Patent Grant
8591249
The present invention relates to an automatically locking connector system for joining a first connector body with a second connector body. More particularly, the present invention relates to an automatically locking connector system that automatically disengages at a predetermined force.
Automatically locking connector systems are used for a variety of applications, such as electrical, fluidic, mechanical, optical, hydraulic or pneumatic systems, to provide a connection between various components and devices. A typical connector may comprise a female connector assembly and a male connector assembly that are designed to be engaged and disengaged with one another. Prior patents describe a coupling mechanism, having one coupler half that is inserted into the other half and a sleeve on one half, which rotates against a torsional spring force as a result of the camming action of complementary tabs on the sleeve and the inserted coupler half. The restoring force of the spring causes the sleeve to rotate into a locking position after the complementary tabs have passed each other. The tabs prevent disengagement of the coupler halves until the sleeve is twisted to permit the tabs to clear each other during uncoupling.
With telescopically mating electrical connectors, such as a plug and a socket, it is often desirable or necessary to lock the two connector bodies together after their conductive contacts have been physically and electrically joined. Single conductor connectors with some form of bayonet joint may be rotated to a locking position. Multiple male and female contacts, however, must be slidingly joined telescopically without rotation, and typically have used a pliable plastic connector body which is deformed as a catch on one connector body rides over a detent on the other connector body to a locking position beyond the detent.
Many locking connectors are designed to lock in the mated position and must be manually disengaged. However, in certain applications, it is desirable that the connectors automatically disconnect when a force exceeding a predetermined level is applied to the connector assembly or a cable extending from the connector assembly. For example, requirements exist in some industries and in various applications that a mated pair of connectors disengage (or break away) before the cable or the connectors are damaged or before the equipment or machinery to which the cable is attached is damaged. This helps to prevent damage to expensive machinery, components or personnel someone inadvertently trips over a cord, as the connector will disengage rather than transfer the force to the equipment. In other applications or environments, it is important to have a connector which can be easily engaged and disengaged quickly, without the need for cumbersome steps such as rotating the connector. This is particularly true in harsh environments or in military applications in which a soldier must be able to quickly connect and disconnect from equipment and the like.
While breakaway connectors, such as the Souriau JDX connectors, are known in the industry, these types of connectors can malfunction or be damaged if a significant off-axis or non-axial force is applied to the axis of the connector. As one half of the connector is mounted to a fixed member, the application of a significant off-axis or non-axial force can cause the connector halves to twist, which in turn causes the contacts to be damaged. In addition, if the off-axis or non-axial force does not translate to a large enough lateral force, the connector may not break away but remain connected. These are unacceptable results. It would, therefore, be beneficial to have a breakaway connector in which the fixed connector was flexible and able to bend when a off-axis force is applied, thereby allowing the off-axis force to more easily be translated to an axial force to prevent damage to the connector and allow the connector to be properly disengaged when an appropriate off-axis or axial force is applied.
An exemplary embodiment is directed to a connector which has a flexible portion which allows the connector to bend in response to non-axial forces applied thereto. When off-axis forces are applied to the connector or a mating connector, the off-axis forces do not cause oblique loading on the connector or mating connector.
An exemplary embodiment is directed to a breakaway connector for mating with a mating connector. The breakaway connector has a first end and a second end, with the second end configured to mate with the mating connector. A flexible portion is positioned between the first end and the second end. The flexible portion allows the second end to move relative to the first end. The second end is moveable to allow the mating connector to be properly disengaged from the second end even if off-axis forces are applied to the mating connector.
An exemplary embodiment is directed to a connector for mating with a mating connector. The connector has a flexible portion provided between a first end and a second end of the connector. The flexible portion allows the second end to move relative to the first end. The mating connector can be mated or unmated to the second end at an angle relative to the longitudinal axis of the unflexed connector without damaging the connector or the mating connector.
Other features and advantages of the present invention will be apparent from the following more detailed description of the preferred embodiment, taken in conjunction with the accompanying drawings which illustrate, by way of example, the principles of the invention.
Wherever possible, the same reference numbers will be used throughout the drawings to represent the same parts.
