EP1744407B1 - Vibration protection for coupling parts with screw engagement - Google Patents

Abstract

The plug or socket has a contact holder (1) with contact chambers for receiving contact partners. The holder has axial stop surfaces (1.5, 1.6) for receiving threaded parts and a bearing surface serving as a pivot bearing. The holder has a bending plate (1.1) in an area of the bearing surface, where the bending plate is radially movable. The plate is provided with edge surfaces that point in moveable direction and are normally adjusted.

Description

The invention relates to a plug or a socket of a plug connection with screw locking, in particular a plug connection for automation technology according to the standard IEC 61076-2-xxx ("Connectors for electronic equipment"), according to the features of the preamble of claim 1.

Such plugs or cans are mostly used in the industrial environment under the influence of moisture, spray liquids, aggressive media, vibrations and the like, and fastened with the aid of a cap screw or a union nut with each other, or possibly with corresponding counterparts to sensors, electronic modules and the like. In view of such harsh operating conditions, it is indispensable to properly seal the connector space within which the current paths pass against water and other liquid or powder media. This can be done on the one hand with the help of seals that are pressed radially or transversely to the plug or to the longitudinal axis of the screw, which, however, over the cross section of the connector of course requires more space. Since it depends very much on a compact design with screw-locked connectors according to IEC 61076-2-xxx, seals are usually pressed axially against corresponding surfaces on the corresponding counterpart here. An essential function of the screw lock, which is accomplished by means of cap screws or union nuts, is therefore to generate the required compressive force at the end of the screwing process, which is required for pressing the respective seal. It is noteworthy here that the distance traveled by such miniature or miniature connectors which is required for pressing the seal, is usually relatively small in relation to the respective thread pitch, ie this compression is generated over the last small fraction of a revolution of the respective cap screw or union nut. In view of the vibrations and other mechanical stresses that such connectors are subject to in operation, there is a risk that - especially in case of incoming resonance cases - inadvertent loosening or at worst loosening the screw can use what the tightness of the connector override, and thus would cause a functional failure. It is therefore necessary to counteract such problems by appropriate design measures.

Basically, it is useful both in view of emerging dimensional and tolerance chains as well as the acting force flows to provide such a vibration protection at the point at which the respective cap screw or union nut is rotatably mounted. In the case of the above-described connectors, this pivot bearing is usually on the from electrical insulation material - usually plastic - existing contact carrier.

In order to prevent unintentional loosening of the screw lock, it must be ensured in principle that the torque over one revolution of the cap screw or union nut is not constant but wavelike. The amplitude and period of this characteristic must be based on the one hand on the nature and intensity of the respective disturbing influences. On the other hand, taking into account the existing tolerances, the period must at most be designed to be so large that the area over which the screw lock could nevertheless still loosen, can not adversely affect the sealing function.

Another very important aspect in this context is the feel. In view of the fact that such connectors are manually operated, it is important that this characteristic especially in terms of their uniformity and reproducibility, as well as in terms of their qualitative The course should be interpreted in such a way that the user is subject to a subjective sense of quality.

Such vibration-protected connectors are known in numerous embodiments.

Basically, one can distinguish between solutions that work with or without additional parts on the one hand with regard to the pairing in each case of contact carrier screw cap or contact carrier cap nut. Furthermore, it can be distinguished whether the desired wave-like torque curve is generated by forces which in one case preferably act radially or transversely, and in the other case preferably along the plug-in or screw axis.

A vibration protection with additional parts and axially acting forces is for example US 6,135,800 . G 92 12 936 . DE 28 40 728 B1 . DE 3500172 A1 . WO 87/00352 . US 3,917,373 . FR 1 188 157 or GB 825,579 known. A vibration protection with additional parts and radially acting forces is off DE 43 01 503 A1 . US 4,239,314 or US 4,682,520 known. A vibration protection without additional parts and axially acting forces is in US 6,135,800 . DE 35 00 172 A1 . US 4,462,653 or DE 32 09 734 C2 disclosed. Finally, a vibration protection without additional parts and radially acting forces DE 44 04 484 C2 . G 93 01 171 . DE 35 00 172 A1 . DE 36 25 134 C1 such as US 4,682,520 known.

