DE102008049959B4 - Pipe coupling element - Google Patents

Abstract

A pipe coupling member having a body having a through-channel with an orifice and an axis, and a locking device having an annular wall surrounding the axis with an engagement geometry, wherein the annular wall is divided into a plurality of sections in the circumferential direction, wherein movable portions having a contiguous peripheral region cover at least 180 °, each formed as a rocker, which are pivotable from a mounting position into a locking position, wherein a slider is provided which surrounds the annular wall and is translationally displaceable parallel to the axis, characterized in that the slide (18) a Has locking device.

Description

The invention relates to a pipe coupling element having a body, which has a through-channel with an orifice and an axis, and a locking device, which has an annular wall surrounding the axis with an engagement geometry, wherein the annular wall is divided into several sections in the circumferential direction, wherein movable sections, which cover a continuous circumferential region of at least 180 °, each formed as a rocker, which are pivotable from a mounting position into a locking position, wherein a slide is provided which surrounds the annular wall and is translationally displaceable parallel to the axis.

Such a pipe coupling element serves to form a fluid connection between two pipes. The pipes may also be present outside the pipe coupling as a hose or the like. It is also possible that with the help of such a pipe coupling a hose is connected to a pipeline, as is the case for example in the household in a washing machine or a dishwasher.

The invention will be described below with reference to a connection for a household washing machine. But it is also applicable to other uses, for example when connecting a hose to a heat exchanger in a motor vehicle.

If you want to connect the hose of a washing machine to a faucet or another connection of a laid in a house pipe, then the corresponding pipe coupling element usually has a union nut. The corresponding counterpart on the pipe has an external thread. To produce the pipe coupling, the union nut is attached to the external thread and screwed. The body is used on the counterpart. A seal disposed between the body and the counterpart is then compressed in the axial direction and accordingly seals the transition from the counterpart to the pipe coupling element.

The installation of such a pipe coupling is not only expensive, but also brings the risk of incorrect assembly with it. For example, if the union nut is tightened with excessive torque, the seal may be squashed and unable to perform its sealing function. Another problem arises from the fact that after completion of the assembly, the pipe connected to the pipe coupling element is moved. In this case, under unfavorable circumstances, the union nut can be rotated in the release direction, so that the tightness is also no longer guaranteed.

Out EP 0 340 194 A1 is a hose or pipe coupling known. The hose or pipe coupling has a female coupling element, a male coupling element and a locking device. The locking device has arms, a trained as a spiral locking element and a ring. The arms are pivotally arranged about a point on the female coupling element and engage in the male coupling element. Two to eight arms surround almost the entire circumferential direction of the clutch. The arms have guide surfaces on which the locking element and the ring are slidably disposed. Depending on the position of the locking element and the ring, the arms are in a locking position in which the coupling elements are connected, or in an open position in which the two coupling elements are releasable.

Out DD 253 070 A1 is a quick coupling between hoses and valves or pipes known. The quick coupling has a hose connection with a cone, a connecting piece and a fitting. At least two rockers are arranged on the circumference of the hose connecting piece. The rockers are mounted in grooves and are half enclosed by a sleeve which is axially displaceable on the rockers and thus on the hose connection piece. If the sleeve is pushed in the direction of a fitting fitting to a sealing ring, the rockers are pressed against the thread present on a connecting piece.

The invention has for its object to make the installation of a pipe coupling easy.

This object is achieved in a pipe coupling element of the type mentioned above in that the slide has a locking device.

With such a configuration, the assembly of the pipe coupling element is relatively simple. You move the rockers in their mounting position. In this position, an opening at the free end of the pipe coupling element is greatest. With this large opening, the pipe coupling element can then be placed on the counterpart. The rockers are then pivoted into their locked position. As a result, the opening at the free end of the pipe coupling element is reduced so far that the rockers are set with their engagement geometry on the counterpart. One then only has to prevent the rockers from the locking position can swing back into the mounting position. But this is possible without much effort. A slider is provided, which surrounds the annular wall and is translationally displaceable parallel to the axis. If the slider is moved, for example, to the free end of the pipe coupling element, then the rockers are pivoted from the mounting position to the locked position and held by the slider in this locked position. On the other hand, if the slider is moved to the other end of the rockers, then the rockers are no longer held at their free end, so that they can be pivoted to the mounting position. The slider has a locking device. Such a locking device can be used together with or without spring. The locking device, however, secures the slider to be moved out of the position in which it holds the rockers in their locked position.

