DE102010027444B3 - Cable tension relieving and sealing system for holding cables at cable outlet of e.g. connector housing, has strain relief element operatively connected with seal element, where strain relief element is rotatably fixed at end - Google Patents

Abstract

The system has a helical strain relief element (40) operatively connected with a seal element. The strain relief element comprises a contour (41) inserting a cable outlet connecting piece into a recess at an end (40a) of the strain relief element, so that the strain relief element is rotatably fixed at the end in a torque proof manner. The strain relief element comprises engagement hooks (43) radially pointing in an outward direction at other end (40b) of the strain relief element, where the hooks are intervened in a snap-in configuration of the cable outlet connecting piece.

Description

The invention relates to a Kabelzugentlastungs- and sealing system for cable outlets of connector housings or cabinets, consisting of a strain relief and a sealing element.

Such Kabelzugentlastungs- and sealing systems are required to hold cables to cable outlets of connector housings, cabinets or similar twisting and zugsicher.

State of the art

The EP 0 627 588 B1 shows a cable gland for securing a cable to a cable outlet nozzle. The nozzle is provided with individual, flexible clamping tongues which, when a union nut is screwed on, are guided against a gasket pushed over the cable jacket, thereby clamping the gasket and, at the same time, the cable.

When compressing the clamping tongues, it may happen that the pressing pressure exerted on the cable via the gasket does not reach the required height for securing and securing the cable.

The DE 3 128 541 C1 shows a cable gland with a fuse against accidental loosening. However, the cable gland requires special tools here.

task

The object of the invention is to propose a cable fixation, which eliminates the shortcomings described above and is easy to install.

The object is achieved in that the strain relief element has a helical structure and is operatively connected to the sealing element.

Advantageous embodiments of the invention are specified in the subclaims.

A Kabelzugentlastungs- and sealing system is usually integrated in a cable fixing element, such as a cable gland. The cable fixation consists essentially of the components clamping sleeve, spring element and locking ring, which fix a cable on a cable outlet connection of a connector housing in operative connection with the Kabelzugentlastungs- and sealing system. The cable can be multi-core, for example.

The cable strain relief and sealing system consists of a strain relief and a sealing element. The strain relief is shaped substantially like a coil spring and thus has a helical structure. The word "helical" can also be equated with the word "helical" in common usage. On one side, the strain relief is connected to the sealing element. The strain relief element forms with the sealing element a functional unit, which is also referred to as an operative connection.

The sealing element is disc-shaped and provided centrally with an opening whose diameter is smaller than the diameter of the cable to be connected.

Optionally, the sealing element can also be provided with a so-called push-through membrane instead of the opening.

The side of the sealing element, which is directed to the cable outlet direction (the outside), is provided at the edge with concentrically revolving slats, so-called press blades. The opposite side (the inside) of the sealing member also has lamellae, called sealing lamellae, which enclose the opening for the cable to be connected. The sealing blades run concentrically around the opening of the sealing element, which is provided for the cable. The cable is pushed during assembly through the strain relief and through the openings of the sealing element and the clamping sleeve.

Often the sealing element is made of material having elastomeric properties (such as EPDM, NBR, PU, etc.). In this case, the lamellae are already molded in the manufacturing process. The inside sealing lamellae ensure an improved sealing function between the sealing element and the cable sheath. The outside press blades of the sealing element increase the sealing effect between the clamping sleeve and the cable outlet connection.

The locking ring simultaneously encloses the clamping sleeve and the cable outlet connection. Both on the clamping sleeve and on the locking ring, a contour is formed on the inside, between which an open, annular spring element is inserted.

The locking ring is rotatably mounted around the cable outlet nozzle and the clamping sleeve. Upon rotation of the locking ring, so with a relative movement of the locking ring to the clamping sleeve, the relative distance of the above contours to each other changed. Because the spring element is clamped between these contours, thereby changing the diameter of the spring element.

The rotational direction of the locking ring, in which the diameter of the spring element is larger, is called the opening direction. In the end position (also called stop position) of this direction of rotation, the spring element has reached its maximum diameter. In an opposite direction of rotation, the so-called locking direction, the diameter of the spring element is again smaller, until the diameter is minimal in a second end position.