The present invention provides a connector system that automatically disengages at a predetermined breakaway force, whether such force is applied in line with the axis of the connector (axially) or not in line with the axis (off-axis), to prevent damage to the connector system, to equipment attached to the connector system and/or personal injury. The present invention also provides a connector system that is easy to connect and disconnect in harsh or challenging environments, thereby preventing damage to the connector system and equipment attached thereto and allowing the user to quickly enter or leave any area without concern for damaging the equipment, thereby providing maximum flexibility and safety to the user/operator. The invention will be described below relative to illustrative embodiments. Those skilled in the art will appreciate that the present invention may be implemented in a number of different applications and embodiments and is not specifically limited in its application to the particular embodiments depicted herein.
An example of a breakaway connector according to the present invention is a male-female connector. A male-female connector is expressly meant to refer to any connector that relies on axial insertion of a male part into a female part to establish a connector, including, without limitation, male-female pin connectors, male-female plugs and receptacles, and male-female flat connectors and receptacles. The characteristic feature of a male-female connector of this type is that the respective male and female parts of the connector are engageable by pressing the respective parts together axially and are disengageable by pulling on the respective parts, relative to each other. This feature will be discussed further herein below.
In general, the flexible connector and the connector assembly are positioned at respective ends of cables or other components which contain any known electrical or fiber optic conductors, including, for example and without limitation, one or more conductors for carrying power, unidirectional signal traffic, and/or bidirectional signal traffic.
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Referring to
The retaining ring 44 is preferably in the form of a ring that can expand in diameter, which extends by more than 180 degrees about the axis of the receptacle connector 22. The dimensions and configuration of the retaining ring 44 allow the retaining ring to expand within the recess 40. As the retaining ring 44, projections 43, and shoulders 80 are of the type well known in the industry, a more detailed explanation can be found in U.S. Pat. No. 5,427,542 which is hereby incorporated by reference in its entirety.
If a sufficient rearward force is applied to the mating connector 14 or the cable attached thereto, the shoulders 80 press the retaining ring 44. This causes the retaining ring 44 to “ride” up the ramp formed by movement of the shoulders 80 over the projections 43. The retaining ring expands in diameter to allow for the removal of the mating connector 14 from the flexible connector 10 when sufficient force is applied. After the mating connector 14 has been pulled completely out of the flexible connector 10, the retaining ring 44 remains in the recess 40. The same mating connector 14 or similar mating connector can be reinstalled in the field, by merely pressing the mating connector 14 in the forward direction until the shoulders 80 move past the projections 43, causing the free end of the cover 76 to engage and expand the retaining ring 44, thereby retaining the mating connector 14 in the flexible connector until such time as a sufficient force is again applied.
The force required to expand the retaining ring 44 depends upon the construction of the retaining ring 44, and on the angles of the projections 43 and shoulders 80. The more gradual the angles and the more resilient the retaining ring 44, the less axial force required to pull out the mating connector 14 from the flexible connector 10.
While the illustrative breakaway connector assembly 12 is shown using a retaining ring, projections and shoulders, many other types of breakaway retaining systems are known and can be used without departing from the scope of the invention. It is emphasized that the in-line receptacle connector 22 and the mating connector 14 shown and described herein are strictly examples in accordance with the present invention, and that other known connectors may be used instead of those shown.
In general, breakaway connector assemblies known in the prior art disengage appropriately when an axial removal force is applied to the connector or the cable. This allows the connectors and terminals to be disengaged in the axial direction. In so doing, the connectors and terminals are not damaged, as the disengagement occurs in a precise and controlled manner. However, in the field, it is uncommon for a disengagement force to be applied directly in line with the axis. It is typical for forces to be applied with an axial component and a transverse component. This can cause the connectors to fail, particularly in applications in which one of the connectors is fixed to a panel. In the prior art, if the transverse component is large, the mating connector is pulled from the fixed connector at an angle, which can cause damage to the retention members, the contacts and the connector in general. This results in the need to repair or replace the connectors or the components.
In addition, with the fixed connector of the prior art, when the mating connector or cable is pulled at an angle relative to the axial direction of engagement between the fixed connector and the mating connector, off-axis force causes oblique loading on the fixed connector, which increases the force needed to disconnect the mating connector from the fixed connector. If the angle of the applied force is more than a few degrees, it may be effectively impossible to disconnect the mating connector because of the oblique loading. The mating connector therefore binds, and the axial force required to separate the mating connector from the fixed connector can become higher than the designed axial force needed to disconnect the connectors, which may result in damage to the connector components or panel. As the fixed connector cannot properly accommodate these off-axis forces, the breakaway connector becomes essentially inoperable under these conditions.
