EP0396513A1

EP0396513A1 - An automatically-connected electrical connector

Info

Publication number: EP0396513A1
Application number: EP90830176A
Authority: EP
Inventors: Oreste Vittone; Matteo Picciriello
Original assignee: Fiat Auto SpA
Current assignee: Fiat Auto SpA
Priority date: 1989-05-03
Filing date: 1990-04-24
Publication date: 1990-11-07
Anticipated expiration: 2010-04-24
Also published as: EP0396513B1; DE69012411T2; IT8967318A0; IT1232085B; DE69012411D1; BR9002125A

Abstract

A device is described for connecting multiway connectors to each other or to electrical equipment, the device enabling elastic energy to be stored during the first part of its connecting travel and to be returned during the second part as a force pulling the device to its travel-limit position thus enabling the automatic complete connection of the connectors (1, 2) and reliable electrical contact to be achieved automatically.

Description

The present invention relates to an electrical connector of the type corresponding to the first part of Claim 1.
Electrical connections between the battery and electrical accessories of a motor vehicle are made by means of male/female electrical terminals (also called "pins") carried by multiway connectors (also commonly known as blocks).
This facilitates electrical connection at the assembly stage and enables the electrical equipment of a motor vehicle to be maintained and replaced during the vehicle's lifetime.
The connection normally consists of two complementary half-connectors (male and female) which are joined together.
The problem inherent in connections of this type is the possibility that, during assembly, the operator may interconnect the two half-connectors only partially (not fully); this partial connection naturally does not show up during testing since it is able to transmit current temporarily but may cause the half-connectors to come apart later, during use of the vehicle, because of vibrations, with the consequent disconnection of the services dependent on the connectors concerned.
It has also been proposed (British patent application No. 2 169 758) to provide one half-connector with resiliently-deformable elements in order to increase the force needed for the insertion of the half-connector up to an intermediate point, called the "dead point", so as then to make use of the resulting impulse to reach the travel limit.
Even this type of connector has some disadvantages, however, again due to the possibility of only partial connection during assembly.
The present invention proposes to solve the problems mentioned above so as to provide an electrical connector which is reliable, strong, cheap and easy to handle.
The objects are achieved, according to the invention, by an electrical connector of the type described above having the further characteristics corresponding to the second part of Claim 1.
The dependent claims give some advantageous solutions of the electrical connector according to the invention.
Further advantages and characteristics of the invention will become clear with reference to the appended drawings, in which:

Figures 1 to 4 show the electrical connector according to the invention during the stages of connection of two half-connectors;
Figure 5 shows the elastic-energy-storage device of the connector according to the invention;
Figures 6a and 6b indicate qualitative changes in some quantities which come into play during the connection;
Figures 7a and 7b indicate quantitive changes in some quantities which come into play during the connection;
Figure 8 shows some positions of the elastic-energy-storage device according to the invention during its connection travel;
Figure 9 shows the qualitative variations in the pulling force with variations in the angle of inclination of the bearing surface of the energy-absorption device according to the invention;
Figure 10 shows the changes in the forces which come into play during the entire connection travel.