If no force is exerted on the spring element via the abovementioned contours, the spring element is in its so-called zero position.

As already mentioned above, the cable is inserted before the installation of the cable fixing device in the opening of the funnel-shaped clamping sleeve. At the same time it is enclosed by the helical strain relief and the attached thereto sealing element. The clamping sleeve is surrounded in the lower part of the locking ring. Subsequently, the clamping sleeve is placed on the cable outlet nozzle, so that the locking ring equally encloses the upper portion of the cable outlet nozzle.

As already described in detail above, the spring element between the Abstützkontur the clamping sleeve and the driver contour of the locking ring is clamped.

The spring element is conically shaped on the inside. The cable outlet nozzle includes a circumferential groove into which the conically shaped spring element is inserted, while the locking ring is rotated in the locking direction. If the end position of the locking direction is reached, the conically shaped inner side of the spring element engages precisely in the circumferential groove of the cable outlet connecting piece. As a result, the clamping sleeve enclosing the cable is held or fixed on the cable outlet connection.

In a particularly advantageous embodiment, the spring element engages already in its zero position in the circumferential groove of the cable outlet nozzle. To fix the clamping sleeve on the cable outlet connection, it can simply be pushed onto the cable outlet connection. The spring element initially gives way slightly radially back and then snaps into the circumferential groove.

One surface of the Abstützkontur the clamping sleeve and a surface of the Mitnehmerkontur the locking ring is each obliquely (at an acute angle) to a surface that clamps a radial vector with an axial vector of the clamping sleeve aligned. These are the surfaces that are directed to the respective ends of the clamped spring element. The ends of the spring element are suitably oriented obliquely opposite. As a result, slide the ends of the spring element, when turning the locking ring in the opening direction, radially outward away. When turning in the opposite direction in the locking direction, however, the ends of the spring element are guided radially inward. This ensures that the diameter of the spring element changes uniformly. The ring shape is always preserved.

In plan view of the clamping sleeve, the Abstützkontur forms a substantially rectangular triangle, the hypotenuse forms the above-mentioned slope for radial guidance of the spring element upon rotation of the clamping ring. The same applies to the geometry of the driver contour of the locking ring.

The clamping sleeve comprises elongate webs, which are directed radially outwardly within a plane. These webs are introduced when merging clamping sleeve and locking ring in axial recesses of the locking ring. These recesses are enclosed by internal webs of the locking ring. The webs of the clamping sleeve and the locking ring are inclined opposite, viewed in the plane of the plugging direction. During the relative movement of the locking ring to the clamping sleeve, ie during the rotational movement of the locking ring, both webs are pressed against each other, so that the parts (clamping sleeve and locking ring) are clamped together. This deadlock is also referred to as a bayonet lock.

When jammed webs and the end position of the locking direction is reached and the spring element engages in the circumferential groove of the cable outlet nozzle.

The clamping sleeve encloses part of the lateral surface of the cable outlet nozzle. Inside the clamping sleeve, a peripheral edge is formed. Between this edge and the boundary of the cable outlet nozzle, the sealing element is arranged.

Due to the jamming of the locking ring with the clamping sleeve and the simultaneous fixing of the clamping sleeve on the cable outlet nozzle, the sealing element between the above-mentioned peripheral edge of the clamping sleeve and the boundary of the cable outlet nozzle is clamped.

The conical inner shape of the spring element supports the clamping force by the clamping sleeve is pulled slightly down on the cable outlet nozzle.

The inner circumferential edge of the clamping sleeve exerts a force on the press blades of the sealing element. The contact surface between the inner, circumferential edge of the clamping sleeve and the sealing element decreases due to the peripheral pressing blades. Thus, with the same pressing force, a higher pressure is exerted on the seal.

In completely separate, so entklemmten webs, the end position of the opening direction is reached and the spring element has a maximum diameter. Now the clamping sleeve is removable from the cable outlet connection.

Outgoing from the cable outlet, the cable is enclosed by the strain relief element. The strain relief comprises at a first end contours, which are insertable in recesses of the cable outlet nozzle. As a result, the strain relief element is rotationally fixed at this end about its axial axis.