Preferably, a spring is arranged between the slider and a support flange on the body. This spring pushes the slider so that the rockers are held in the locked position, and holds the slider in this position. An accidental release of the rockers, d. H. accidental pivoting from the locked position back into the mounting position is thus prevented with great reliability.

Preferably, the spring is attached to the slider. This facilitates handling during assembly of the pipe coupling element.

It is also advantageous if the spring is formed of plastic and formed integrally with the slider. The slider and the spring can then be formed together as an injection molding element, for example. In this case, it is not necessary that the slide and the spring are formed from the same plastic material. It's enough if they can be made together.

It is advantageous if the spring has a maximum extent in which the slide is arranged in the axial direction still on the annular wall. In this case, virtually no measures for a captive are required. It may be convenient to connect the spring with the body. This connection is only lightly loaded and accordingly can also be correspondingly weak.

It is preferred that the locking device has at least one support which is movable into a supporting position in which it supports the slider relative to the body. For the displacement of the slider, it would then be necessary to deform the support. This is generally not possible, so that the support moved into the support position or the corresponding supports sufficient to hold the slide with the necessary reliability in the position in which he keeps the rockers in turn in the locked position.

Preferably, the support is pivotally mounted on the slider and optionally has a bias in the direction of the Stutz position. If the support is pivotally mounted on the slider, then you can ensure that the support and the slider are permanently connected to each other. Once the slider has been moved to its final position in which it holds the rockers in the locked position, you can swing the support so that it supports the slider relative to the body, in particular the support flange. When choosing the direction of the pivot axis you have relatively great freedom. The pivot axis may be directed radially, for example, relative to the axis. But it can also be designed as a tangent to the slider. If the post has a bias towards the support position, then the post will automatically snap into the support position when the pusher has been moved to its final position.

Preferably, each rocker includes with its radial outside an obtuse angle which extends parallel to the axis. With this embodiment, the assembly of the pipe coupling element is further simplified. In order to pivot the rockers from the mounting position to the locking position, the slider only has to be moved away from the open end of the pipe coupling element to the other end of the slide. Due to the V-shaped configuration, the slider then pushes inwardly the ends of the rockers, where the engagement geometry is not located, so that the engagement geometry is moved radially outward. This creates the desired mounting opening, so that the pipe coupling element can be placed on the corresponding counterpart. By moving the slider in the opposite direction is achieved due to the V-shaped configuration that the rockers are moved with their engagement geometry again radially inwardly to make the connection with the counter element of the pipe coupling element.

Preferably, each rocker in the locking position on a first portion of its outer wall, which is parallel to the axis. Once the slide has reached this section, it can be moved without much effort to its final position. The end position is provided so that the slide with a long "lever arm" acts on the rockers, so that a very large force would be required to pivot the rockers from their locking position back to the mounting position. This results in a relatively high compressive strength in the use of the pipe coupling element for producing a pipe coupling.

Preferably, each rocker is pivotable with its engagement geometry by a distance which is greater than a depth of the engagement geometry. This makes it possible to completely free the rocker from the engagement geometry of the counter element or it is possible to bring each rocker without interference by the engagement geometry of the counter element with the counter element in engagement. The risk of damage and the resulting leakage is thus relatively low.

Preferably, each rocker is supported by a support foot on the body. This results in good geometric conditions for the pivot axis about which the rocker pivots relative to the body. With the support foot, the rocker with respect to the pivot axis is radially displaced slightly outwards, so that the rocker can be pivoted relatively freely, without being affected by other elements of the body.

It is preferred that the support leg is arranged in a groove. The groove, however, ensures that the support foot and thus the rockers in the axial direction, d. H. parallel to the axis, can be displaced when the rocker is pivoted from its mounting position to the locked position.

