NO131223B - - Google Patents

Description

Collapsible connecting device.

The present invention relates to new and improved electrical contact devices, and in particular collapsible connection devices for conductors with large diameters.

Connection devices of this type are often, but not always, used on electrical conductors in the power supply. And normally a designer who has to make such connecting devices encounters a number of problems. The connection devices should be suitable for use in connection with conductors with different cross-sectional shapes and different diameters. Moreover, when placed around the conductor, the connection device should close close to and almost seal it to prevent the ingress of foreign elements and contaminants such as moisture and the like. And once the conductor is sealed, the seal must be maintained. E.g. the connector must be of such a shape that when pressure is applied at points along the conductor to seal it tightly, this local compression or shrinkage does not cause the adjacent parts of the connector that have already been sealed to spring back open. Also, if the conductors are wound in a spiral, the connection device must be designed so that it does not burst open if the cable exerts an inherent outward pressure as a result of its spiral shape. There are a number of known collapsible connection devices, but none of them satisfy all the above-mentioned requirements.

An object of the present invention is to provide compressible electrical connection devices with a built-in closing rib which locks and holds the cable and which produces a mechanically and electrically secure joint.

Another object is to provide a connection device which can be sealed with a fixed contact pressure against the conductor and which will not spring up again at a previously sealed point when a nearby point is subjected to pressure to seal the conductor.

A further object of the invention is to provide connection clamps which will withstand internal pressure exerted by the conductors and will retain their closed condition after being sealed.

And finally, it is an object of the invention to produce a connection device that can be used for a number of different cable diameters.

All this is achieved by designing the connection device according to the patent claims set out below.

In order to provide a clearer understanding of the invention, reference is made to the detailed description below of an exemplary embodiment with reference to the accompanying drawings where: Figure 1 shows a perspective sketch of the connection clamp before it is pressed together, Figure 2 shows a side view of the connection clamp before compression, Figure 3 shows another side view of the connecting clamp while the compression tool presses the cams inwards over the corresponding recesses and against the oppositely placed arms and also shows the hinge effect at the transition between the cam and the arm to which it is attached. Figure 4- shows a cross-section of the coupling clamp fully compressed and with the lugs locked in their final position. Figure 5 shows a side view of the coupling clamp after compression. Figure 6 shows a perspective sketch of another embodiment of

-up finn-e 1 s one

Figures JA, 7B and 7C (corresponding to the fragments in Figure 4-which are inside the dash-dotted circle 7c) show end views of these fragments for a modified version of the cam and the corresponding part of an arm used on the coupling clamp , and Figures 8A (corresponding to the portion of Figure 6 surrounded by the dash-dotted line 8A), 8B and 8C show end views of a further modified construction of the cam and the corresponding portion of the arm of the coupling clamp.

Figures 1 and 2 show a connection clamp which represents a preferred embodiment which shows an example of the principle according to the invention. In general, this embodiment comprises a practically H-shaped body 11, made of a malleable metal. The body 11 comprises two pairs of arms 12 and 13 which extend outwards from an intermediate section 14. The arms 12 are placed some distance from each other so that a recess 15 appears between them. In a similar way, there is a distance between the arms 13 so that the recess 16 , which usually have somewhat smaller dimensions appear between these arms.

The body 11 is equipped with several longitudinally alternately arranged rows of deformable ribs 17 and grooves 18. In particular, the ribs 17 which extend along the recess will project into the recess 15 and along the inner surface of each arm 12.

The many deformable ribs 17 and the alternately arranged grooves 18 which are placed along the inner surface of each arm 12 and along the bottom of the recess form a practically folded arc-shaped cross-section. This shape of the ribs 17 and the grooves 18 ensures that the arm 12 is bent in a desired way as previously described and enables the arms 1.2 to join tightly to the conductor.

The body 11 is provided with several alternately arranged deformable ribs 21 and grooves 22 which extend along the bottom of the second recess 16 and along the inside of each arm 13. The ribs 21 extend into the recess 1"6.