At a second end, the strain relief element comprises radially outwardly facing latching hooks. These latching hooks engage in associated latching contours of the cable outlet connecting piece, so that the second end of the strain relief element can be fixed in a rotationally fixed manner in one direction. When rotated in the other direction, the flexible latching hooks slide on the latching contours.

Furthermore, the strain relief on the second end axially outwardly facing driver hook. The clamping sleeve includes on the inside matching Mitnehmerkonturen. In a relative movement of the clamping sleeve to the strain relief in a first direction, the so-called clamping direction, the second end of the strain relief is relative to the first end, which is fixed in the cable outlet nozzle, moved or rotated.

The Mitnehmerkonturen are strung together in a circle inside the clamping sleeve, along the cable opening. In the radial direction, the adjacent driver contours are offset from each other. You could also say that the Mitnehmerkonturen run along their direction of extension radially outward, viewed in the counterclockwise direction.

As a result, the helix structure of the strain relief can be lashed around the cable sheath. This will be described later in more detail.

The Mitnehmerkonturen the clamping sleeve are therefore shaped such that in a relative movement of the clamping sleeve for strain relief in a second direction, ie opposite to the clamping direction, the driving hooks of the strain relief along the Mitnehmerkonturen the clamping sleeve slide along without a sufficient force is exerted on the driving hooks, which would cause relative rotation of the ends of the strain relief. The driver hooks are made of an elastically deformable material and optionally smooth slightly in the radial direction.

As already described above, the strain relief element is helically or helically formed between its two ends. This helical structure encloses the cable sheath of the cable to be connected. By the above-described relative movement of the two ends of the strain relief to each other, the slope of the helical structure is changed. The radius of the helix increases or decreases accordingly.

As the radius becomes smaller, the cable is constricted and fixed by the spiral or helix shape of the strain relief element. This ensures a strain relief for the cable.

By a reciprocating movement of the clamping sleeve relative to the cable outlet nozzle, the helical or helical part of the strain relief is clamped around the cable sheath.

In a direction of rotation (the clamping direction) of the clamping sleeve, the latching hooks of the strain relief element are continued and the helical structure narrows around the cable sheath. In the other direction of rotation, the driver hooks slide on the driver contours of the clamping sleeve. The device acts like a so-called ratchet.

In an advantageous embodiment, the strain relief element has a first and a second helical structure. The structures are in opposite directions, d. H. one is on the right and the other on the left. In such a double helix the constricted cable sheath is always centered, d. H. aligned along the axial axis of the strain relief.

embodiment

An embodiment of the invention is illustrated in the drawings and will be explained in more detail below. Show it:

1 a perspective drawing of the device for fixing the cable to a cable outlet nozzle without cable strain relief,

1a a perspective view of the locking ring,

1b a perspective view of the clamping sleeve,

1c a perspective view of the spring element,

2 a perspective view of the cable outlet nozzle,

3 a sectional view of the device for fixing the cable on the cable outlet nozzle,

4 an exploded view of the device for fixing the cable to a cable outlet nozzle,

5 a perspective view of the strain relief in Doppelhelixausführung,

6a a perspective view of the strain relief element with connected sealing element,

6b a plan view of the sealing element,

7 a sectional view of the device for fixing the cable to a cable outlet nozzle with cable strain relief and

8th an exploded view of the device for fixing the cable to a cable outlet with cable strain relief.

The 1a . 1b and 1c show the individual components of the device 1 for fixing a clamping sleeve 2 on a cable outlet 30 , The cable is not shown in this illustration for clarity.

The fixation of the cable enclosing clamping sleeve 2 on the cable outlet, is first, regardless of the fixation of the cable in the clamping sleeve 2 himself, described. In a second part of the description is then discussed the strain relief of the cable and the sealing of the Kabalfixierungsvorrichtung against media such as dust and water.