It is preferred that the groove is formed as a circumferentially continuous annular groove. This can be achieved that the body is rotatable relative to the rockers. This makes it possible to change the angular position of the pipe coupling element relative to the counter element, so that one can reach, for example, another outlet angle for a pipe connected to the pipe coupling element without the risk that the pipe coupling element is released from the counter element.

Preferably, the support foot in the circumferential direction has a smaller width than the rocker. This achieves a simple way that the rocker is freely pivotable between its mounting position and its locking position.

Preferably, the support leg is arranged in the axial direction with a predetermined distance behind the mouth. Thus, the rocker overlaps the mouth. The mouth can then be retracted into a corresponding opening on the counter element, without such a movement being disturbed by the rockers.

The invention will be described below with reference to preferred embodiments in conjunction with a drawing. Herein show:

1 several illustrations for explaining the basic structure of a pipe coupling element,

2 several possibilities of an engagement geometry of a counter element,

3 a section through another pipe coupling element,

4 the pipe coupling element after 3 mounted on a counter element,

5 a partial section VV after 3 and

6 a further embodiment of a pipe coupling element.

1 shows various sections in the manufacture of a pipe coupling element. The pipe coupling element 1 has a body 2 on. In the body 2 is a passageway 3 with a mouth 4 arranged. To simplify the following explanation, an axis is used 5 the estuary 4 Are defined. The passageway 3 is in the present embodiment in a socket 6 away, the several ribs 7 on its outside. At the neck 6 can be fixed in a manner not shown, a hose or a plastic pipe.

The estuary 4 is from a round cord sealing ring or O-ring 8th surround. The O-ring 8th when using a pipe coupling element 1 a connection with a counter element 9 want to produce, of which different embodiments in 2 are shown in an opening 10 of the counter element 9 introduced and seals there radially.

To the corpus 2 in the counter element 9 to hold is a locking device 11 provided, one the axis 4 having surrounding annular wall. The ring wall is like this 1b shows divided in the circumferential direction in several sections. Each section has an engagement geometry on its radially inner side 13 on. This engagement geometry 13 is the engagement geometry of the counter element 9 adapted with the pipe coupling element 1 to be connected. In the present exemplary embodiment of 1 and 2a is the engagement geometry 13 formed as an axial sequence of circumferential notches 14 that with corresponding protrusions 15 can be brought into engagement with the counter element.

The sections are called seesaws 12 trained with a support leg 16 in a groove on the circumference of the body 2 are supported. As in particular from 1b it can be seen, the seesaws have 12 on its radial outside the shape of a very flat V. So the two sections of the V include an obtuse angle.

In 1c is shown on the seesaws 12 a slider 18 is attached, the the seesaw 12 surrounds. The slider 18 can be parallel to the axis 5 opposite the body 2 be translated translationally.

When the slider 18 to the neck 6 is moved, then he pivots the rockers 12 around the support foot 16 so that the seesaws 12 open at its free end, ie enlarge an opening, in which then the counter element 9 can occur. When the slider 18 however, from the neck 6 is moved away, so the open end, then the seesaws 12 pivoted in the opposite direction so that they are brought into abutment with each other in the circumferential direction, whereby the notches 14 the engagement geometry 13 be engaged with the projections 15 on the counter element 9 , As long as the slider over the front end of the rockers 12 pushed, can the seesaw 12 Do not open and the engagement between the coupling element 1 and the counter element 9 remains. This also applies to larger pressures, for example, 20 bar.

To cancel the procedure, the slider is 18 in the opposite direction, so to the neck 6 postponed. Due to the V-shape of the rockers 12 the slide opens 18 then the seesaws 12 by putting them around the support foot 16 pivoted, leaving the notches 14 from the projections 15 come free and the corpus 2 from the counter element 9 can be deducted.