In a similar way, the ribs 21 and the grooves 2 2 form an arched cross-section. It can be noted that because the recess 16 is somewhat smaller to be adapted to a smaller conductor, there are fewer ribs 21 which here extend along the bottom of the recess and up along the side of the arm 13 than there were along the bottom of the somewhat larger recess 15 and along the arms 12.

The ribs 17 in the recess 15 and the ribs 21 in the recess 16 form a yielding, deformable body which, under the influence of an external pressure, will adapt to the conductor's size and which will at the same time take the same shape as the conductor.

Closely connected to one of the arms 12 is a flexible knob 2 3 which extends further out than the opposite arm 12. The knob 2 3 has a practically arc-shaped shape on both the inside and the outside. On the inside of the cam 23 there are a number of longitudinally deformable ribs 28 and grooves 29 which are arranged alternately, which ribs will deform when pressed against the conductor until they take the same shape as the conductor's surface. On the inside of the arm 12

and the cam 2 3 there is a locking rib or pawl 2 4 - and a corresponding groove or groove 2 5 for receiving the rib or pawl 24.

According to the invention, equipment is provided to form mechanical contact between the cam 23 and the oppositely directed arm 12 when the cam 23 is in its closed and compressed state where it folds around and holds the conductor which is placed in the recess 15.

Notches or serrations 2 6 are formed on the outside, the top surface or contact surface of the cam 2 3 and extend along the entire length of this cam from one end to the other. Corresponding locking notches or serrations 27 are placed on the inside or contact surface of the opposing arm 12 and extend along the entire length of such an arm. As will be seen, a conductor is introduced into the opening 15 with the cam 23 in the open position. In the event of subsequent clamping as shown in Figure 3, the recess 25 will come into engagement with the locking groove 24 and the cam 23, as it is hinged, is held in position above the conductor by this locking effect. This retaining hinge ensures that the cam 2 3 assumes a correct position when it is bent inwards into its corresponding recess 15 and inwards towards the opposite arm 12 even before the cam engages with this arm. Upon further compression, the cam 2 3 is pressed in over the opposite arm 12 and engages with this by means of the notches or serrations 2 6 on the contact surface of the cam 2 3 and the corresponding, complementary designed notches or serrations 2 7 on the contact surface of the arm 12 The conductor which is inside the recess is thereby encapsulated and retained inside the recess 15.

The length of the cam 23, or in other words, that stretch

of the cam 2 3 that extends from the corresponding arm 12 is somewhat smaller than the width of the recess 15 between the arms 12. This ratio ensures that the cam 2 3 will be able to move into the recess 15 when it is bent and will, when the connecting device is subjected to

external pressure ensure mutual mechanical engagement between the serrations on the cam and the arm.

A similar cam 31 is attached as an extension of one of the arms 13 on the same side of the conductor as the previously mentioned cam 23. The cam 31 extends outwards towards the end of the other, corresponding arm 13. Both the cam 31 and the arm 13 are designed on in a similar manner to the cam 2 3 and the arm 12, but in the figure different reference numerals'1 are used here for the details. Thus, respectively, 36 and 37 are alternately arranged rows of deformable ribs 3 6 and grooves 3 7 on the inside of the cam 31, 32 is a locking rib or pawl at the attachment to the cam 31, and 33 is the corresponding groove, 34 and 35 are serrations on the contact surface to the cam 31 and the arm 13.

To install the conductor 41, it is placed in the recess 15

and the cam 2 3 is bent in over the conductor by means of a clamping tool 42 as shown in figure 3. As indicated above, the cam 2 3 will be pressed into 1 the recess 15 within the opposite arm 12 and the abutment rafts of the cam 2 3 and the arm 12 engage with each other.

A smaller conductor 43 is placed in the recess 16 and the cam 31 is clamped over the conductor under pressure as shown in Figure 3. In a similar way, the cam 31 closes the recess 16.