The clamping sleeve 2 ( 1b ) has a substantially funnel-shaped shape. The clamping sleeve 2 includes a downwardly tapered cable exit opening 5 , Locking side are radially outwardly pointing elongated webs 4 formed. Near one of these jetties 4 extends in the axial direction a Abstützkontur 3 , This has essentially the shape of a triangle extruded into space, a so-called triangular column with a side surface 3a ,

The locking ring 20 ( 1a ) is designed substantially cylindrical. At one end, the opening is through a radially encircling bottom ring 24 narrows. At the bottom ring 24 is a driver contour 21 formed. Geometrically, the shape of the driver contour corresponds 21 essentially the shape of the Abstützkontur 3 the clamping sleeve 2 ,

At the opposite end of the locking ring 20 are elongated bridges 23 formed by recesses 22 are separated from each other. The bridges 4 the clamping sleeve 2 be in the recesses 22 of the locking ring 20 introduced.

The spring element 10 ( 1c ) has substantially the shape of an open ring, wherein the spring element 10 is conically shaped inside. One end of the spring element 10 is two-tiered 11a . 11b educated. Between the surface 3a the supporting contour 3 the clamping sleeve 2 and the area 21a driver contour 21 of the locking ring 20 are the ends 11b . 12 of the spring element 10 curious; excited.

By a relative movement of the locking ring 20 to the clamping sleeve 2 the distance between the driver contour changes 21 to the support contour 3 , This will cause the spring element 10 expanded, so that the diameter D, depending on the direction of rotation of the locking ring 20 , changed. Upon rotation of the locking ring 20 to the end position clockwise (locking direction) is the diameter of the spring element 10 minimal D1. At the same time, the webs push 4 and 23 over each other and jam the clamping sleeve 2 with the locking ring 20 according to the bayonet principle. With opposite rotation (opening direction) of the locking ring 20 becomes the diameter of the spring element 10 maximum D2 and the bars 4 and 23 do not stand on top of each other, so the clamping sleeve 2 from the locking ring 20 can be removed.

The cable outlet nozzle 30 ( 2 ) is substantially cylindrical in shape and usually on a connector housing (not shown here) integrally formed. In the lateral surface of the cable outlet spigot 30 is one to the base area 32 parallel, circumferential groove 31 brought in.

The locking ring 20 equally encloses the clamping sleeve 2 and the cable outlet 30 ( 3 ). Upon rotation of the locking ring 20 in the end position of the locking direction, engages the conically shaped inner side of the spring element 10 precisely fitting in the circumferential groove 31 of the cable outlet nozzle 30 one. This will cause the adapter sleeve 2 on the cable outlet 30 fixed.

The inside conical shape of the spring element 10 causes when entering the circumferential groove 31 that the clamping sleeve 2 slightly downwards - in the direction of the cable outlet spigot - is pulled. The spring element 10 includes an edge on the outside 13 for centering the spring element 10 in the locking ring 20 serves.

The 4 shows an exploded view of the elements clamping sleeve, spring element and locking ring, which are suitable in the above described context for the fixation of the clamping sleeve on the cable outlet nozzle. The locking ring 20 is shown here in partially sectioned illustration. This is the contour 25 recognizable, the spring element 10 fixes or supports.

As previously announced, the strain relief of the cable and the sealing of the cable fixation device against media such as dust and water are now addressed.

The strain relief element 40 ( 5 ) consists essentially of end-side rings, which by a helical or helical structure 42 connected to each other. In 5 is a strain relief element 40 shown with double helical structure. That means it's between the ends 40a . 40b to find simultaneously a left-handed and a right-handed structure. This will provide a better centering of the cable in the strain relief 40 reached.

At the first end 40a the strain relief element 40 are radially outward contours 41 provided in matching recesses 33 of the cable outlet nozzle 30 are insertable. This will be the first end 40a the strain relief element 40 in the cable outlet 30 fixed against rotation.

At the second end 40b includes the strain relief element 40 radially outwardly pointing latch hooks 43 , These lock with locking contours 34 in the upper part of the cable outlet spigot 30 so that too the end 40b is rotatably fixed.

Furthermore, the strain relief comprises 40 at the second end 40b axially upwardly pointing driver hooks 44 , with driver contours 6 the clamping sleeve 2 interact. The driving hooks 44 have essentially the shape of a sawtooth. By a rotation of the clamping sleeve (relative to the cable outlet nozzle), in the direction of the falling edge of the driving hook 44 , will be the second end 40b the strain relief element 40 relative to the first end 40a moves and the helical structure between the ends 40a . 40b narrows. An interposed cable is clamped and so realized a strain relief for the cable.