However, one is in the design of the engagement geometry 13 not on the in 1 and 2a illustrated geometry with notches 14 and protrusions 15 limited. The 2 B to 2d show other shapes. In 2 B is a single lead 19 shown. Again, the O-ring 8th in the opening 10 on the counter element 9 inserted and the intervention takes place via the single projection 19 , The engagement geometry 13 on the radial inside of the rockers 12 then has an appropriate training.

In the embodiment according to 2c is a circumferential bead 20 at an axial distance from the opening 10 arranged. Again, the O-ring 8th in the opening 10 introduced and by the collapse of the rockers 12 becomes the engagement with the bead 20 produced.

In 2d has the counter element 9 also the opening 10 into which the O-ring 8th can be introduced, whereas a cone 21 in the area of the opening 10 the counter element 9 that's on its back 22 forms an engagement surface.

The 3 to 5 show a modified embodiment.

A counter element 23 has an external thread as engagement geometry 24 on. In the coupling element 1 is the neck 6 at an angle of 90 ° to the axis 5 arranged. Accordingly, the passageway 3 also at an angle of about 90 °. Incidentally, elements corresponding to those of 1 and 2 correspond, provided with the same reference numerals.

In particular in 3 can be the V-shape of the rockers 12 detect. The support foot 16 in the groove 17 forms a pivot axis. When the slider 18 from the free end 25 is moved away (arrow 26 ), then comes from a first section 27 the seesaw 12 , which in the locking position parallel to the axis 5 runs to a second section 28 the seesaw 12 , in the locking position an angle of for example 10 to 20 ° with the axis 5 includes and pivots the second section 28 so that it is parallel to the axis 5 lies. This will be the first section 27 the seesaw 12 pivoted radially outwards, so that the engagement geometry 13 from the external thread 24 is released. The engagement geometry is formed in this case as an internal thread.

To make sure the slider 18 in the locking position of the rockers 12 stays is a spring 29 provided on a support flange 30 of the body 2 abuts and with the support flange 30 is connected, for example by gluing. The feather 29 is, just like the slider 18 , made of a plastic. The slider 18 and the spring 29 can be integrally formed, for example, by being produced together by injection molding.

The feather 29 has a maximum extent. This extent is such that the slider 18 not about the free end 25 the seesaw 12 can be postponed. However, the spring can be 29 , which is designed here as a helical spring, almost completely squeeze, so that the slider 18 over the second section 28 the rockers can be pushed to them at the free end 25 move apart.

As based on 5 can be seen, the support foot points 16 a seesaw 12 in the circumferential direction has a width which is smaller than the width of the rocker 12 in the circumferential direction. This makes it possible to tilt the rocker 12 around the support of the support foot 16 in the groove 17 easier to reach. Dashed is a floor 31 the groove 17 shown. It can be seen that the groove 17 is formed continuously in the circumferential direction. So you can do the corpus 2 opposite the seesaws 12 twist without the intervention of the rockers 12 with the external thread 24 on the counter element 23 is resolved.

With the in the 3 to 5 illustrated embodiment of a pipe coupling element 1 can replace the conventional union nut. The assembly of the pipe coupling element 1 on the corresponding counter element 23 is greatly simplified. All you have to do is get the body 2 with the O-ring 8th in an opening of the counter element 23 introduce. In this state is the slider 18 pushed back, ie he is the support flange 30 adjacent. The seesaws 12 have been swung apart, as by a double arrow 32 is indicated. If the body 2 opposite the counter element 23 is arranged in its final position, then the slider 18 on the counter element 23 too moved and the seesaws 12 will be opposite to the direction of the double arrow 32 moved towards each other, leaving the external thread 24 on the counter element 23 tightly enclose. The slider 18 will be in this position by the spring 29 held.

A change of the counter element 23 is therefore not required.

Through the O-ring 8th an improved tightness is achieved. An embodiment has shown a compressive strength up to 20 bar. The pipe coupling element 1 is opposite the counter element 23 freely rotatable without affecting the connection between the pipe coupling element 1 and the counter element 23 solves.

Shown is that all sections of the locking device 11 as seesaws 12 trained and thus are mobile. However, this is not mandatory. It's enough if the seesaws 12 circumferentially cover a continuous area of at least 180 °. In this area, however, should at least two seesaws 12 be arranged.