The embodiment of the electrical connectors according to the invention relates to the mechanical and electrical connection of two separate ribbons of cables 9 and 10 but the invention is also suitable for a case in which a half-connector, such as 1, is to be inserted in a corresponding seat in electrical equipment carrying electrical connections.
The electrical connector according to the invention consists of a first half-connector 1 carrying within it male/female electrical cable terminals, also called pins (not shown in the drawings), of a ribbon of cables 9 and a second half-connector 2 carrying within it male/female electrical cable terminals, also called pins, of another ribbon of cables 10. A "V"-shaped spring 4 is fixed at 3 in the half-connector 1 with the axis of symmetry of the "V" coincident with the longitudinal axis of the connector according to the invention.
In correspondence with the position in which the spring 4 will be situated after connection, the half-connector 2 has walls 11 with inclined surfaces 7.
The insertion of the half-connector 1 into the half-connector 2 is achieved in the following manner: the two half-connectors 1 and 2 are placed face to face with the spring 4 and the wall 11 in contact with each other; at this stage, the force Fo (the force exerted on the half-connectors by the operator) is zero (Figures 1 and 2).
As the insertion travel is continued (Figure 3), the force Fo increases in value because of the loading of the spring 4 until the two arms 6 of the latter reach the "dead point", that is they come into contact with the corners 7′ of the walls 11; in this position, the spring 4 has stored all the elastic energy and the operator has exerted the maximum force Fo.
Electrical contact between the pins of the half-connectors 1 and 2 has not yet been achieved at this moment; it occurs only after the "dead point".
As soon as the "dead point" is reached, the half-connector 1 is pulled into the half-connector 2 by the elastic force stored in the spring 4 whose arms 6 act on the inclined planes 7 which are arranged so as to pull the two half-connectors 1 and 2 towards each other.
During this travel, in order to keep the two half-connectors 1 and 2 in equilibrium, it would be necessary to reverse the force Fo exerted from outside.
The spring 4 therefore develops a force Fr, a pulling force, which ensures the complete and automatic connection of the two half-connectors 1 and 2, that is without any force on the part of the operator, enabling the connection of the male/female pins of the block and also overcoming the resulting friction.
When they have reached their travel limit, the two half-connectors are connected permanently by a positive engagement (not shown in the drawings) which can be released in known manner so that the two half-connectors 1 and 2 can be separated and the two ribbons of cables 9 and 10 disconnected.
If friction is left out of consideration, the force Fo depends on the angle of the spring 4 as well as on its geometry and resilient characteristics, the angle meaning, more precisely, that which is formed between the longitudinal axis of the connector and the tangents to the two arms of the spring 4 at their points of contact with the corners 7′ of the walls 11; this angle varies during the connection travel from an initial maximum to a minimum when the "dead point" is reached and then increases again during the "pulling".
The force Fr depends on the orientation of the inclined surfaces 7 of the walls 11 and on the elastic force stored in the spring 4.
It should be noted that the"V"-shape of the spring 4 is only an example, since it is possible to think of other configurations with any other type of resilient device for storing the energy obtainable during the first stage of the connection travel. For example, a helical spring could be inserted between the two arms 6 of the spring 4, perpendicular to the longitudinal axis of the connector, for storing elastic energy. In this case the two arms of the "V"-shaped device could be rigid and hinged at the vertex of the "V".
The resilient element of the engagement system may be the spring 4 alone, as indicated in the drawings, or the walls 11 may be resilient so as to absorb energy, the "V"-shaped device being rigid. It is even possible to combine the two extreme cases, that is a spring 4 and walls 11 which are both resilient so as to absorb energy.
As stated, the electrical contact takes place only after the "dead point", thus ensuring that it is impossible for the operator to connect the two half-connectors 1 and 2 only partially. In fact, (once the operator is no longer exerting the force Fo (Figure 2)), the two half-connectors are either completely connected (Figure 4) or they are disconnected so that, even in the event of a connection not being achieved, this anomaly is immediately shown up and corrected upon testing.
With reference to Figures 5 to 10, the changes in the forces which come into play will now be explained. The graphs have been determined with the sliding friction between the contact surfaces of the spring 4 and the walls 11 being ignored for simplicity of explanation. Naturally, the friction, which is present in reality, will be such as to require the operator to exert a greater force Fo to achieve the same elastic deformation as in the case of zero friction. Similarly, when the "pulling" force comes into play, the force available for the connection of the electrical pins will be less, for a given elastic deformation of the spring 4, because of the friction.
Figure 5 shows the position of the spring 4 during the insertion of the half-connector 1 into the half-connector 2 in continuous outline and its initial position and the "dead point" position in chain line. In Figure 5, the following values are shown:
α = the angle of the arms 6 (according to the definition given above), the indices "i" and "o" indicating its initial value and its dead-point value respectively.
Fo = the force applied by the operator to the half-connector 1,
Fo/2 = the reaction force exerted by the restraints along the axis of the connector,
Fe = the elastic deformation force,
If, as stated, the frictional forces are ignored, then by simple mathematical steps:
Fe = Fo/2 x 1/sin α
From a study of this formula it can be seen that, for a given force Fo, the resilient force Fe is greater the smaller the angle α.
Figures 6a and 6b show qualitative changes in the angle α and in the elastic deformation force Fe during the connection travel up to the "dead point" indicated xo.
Figures 7a and 7b show a numerical example of the values of the angle α and of the elastic force Fe respectively on the ordinates as functions of the connection travel.
Figure 8 shows some positions of the spring 4 during its pulling travel, together with a graphical representation of the forces, the sliding friction of the arms 6 on the surfaces 7 of the walls 11 being ignored, as already stated. Thus, by simple steps:
Fe = F_r/2tg β
β being the angle between the inclined surface 7 and the longitudinal axis of the connector.
It can be seen that, for a given stored elastic force, the pulling force Fr is the greater the greater the angle β.
On the other hand, the travel achieved by the pull up to the complete restitution of the stored elastic energy (Fe=0) is naturally smaller the greater the angle β . The optimum value of β must therefore reconcile two conflicting requirements, which are: a) to maximise the pulling force Fr for a given elastic force Fe up to the point of complete connection;
b) to maximise the travel due to the pull in order to ensure the complete connection of the male-female contacts.
A good compromise is given when β is between 40° and 50°.
Figure 9 shows the qualitative changes in the elastic force Fe and in the force Fo acting along the longitudinal axis of the connector as functions of the connection travel. The family of curves after the point xo ("dead point") has been crossed indicates how the pulling force Fr changes with variations in the angle of inclination β of the inclined surfaces 7 of the walls 11.
Figure 10 shows the qualitative changes in the forces which come into play in the connector throughout the connection travel. As well as the changes in the forces Fe, Fo and Fr already described with reference to the preceding figures, the mechanical characteristic of the force Fa for the connection of the electrical terminals, also known as pins, is also shown.
It can be seen that the pulling force Fr is such as to exceed the force Fa for connecting the electrical terminals so that the equilibrium between the two forces takes place downstream of the positive engagement point shown by the broken line 8 in the drawing.
Moreover, it is clearly shown in Figure 10 that electrical contact starts to occur downstream of the "dead point" so that electrical contact is not possible when the pins are only partially connected.
If friction is ignored, the energy stored during the first stage is equal to the energy returned during the second stage, that is, as a first approximation:
Fo x l₂ = Fr x l₁, (in exact terms
where l₂ and l₁ are the longitudinal components of the arms of the spring 4 and of the inclined surfaces 7 respectively. From this formula it can be deduced that the pulling force Fr can be made greater than Fo in order to ensure the automatic connection of the two half connectors by changing the geometry of the energy-storage system, in this case for example, by increasing l₂ relative to l₁.