The disadvantages of solutions with additional parts are the following: An additional part causes the dimensional, shape and position tolerance chains relevant to the function to be correspondingly larger; This leads to a reduction in the quality of the components, while the quality of the components remains the same, or, if the quality of the components remains the same, to correspondingly higher quality (and thus cost) requirements for the individual parts involved. In addition, an additional part claimed correspondingly more space, which runs counter to the general desire for a compact design. The assembly effort is both quantitatively - number of steps involved - as well as quality - usually it is very small, filigree parts - increased. With such filigree parts growing In addition, the risk that they are lost when mounting or simply forgotten, resulting in that the desired vibration protection is missing, An additional part generally generates higher storage, administration, handling costs and the like. Of course, it is deduced from these disadvantages that a solution with an additional part performs both functionally and economically inevitably worse than vibration protection without an additional part.

The disadvantages of solutions with axially acting forces are still the following: Axially acting forces are generated by form-fitting interactions on force-transmitting bearing surfaces between the contact carrier and the respective threaded part by these surfaces are each performed with corresponding projections and corresponding gaps. Of course, the overlapping of these elements may only be so great that a trouble-free operation of the screw locking is still possible. As a result of the usually very small space conditions, these projections and / or gaps can not be designed as resilient elements with exactly defined characteristics, but rather only as material knobs, as quasi-Axialverzahnungen and the like. Federtechnisch elements with very high and poorly reproducible stiffness can be realized in this way, which leads in connection with the additionally present dimensional and tolerance chains to even less reproducible forces and thus moments. Due to the fact that the axial play between the parts involved in the vibration protection is usually greater than the overlap of these interacting elements arise, depending on their relative position, either constant torque curves, torque curves with gradually rapidly increasing ripple and finally gradients maximum ripple. The main disadvantages of such designs are therefore: Poor feel and low reproducibility of torque curves, the range between no or barely noticeable vibration protection and barely to be operated screw locks enough. Due to the high stiffness these are already very small elements subject to high and usually fairly uneven wear.

The disadvantages listed under the group of solutions with axially acting forces apply mutatis mutandis to embodiments with radial forces, if between the interaction elements in no relatively accurate and well reproducible spring characteristic exists such. B. in the writings DE 44 04 484 C2 . DE 35 00 172 A1 or US 4,682,520 ,

An additional disadvantage in terms of fonts DE 44 04 484 C2 and US 4,682,520 is that if the torque curve in the end position of the screw locking in turn ends at a rising edge before its maximum, then adjusts a releasing torque during operation, which of course counteracts the actual function of the screw lock.

The important requirement of a well-definable and easily reproducible spring characteristic, without the need for additional parts, ultimately meet only the fonts DE 36 25 134 C1 and G 93 01 171 , However, these two solutions also have some disadvantages described below.

The disadvantages of the solution G 93 01 171 are: The here provided on the contact carrier spring element 24 with the locking knobs 19 is a two-sided firmly connected or "clamped" Biegelamelle. Such a design has the consequence that, especially to the largely rigid or transverse to Deflection direction not yielding "clamping points" of the lamella very high mechanical stresses in the material arise, which has an increased negative impact in the case of a dynamically loaded plastic spring. Such a realization is also very disadvantageous with regard to the flow behavior of the plastic compound on such a double-sided connected slat. Since the cutout 23 must be produced by a tool core, which acts as an obstacle with respect to the molding compound, and the blade further forms a very narrow flow channel on the tool side, tie lines will very likely arise over the longitudinal extent of the blade, as a result of converging flow fronts. On the material side, such seams represent a considerable loss of strength and a very high risk of breakage, and should be avoided precisely along such dynamically loaded elements by a more equitable design. The shape of the toothing on the threaded portion 15 has an approximately trapezoidal shape with flattened tips. By flattening these tooth tips, however, there is a risk that the blade in the end position of the Schaubverriegelung remains in a stable manner in its biased position. Given the pronounced creep and relaxation behavior of plastics, this would of course result after a certain time in either a greatly reduced spring action of the lamella, or even a fracture thereof.

The solution of DE 36 25 134 C1 Finally, there are the following disadvantages: A problem is that the here almost unilaterally connected or "clamped" and thus injection-molded with respect to the formation of weld lines Biegelamelle 10 has such an orientation that by the interaction between lamella and a like in the FIGS. 4 and 5 teeth shown acting forces in a plane which is perpendicular to the plane defined by the neutral fiber of the blade and the deflection direction. As a result, the bending blade does not only have a desired compliance defined in the radial deflection direction, but also an undesirable bending and torsional compliance in a tangential direction which is of comparable magnitude. This can easily lead to unwanted Tangentialauslenkungen or oscillations, especially when occurring resonance cases, which on the one hand an increased wear, but also have noticeable negative effects on the feel and on the function at all result. Due to the relatively wide-surface design of the blade tips 11, where the interaction with the teeth 43 takes place, there is also the danger that the blade, in the end position of the Schaubverriegelung, remains in a stable manner in its biased position, which also either to a then greatly reduced spring action, or even lead to a fracture of the lamella. Another problem, especially in the case of miniature connectors, such as those according to IEC 61076-2-xxx, is the rather large space required by such a design, especially in the longitudinal direction.