Upon rotation of the clamping sleeve 2 against the falling edge of the driving hook 44 , the catch hooks slide 44 at the driver contours 6 the clamping sleeve 2 from. The ends 40a . 40b are not moved relative to each other.

In a reciprocating motion of the clamping sleeve 2 , the helical or helical structure can be lashed around the cable sheath of the cable to be connected, as with a ratchet. There is no need for another tool.

The second end 40b the strain relief element 40 is with the sealing element 50 connected ( 6a . 6b ). The catch hooks protrude 44 through recesses 54 , The cable to be connected is through the opening 51 of the sealing element 50 guided. The diameter Dd of this opening is in each case smaller than the diameter of the cable to be connected.

On the outside, the sealing element comprises 50 Press slats 52 , These ensure sufficient contact pressure of the seal on the cable outlet spigot 30 ,

The clamping sleeve 2 encloses part of the lateral surface of the cable outlet nozzle 30 , Inside the adapter sleeve 2 is a circumferential border 7 formed. Between this edge 7 and the boundary 35 the cable outlet 30 is the sealing element 50 in the assembled state of the device 1 arranged ( 7 ).

The inner sealing blades 53 along the opening 51 , reinforce the material density of the elastomer and thereby increase the contact pressure (tightness) to the cable sheath.

The 7 shows all components of the device for fixing, sealing and strain relief of a cable to be connected to a cable outlet connection of a connector, control cabinet or the like in operative connection.

The 8th shows an exploded view of the components 7 ,

Claims (9)

Cable strain relief and sealing system for cable outlets of connector housings or control cabinets, consisting of a strain relief element ( 40 ) and a sealing element ( 50 ), characterized in that the strain relief element ( 40 ) a helical structure ( 42 ) and with the sealing element ( 50 ) is operatively connected. Cable strain relief and sealing system according to claim 1, characterized in that the strain relief element ( 40 ) at a first end ( 40a ) Contours ( 41 ), which in recesses ( 33 ) of the cable outlet connection ( 30 ) are insertable, so that the strain relief ( 40 ) at this end ( 40a ) is fixed against rotation. Cable strain relief and sealing system according to claim 2, characterized in that the strain relief element ( 40 ) at a second end ( 40b ) radially outwardly facing latching hooks ( 43 ), which in associated latching contours ( 34 ) of the cable outlet nozzle ( 30 ) are engageable, whereby the strain relief ( 40 ) at the second end ( 40b ) is rotatably fixed in one direction of rotation. Cable strain relief and sealing system according to claim 3, characterized in that the strain relief element ( 40 ) at the second end ( 40b ) axially outwardly facing driver hooks ( 44 ), and the clamping sleeve ( 2 ) inside matching driver contours ( 6 ), so that by a relative movement of the clamping sleeve ( 2 ) to the strain relief element ( 40 ) in a first direction, the second end ( 40b ) of the strain relief element relative to the first - in the cable outlet connection ( 30 ) - fixed end ( 40a ) is movable. Kabelzugentlastungs- and sealing system according to claim 4, characterized in that the driving hook ( 44 ) of the clamping sleeve ( 2 ) are shaped such that during a relative movement of the clamping sleeve ( 2 ) to the strain relief element ( 40 ) in a second direction, the catch hooks ( 44 ) of the strain relief element ( 40 ) on the driving hooks ( 44 ) of the clamping sleeve ( 2 ) are slidable along. Cable strain relief and sealing system according to one of the preceding claims, characterized in that strain relief element ( 40 ) a first ( 42a ) and a second ( 42b ) has helical structure, which are opposite to each other, ie one right-handed and the other left-handed, are formed. Cable strain relief and sealing system according to claim 1, characterized in that the sealing system ( 50 ) is disc-shaped and centrally a circular opening ( 51 ) whose diameter (Dd) is smaller than the diameter of a cable to be sealed. Cable strain relief and sealing system according to claim 1 or 7, characterized in that the sealing system ( 50 ) one-sided press blades ( 52 ) extending substantially along the circumference. Cable strain relief and sealing system according to claim 1 or 7 to 8, characterized in that the sealing system ( 50 ) one-sided sealing blades ( 53 ) substantially concentric around the opening (FIG. 51 ).

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