Claims

1. An electrical connector, preferably for multiway connections in the electrical system of a motor vehicle, comprising a first half-connector (1) carrying male/female terminals of a first ribbon of cables (9) and a second half-connector (2) carrying female/male terminals of a second ribbon of cables (10) or of electrical equipment,
characterised in that
it includes a resilient device which stores energy during a first stage in the connection of the half-connectors (1, 2) and which can return the stored energy to enable the automatic connection of the first and second half-connectors (1, 2) during a subsequent, second stage in the connection of the half-connectors (1, 2).

2. A connector according to Claim 1,
characterised in that
the resilient device for storing energy comprises a "V"-shaped spring (4) fixed at its vertex in the first half-connector (1), symmetrically with respect to the longitudinal axis of the connector, and the second half-connector (2) includes walls (11) with surfaces (7) which are inclined at an angle β to the longitudinal axis of the connector, the walls (11) being adapted to cause the elastic deformation of the "V"-shaped spring during the connection and the inclined surfaces (7) being adapted to generate a force for inserting the half-connector (1) into the half-connector (2).

3. A connector according to Claim 2, characterised in that the angle β is between 40 and 50°.

4. A connector according to Claim 2 or Claim 3,
characterised in that the longitudinal component (l₂) of the length of the arms of the "V"-shaped spring (4) is greater than the longitudinal component (l₁) of the length of the inclined surfaces (7).

5. A connector according to any one of Claims 2 to 4,
characterised in that the longitudinal component (l₁) of the length of the inclined surfaces (7) is greater than or equal to the travel necessary for the electrical coupling so as to prevent partial electrical coupling.

6. A connector according to any one Claims 2 to 5,
characterised in that
the walls (11) with inclined surfaces (7) are rigid.

7. A connector according to any one of Claims 2 to 6,
characterised in that the walls (11) with inclined surfaces (7) are themselves resilient.

8. A connector according to any one of the preceding claims,
characterised in that it includes an engagement system for preventing the accidental release of the two half-connectors (1, 2).