The clamping tool 42 may be of any suitable type. The clamping jaws 42a, 42b are placed over the connecting device and are brought to exert a pressure whereby the body 11 is brought to assume the shape shown in Figures 4 and 5.

In particular, the tool 42 will squeeze the cams 2 3 and 31 into the corresponding recesses 15 and 16 and against the oppositely directed arms 12 and 13. When the cams 23 and 31 are bent, the locking ribs 24 and 32 will engage with their respective locking grooves 2 5 and 33 and result in a movable retention of the cams, whereby the cams are held in a correct position in relation to the oppositely directed arms 12 and 13. This first effect of the compression is best shown in Figure 3.

During continued compression of the tool 42, the arm pairs will

12 and 13 are bent towards each other so much that the landing rafts on the cams 2 3 and 31 come into contact with the landing rafts on the arms 12 and 13. This results in blocking by overlapping connections which encapsulate and retain the conductors 41 and 4 3 as shown in figure 4 The cams 2 3 and 31 and the arms 12 and 13 are then placed around their corresponding conductors 41 and 4 3 and are in close contact with these. Knobs 2 3 and 31

after the pressure is retained by the arms 12 and 13 due to mechanical interaction between the serrations 2€ and 34 on the landing rafts of the cams 23 and 31 and the corresponding, complementary serrations 27 and 35 on the landing rafts of the arms 12 and 13. Thus the connecting device is locked on a in such a way that a compression at a nearby point on the conductor will not cause the already achieved seal to pop up. Nor will an internal counter-pressure from the clamped cables be able to push up the seal that has been made.

During compression of the connecting device, the ribs will

17 and 2 8 will be deformed under the pressure against the conductor 41 so that they will assume the same shape as the surface of the conductor. When the ribs 17 and 28 are deformed, they will be pressed across the contact surface with the conductor with a cleaning effect at the same time as they form exactly to the shape of the conductor so that a very good connection is achieved.

As a result of grooves 18 being placed along the bottom of the recess 15 and along the inner surface of the arms 12, the arms 12 will bend towards each other at the bottom of the recess 15 and thereby prevent bulging at this area in the bottom of the recess.

If a mass or paste (not shown) is used inside the connecting device, this will remain in the grooves 18 and 29 as it is retained by the ribs 17 and 28. Moreover, such a mass will press in between the wires of the conductor and give a more effective effect .

It will be understood that as the ribs 17 and 28 yield and deform under the pressure against the conductor 41 when the connecting device is pressed against the conductor, they will adapt to the shape of the conductor and thereby prevent the conductor from being subjected to excessively high pressure. Of course, this deformation of the ribs 17 and 28 will lead to conductors with relatively large differences in diameter size and geometric shape being placed in connection devices of the same dimension.

The compression around the conductor 4 3 is carried out according to the same guidelines and works in a similar way.

Another embodiment of a collapsible connection device according to the invention is shown in figure 6. In this embodiment, the contact surface of the arm 12 is also provided with notches or serrations 44, but the contact surface of the cam 2 3 is, on the other hand, flat on its contact surface. During the compression, when a conductor is placed in the recess 15, the serrations 44 on the contact surface of the arm 12 will come into engagement with the flat part that forms the contact surface of the cam 23. The pressure force from the clamping tool will cause the smooth metal surface of the cam 2 3 to is deformed when it is pressed against the notches 44 and thereby a mechanical locking is achieved which will be very effective especially for connecting devices which consist of a soft, malleable metal which will flow during the pressing.

In a completely similar way, the contact surface of the arm 13 will be provided with notches or serrations, while the contact surface of the cam 31 is smooth. A locking can then be achieved in the same way for this part of the device.