From the generic US 4,641,811 a connector of a connector is known, comprising a contact carrier with contact chambers for receiving a contact partner, wherein the contact carrier for receiving a threaded portion having axial abutment surfaces and serving as a pivot bearing tread.

The invention is therefore based on the object to realize a vibration protection for a plug or a box (also called coupler) without additional parts and with radially acting forces, which avoids the disadvantages listed above.

This object is solved by the features of claim 1.

Embodiments of the invention, to which this is not limited, are described below and explained with reference to the figures.

FIGURE 1, FIGURE 2:

These figures show a consisting of a contact carrier 1, preferably a pin contact carrier 1 and a threaded part 2, preferably a cap screw 2 assembly, which is part of a connector, not shown here.

FIGURE 3, FIGURE 4:

These figures show a consisting of a contact carrier 3, preferably a female contact carrier 3 and a threaded part 4, preferably a union nut 4 assembly, which is also part of a connector, not shown here.

To the FIGS. 1 to 4 in detail:

The one-piece made of insulating material, preferably made of plastic, running contact carrier 1/3 has to receive the threaded part 2/4, the axial stop surfaces 1.5 / 3.5 and 1.6 / 3.6 and serving as a pivot bearing tread 1.7 / 3.7. In addition, the contact carrier 1/3 in the area of this tread 1.7 / 3.7 at least one, at their in the FIG. 2 and 4 marked connection "x - x" quasi firmly clamped, and at its free end in approximately radially deflectable bending blade 1.1 / 3.1, with the approximately in Federauslenkrichtung facing edge surfaces 1.1.1 / 3.1.1 and 1.1.2 / 3.1.2 and with about this normally facing edge surfaces 1.1.3 / 3.1.3 and 1.1.4 / 3.1.4. The Biegelamelle 1.1 / 3.1 may be oriented in their orientation, depending on the application, both against and in Urzeigesinn, which in the case of multiple bending blades these can be carried out relative to each other both the same and counter-directed. Furthermore, the contact carrier 1/3 is provided with transverse stops 1.3 / 3.3 and 1.4 / 3.4, with the corresponding to the surfaces 1.1.1 1 3.1.1 and 1.1.2 / 3.1.2 stop surfaces 1.3.1 / 3.3.1 and 1.4 .1 / 3.4.1, which prevent transverse deflection of the bending blade 1.1 / 3.1, which is not permissible in the axial direction, for example during assembly or during operation.

Similar to the solution DE 36 25 134 C1 is the Biegelamelle, as already mentioned, also here only on one side of the contact carrier 1/3 at the in the FIG. 2 and 4 marked connection "x - x" firmly "clamped", which has the injection advantage that along the lamella the emergence of weld lines is avoided. In addition, the relatively narrow cross-section having Werkzeugkavität corresponding to the Biegelamelle, relatively uniformly filled in the injection process of the connection "x - x" with molding compound, so that over the longitudinal extent of a very good alignment of the plastic molecules takes place, which in turn a noticeable Improvement of the spring properties entails.

Another important design feature of the Biegelamelle is - in contrast to the solution DE 36 25 134 C1 - In their tangential orientation such that the lines of action of the forces resulting from the interaction between lamella 1.1 / 3.1 and 2.1 / 2.1 teeth are located within the plane defined by the neutral fiber of the blade and the deflection direction. Since, in principle, no axially acting forces occur as a result, and the relatively large flexibility of the blade in the axial direction is not relevant. Otherwise resulting force components which do not point in the (desired) deflection direction within the plane cause almost exclusively tensile or compressive stresses within the bending blade, which causes practically no (undesired) deformations over these directions.