The pivoting movement of the rockers 12 is dimensioned so that during an opening movement the rockers 12 the engagement geometry 13 from the corresponding engagement geometry on the counter element 9 . 23 comes free.

6 shows a further embodiment of a pipe coupling element 1 in which the same and functionally identical elements are provided with the same reference numerals.

The slider 18 is here by two props 33 opposite the support flange 30 supported. The pillars 33 are opposite the slider 18 pivotable about a pivot axis, which is approximately tangential to the outer circumference of the slider 18 runs. The pillars 33 can have some bias towards the in 6 having shown support position. If you have the slider 18 towards the support flange 30 then you have to move to a support surface 34 the prop 33 to press. This pressure becomes the support 33 with its free end attached to the support flange 30 abuts, radially pivoted, so that the support 33 from the support flange 30 comes free. In this situation, the slider is 18 no longer locked, but he can in the direction of the support flange 30 be moved.

A spring, not shown, may be additionally provided here. A use without spring is also possible.

The pillars 33 form a locking device that the slider 18 holding in the position in which the seesaws 12 have taken their locking position.

Claims (16)

A pipe coupling member having a body having a through-channel with an orifice and an axis, and a locking device having an annular wall surrounding the axis with an engagement geometry, wherein the annular wall is divided into a plurality of sections in the circumferential direction, wherein movable portions having a contiguous peripheral region cover at least 180 °, each formed as a rocker, which are pivotable from a mounting position into a locking position, wherein a slide is provided which surrounds the annular wall and is translationally displaceable parallel to the axis, characterized in that the slide ( 18 ) has a locking device. Pipe coupling element according to claim 1, characterized in that between the slide ( 18 ) and a support flange ( 30 ) on the body ( 2 ) a feather ( 29 ) is arranged. Pipe coupling element according to claim 2, characterized in that the spring ( 29 ) on the slide ( 18 ) is attached. Pipe coupling element according to claim 3, characterized in that the spring ( 29 ) formed of plastic and integral with the slider ( 18 ) is trained. Pipe coupling element according to one of claims 2 to 4, characterized in that the spring ( 29 ) has a maximum extent at which the Slider ( 18 ) is still arranged on the annular wall in the axial direction. Pipe coupling element according to one of claims 1 to 5, characterized in that the locking device at least one support ( 33 ) which is movable in a supporting position in which it the slide ( 18 ) is supported relative to the body. Pipe coupling element according to claim 6, characterized in that the support ( 33 ) on the slide ( 18 ) Is arranged pivotably and optionally has a bias in the direction of the support position. Pipe coupling element according to one of claims 1 to 7, characterized in that each rocker ( 12 ) with its radial outer side forms an obtuse angle parallel to the axis ( 5 ). Pipe coupling element according to claim 8, characterized in that each rocker ( 12 ) in the locking position a first section ( 27 ) parallel to the axis ( 5 ) runs. Pipe coupling element according to claim 8 or 9, characterized in that each rocker ( 12 ) in the assembly position a second section ( 28 ) has its outer wall parallel to the axis ( 5 ) runs. Pipe coupling element according to one of claims 8 to 10, characterized in that each rocker ( 12 ) with its engagement geometry ( 13 ) is pivotable by a distance which is greater than a depth of the engagement geometry ( 13 ). Pipe coupling element according to one of claims 1 to 11, characterized in that each rocker ( 12 ) via a support foot ( 16 ) on the body ( 2 ) is supported. Pipe coupling element according to claim 12, characterized in that the support foot ( 16 ) in a groove ( 17 ) is arranged. Pipe coupling element according to claim 13, characterized in that the groove ( 17 ) is formed as in the circumferential direction by the annular groove. Pipe coupling element according to one of claims 12 to 14, characterized in that the support foot ( 16 ) in the circumferential direction a smaller width than the rocker ( 12 ) having. Pipe coupling element according to one of claims 12 to 15, characterized in that the support foot ( 16 ) in the axial direction with a predetermined distance behind the mouth ( 4 ) is arranged.

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