essentially round cross section or, as the case may be, at least sectionally a contour and/or cross section that is essentially the same as that of the outer surface  46  of the flange tube; and where this further has an outer contour  44 , which at least sectionally has a contour and/or cross section that is essentially the same as that of the bearing surface  48  of the bearing sections  12 ,  14 . 
         [0050]    The invention has been described with reference to a preferred embodiment. Those skilled in the art will appreciate that numerous changes and modifications can be made to the preferred embodiments of the invention and that such changes and modifications can be made without departing from the spirit of the invention. It is, therefore, intended that the appended claims cover all such equivalent variations as fall within the true spirit and scope of the invention. 
       LIST OF REFERENCE CHARACTERS 
       [0000]    
       
         
           
               10  Suspension device 
               12  Lower bearing section 
               14  Upper bearing section 
               16  Pivot arm 
               18  Driving direction 
               20  Flange tube 
               22  Cutting disk; coulter disk 
               24  Depth guidance wheel 
               26  Seed tube 
               28  Swing arm 
               30  Pressure roller 
               32  Implement arrangement 
               34  Bearing element 
               36  Edge section 
               40  Guide element 
               42  Inner contour/guide surface/slide surface 
               44  Outer contour/guide surface/slide surface 
               46  Flange surface 
               48  Bearing surface 
               50  Guide segment 
               52  Inner contour 
               54  Outer contour/slide surface 
               56  Support segment 
               58  Inner contour/slide surface 
               60  Outer contour 
               62  Attaching means 
               64  Screw 
               66  Shoulder