The Biegellamelle 1.1 / 3.1 has at its free, resilient end with a corresponding toothing of the threaded part 2.1 / 4.1 interacting projection 1.2 / 3.2, in the Figures 2 and 4 shown cross sections "BB" has a convex curved, preferably circular section 1.2.1 / 3.2.1, and at this both sides adjacent oblique sections 1.2.2 / 3.2.2 or 1.2.3 / 3.2.3. Generally, the cross-sectional shape of the projection 1.2 / 3.2 may consist of at least one convexly curved, preferably circular section, or of at least two straight sections, or of a combination between at least one convexly curved, preferably circular section and at least one straight section. Along the edges forming between projection 1.2 / 3.2 and edge surfaces 1.1.1 / 3.1.1 and I or 1.1.2 / 3.1.2, the bending blade can mainly for assembly reasons further bevels 1.2.4 / 3.2.4 and / or 1.2. 5 / 3.2.5.

The threaded part 2/4 in turn has a Biegelamellen- projection 1.2 / 3.2 corresponding teeth 2.1 / 4.1, at least one, preferably opposite to the mounting direction pointing insertion or mounting bevels 2.2 / 4.2, and the contact carrier 1/3 respectively corresponding stops 2.3 / 4.3 and 2.4 / 4.4, or the tread 2.5 / 4.5.

The teeth 2.1 / 4.1 shown in the cross sections "BB" from the Figures 2 and 4 consists of circular projections on a circular lateral surface at regular pitches "p 1" / "p 3" arranged 2.1.1 / 4.1.1. Generally, the toothing 2.1 4.1 of at least one projection, but preferably of several, over the circumference of the tread 2.5 / 4.5 preferably arranged in regular, or in irregular, or alternately regular and irregular part distances "p 1" l "p 3" Projections 2.1.1 / 4.1.1 exist. Regarding these partial distances "p 1" / "p 3" is to be noted in any case that their respective maximum amount with sufficient certainty must be smaller than the then possible rotation of the threaded portion could lead to an inadmissible reduction of the seal compression. In addition, here also the cross-sectional shape of this or preferably these projections 2.1.1 / 4.1.1 from at least one convexly curved, preferably circular section, or from at least two straight sections, or from a Combination between at least one convex curved, preferably circular section and at least one straight section.

With regard to the between Biegelamellen- projection 1.2 / 3.2 and the toothed projections 2.1.1 / 4.1.1 held and ultimately generating the vibration protection interaction, some other important features are to be considered in view of the structural design of this pairing. The cross-sectional shapes of these projections 1.2 / 3.2 and 2.1.1 / 4.1.1 are on the one hand so matched to each other that they always have a point, or with respect to wear preferably a line contact regardless of their relative position. In this way, overestimates on the contact geometry can be avoided, or it can be ensured that the contact tangent between the projections 1.2 / 3.2 and 2.1.1 / 4.1.1, which influenced by their inclination, the operating force and thus the torque curve directly over the entire range of rotation has a definable and reproducible angle.

Furthermore, it is to be ensured constructively that the projections 1.2 / 3.2 and 2.1.1 / 4.1.1 touch at the points where the bending blade has its maximum deflection or force in such a way that a labile equilibrium of forces is established between them. Concretely, this means that the projections at this point on the one hand touch only point or preferably line-shaped, and on the other hand, that the projections each have a diverging tendency on both sides of this contact point with respect to the contact tangent. Unlike the solutions G 93 01 171 and DE 36 25 134 C1 This ensures that the blade remains in the final position of the screw in its maximum preloaded position, this then generates in operation, especially under the influence of vibration a releasing moment on the threaded part, which in turn to a substantial or complete reduction of their Deflection, and thus leads to the preservation of their spring properties.

The spring properties or the bending forces generated by the bending blade 1.1 / 3.1 in the direction of deflection spring forces can essentially by in the Figures 2 and 4 spring height "h 1" / "h 3", spring width "b 1" / "b 3", spring length "l 1" / "l 3", as well as the amount of deflection "f 1" / "f 3 be defined defined. The edge surfaces 1.1.1 / 3.1.1 and 1.1.2 / 3.1.2 or 1.1.3 / 3.1.3 and 1.1.4 / 3.1.4 can at least partially flat, or at least partially convex curved, or at least partially designed concavely curved are, over the individual surfaces and combinations of such sections are conceivable. The corresponding pairs of surfaces 1.1.1 / 3.1.1 and 1.1.2 / 3.1.2 or 1.1.3 / 3.1.3 and 1.1.4 / 3.1.4 can also, starting from the connection "x - x" towards projection 1.2 / 3.2, each at least partially obliquely apart, at least partially parallel or at least partially obliquely to each other, of course, combinations of such courses or sections are conceivable. The parameters "h 1" / "h 3" and / or "b 1" / "b 3" can therefore at least partially increase in their magnitude along the length "l 1" / "l 3", and / or at least partially constant remain, and / or preferably at least partially decrease. In the preferred case of at least partially decreasing parameters "h 1" / "h 3" and / or "b 1" / "b 3", it is possible, inter alia taking into account the material properties resulting after the injection molding process, to be as optimal as possible or uniform course of the mechanical stresses over the length "l 1" / "l 3" to achieve, which is very advantageous in terms of the life of the blade 1.1 / 3.1, especially in view of the present dynamic loads.