Figures 7A, 7B and 7C show a modified construction of the cam 51 and the contact surface of an arm 52 which can be advantageously used in any of the embodiments in Figures 1-6. For the sake of overview, a dash-dotted circle has been drawn in figure 4

to identify where the fragments in Figure 7 belong. The contact surface of the cam 51 is provided with comb-like inclined surfaces 53 which are terminated by locking teeth 54. Corresponding pawl-shaped locking members 55 are placed on the contact surface of the arm 56. The inclined surfaces 53 guide each other when the connecting device is closed and the tips of the teeth come into engage with each other whereby the cam is maintained in the closed position.

In figure 7A, the cam is shown in the open state. When it is postponed

for pressure (Figures 7B and 7C) with a conductor placed in the recess (not shown), the surfaces 5 3 <p>g 5 5 will easily slide over each other. Thus, a secure locking is achieved between the teeth 54 and 55. This design has the advantage that it prevents a hasty locking of the device due to interference between the two contact surfaces. This feature further prevents the side walls of the connection device from collapsing after a conductor has been placed in it, and that an incorrect connection is formed which is neither tight nor has low electrical resistance.

Figures 8A, 8B and 8C show another modification of the cam 57 and the contact surface of an arm 59. The fragments shown correspond to the parts circled in Figure 6. This modified embodiment can preferably be used in one of the embodiments i., Figures 1, 6 and 7. As can be seen from figure 8A, the contact surface of the cam 5 7 is initially smooth, while the contact surface of the arm 5 8 is provided with a notch 59. The inclined position of the teeth facilitates the compression of the cam 59, and the tip of the teeth acts as barbs which prevents the cam from opening. During the compression (Figures 8B and 8C) with a conductor in place in the connecting device, the teeth 59 will come into strong mechanical engagement with the smooth surface of the cam 57, and the locking effect is produced by the metal in the side wall flowing into the notches 59 as previously discussed in connection with Figure 6.

For the sake of simplicity, the term "dental groove" will be used in general for all the previously mentioned forms of mechanical intervention. Consequently, in the claims the expression "fan-shaped -SJ>0^ will include both ribs and serrations as well as pal-shaped and comb-like surfaces.

Claims (5)

1. Collapsible electrical connection device with fixed closing lugs which can be locked in the clamped position and which provides an electrically and mechanically secure connection, which connection device consists of a body of malleable metal, with a practically H-shaped cross-section and with two pairs of outwardly projecting arms , which arms are placed some distance from each other so that there are intermediate recesses that are designed to accommodate each conductor, and where one of the arms in each pair of arms has an extension in the form of a knob that can be bent over the corresponding recess, characterized in that the length to each cam (23, 31) is smaller than the width of the corresponding recess (15,16) between the corresponding pair of arms, and that the cam and/or its opposite arm is provided with locking means to establish locking, mechanical engagement between the cam and its opposite arm when the cam is in its closed position, i.e. bent over the recess and in that the final clamping takes place by the opposite arm being pressed in against the cam, whereby the connection device encloses and retains the conductor which is placed in the recess. 2. Connecting device according to claim 1, characterized in that the locking means for establishing mechanical engagement comprise tooth-shaped grooves or notches formed on the contact surface of an arm, which tooth-shaped grooves are pressed into the contact surface of the knob during the final clamping and thereby form a locked, secure, mechanical connection . 3. Connection device according to claim 1, characterized in that the locking means for establishing mechanical engagement comprise tooth-shaped grooves or notches on the contact surface of both the arm and the cam, and that the tooth-shaped grooves on the arm fit together with the corresponding tooth-shaped grooves on the cam after clamping and thereby provide secure, mechanical locking. 4. Connection device according to claim 1, characterized in that the locking means for establishing mechanical engagement comprise a smooth contact surface on the arm and tooth-shaped grooves on the contact surface of the cam, and that the tooth-shaped grooves on the cam are pressed into the smooth contact surface on the arm during clamping, and thereby provides a secure, mechanical locking. 5. Connection device according to claim 1, characterized in that the cams can be bent over their corresponding recesses by means of a rotatable, hinge-like suspension with cooperating and locking guides (24, 25) which prevent the cam from being pressed out.