The flexible connector 10 disclosed herein minimizes the possibility of failure, prevents the binding of the connectors, and allows for the proper disengagement and engagement of the mating connector 14 to the flexible connector 10 even if the force applied to the mating connector 14 or the cable attached thereto has large transverse components relative to the longitudinal axis of the flexible connector 10 is an unflexed position.
Referring to
Referring to
As shown, the flexible section 24 allows the receptacle connector 22 to move and rotate about fixed feed-through member 20. Consequently, as a typical force is applied to the mating connector or the cable, with an axial component and a transverse component, the flexible section 24 is bent in the direction of the transverse component, thereby allowing the force to align with the adjusted axis of the receptacle connector 22 and mating connector 14. This allows the mating connector to be pulled from the receptacle connector 22 in line with the adjusted axis, thereby preventing the mating connector from being pulled from the receptacle connector 22 at an angle, and thereby preventing damage to the retention members, the contacts and the connector in general. This facilitates the use of the breakaway connector assembly 12 over many cycles.
In addition, when the mating connector 14 or cable is pulled at an angle relative to the axial direction of engagement between the flexible connector 10 and the mating connector 14, the off-axis force does not cause oblique loading on the flexible connector 10 or the mating connector 14, as the flexible connector 10 bends to essentially convert the off-axis forces into axial forces in the repositioned end of the flexible connector 10. Therefore, the force needed to disconnect the mating connector 14 from the flexible connector 10 is maintained no matter how the mating connector 14 or the cable is pulled. This prevents the mating connector 14 from binding with the flexible connector 10, and prevents any increase in the axial force required to separate the mating connector 14 from the flexible connector 10, thereby minimizing damage to the connector components or panel and facilitating the use of the breakaway connector assembly 12 over many cycles.
Similarly, when the flexible connector 10 or cable is pulled at an angle relative to the axial direction of engagement between the flexible connector 10 and the mating connector 14, the off-axis force does not cause oblique loading on the flexible connector 10 or the mating connector 14, as the flexible connector 10 bends to essentially convert the off-axis forces into axial forces in the repositioned end of the flexible connector 10. Therefore, the force needed to disconnect the flexible connector 10 from the mating connector 14 is maintained no matter how the flexible connector 10 or the cable is pulled. This prevents the flexible connector 10 from binding with the mating connector 14, and prevents any increase in the axial force required to separate the flexible connector 10 from the mating connector 14, thereby minimizing damage to the connector components or panel and facilitating the use of the breakaway connector assembly 12 over many cycles.
The use of the flexible section 24 also allows for the connection between the mating connector 12 and flexible connector 10 to be easily accomplished in all environments. As the receptacle connector 22 can be moved, a user attempting to mate the mating connector 14 thereto need not align the mating connector in a precise orientation to the flexible connector 10. This allows for the connection between connectors 10, 14 to be accomplished quickly and effectively, even in environments which are not user friendly, such as in military or industrial applications.
Due to the flexibility provided in the flexible connector 10, damage to the connectors and components is minimized, allowing for precise repeatability over many cycles. Therefore, the flexible connector 10 can be used over many cycles with little or no risk of failure.
The present invention has been described relative to the exemplary embodiments. Since it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention, it is intended that all matter contained in the above description or shown in the accompanying drawings be interpreted as illustrative and not in a limiting sense. It should be understood that the present disclosure is for the purpose of illustration only, and that the invention includes all modifications and equivalents falling within the appended claims.
It is also to be understood that the following claims are to cover all generic and specific features of the invention described herein, and all statements of the scope of the invention which, as a matter of language, might be said to fall therebetween. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this invention, but that the invention will include all embodiments falling within the scope of the appended claims.
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| Number | Date | Country | |
|---|---|---|---|
| 20120045924 A1 | Feb 2012 | US |
| Number | Date | Country | |
|---|---|---|---|
| 61374483 | Aug 2010 | US |