The at the threaded part 2/4 finally resulting wave-shaped DrehmomentVerlauf which ultimately produces the desired vibration protection, determined on the one hand from the amount of this by the deflection of the bending blade 1.1 / 3.1 and defined above og parameters spring force. Furthermore, this moment is dependent on the respective present, in the Figures 2 and 4 exemplarily indicated angle "α 1" / "α 3" or "β 1" / "β 3", which - depending on the rotational position - between the Lamellenauslenkrichtung and the between the projections 1.2 / 3.2 and 2.1.1 / 4.1.1 adjusting Touch tangent is clamped, and of course of the respective material pairing corresponding friction coefficient.

Claims (7)

1. Plug or socket of a plug-in connection, having a contact carrier (1, 3) with contact chambers for receiving a contact partner, the contact carrier (1, 3) having axial stop surfaces (1.5, 3.5 and 1.6, 3.6) for receiving a threaded part (2, 4) and a bearing surface (1.7, 3.7) serving as a rotary bearing, wherein the contact carrier (1, 3) has in the region of the bearing surface (1.7, 3.7) at least one bending plate (1.1, 3.1), which is fixedly restrained and at its free end can be deflected approximately radially, and the bending plate (1.1, 3.1) is provided with edge surfaces (1.1.1, 3.1.1 and 1.1.2, 3.1.2), pointing approximately in the direction of resilient deflection, and edge surfaces (1.1.3, 3.1.3 and 1.1.4, 3.1.4), directed approximately normal thereto, characterized in that the contact carrier (1, 3) is provided with transverse stops (1.3, 3.3 and 1.4, 3.4) with stop surfaces (1.3.1, 3.3.1 and 1.4.1, 3.4.1) respectively corresponding to the surfaces (1.1.1, 3.1.1 and 1.1.2, 3.1.2).
2. Plug or socket of a plug-in connection according to Claim 1, characterized in that the bending plate (1.1, 3.1) is arranged in tangential alignment on the contact carrier (1, 3) in such a way that the lines of application of the forces produced as a result of the interaction between the bending plate (1.1, 3.1) and a serration (2.1, 4.1) are within the plane defined by the neutral axis of the bending plate (1.1, 3.1) and its direction of deflection.
3. Plug or socket of a plug-in connection according to Claim 1 or 2, characterized in that the bending plate (1.1, 3.1) has a projection (1.2, 3.2), interacting at its free, resilient end with the serration of the threaded part (2.1, 4.1).
4. Plug or socket of a plug-in connection according to one of the preceding claims, characterized in that the projection (1.2, 3.2) has a convexly curved, preferably circular, portion (1.2.1, 3.2.1) and sloping portions (1.2.2, 3.2.2 and 1.2.3, 3.2.3) respectively adjoining said circular portion on both sides.
5. Plug or socket of a plug-in connection according to one of the preceding claims, characterized in that the threaded part (2, 4) has a serration (2.1, 4.1) corresponding to the projection (1.2, 3.2) of the bending plate and at least one inserting or fitting slope (2.2, 4.2), preferably facing counter to the fitting direction, and has the stops (2.3, 4.3 and 2.4, 4.4), respectively corresponding to the contact carrier (1, 3), and the bearing surface (2.5, 4).
6. Plug or socket of a plug-in connection according to one of the preceding claims, characterized in that the serration (2.1, 4.1) comprises circular projections (2.1.1, 4.1.1) arranged at regular pitches ("p 1", "p 3") on a circular peripheral surface.
7. Plug or socket of a plug-in connection according to one of the preceding claims, characterized in that the serration (2.1, 4.1) comprises at least one projection, but preferably a number of projections (2.1.1, 4.1.1) arranged at regular or irregular or alternately regular and irregular pitches ("p 1", "p 3") over the circumference of the bearing surface (2.5, 4.5).

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