This disclosure relates generally to electrical connectors and, more particularly, to electrical terminals and methods of manufacturing the same.
Electrical terminal blocks or just terminals are electrical connectors that facilitate the connecting of individual electrical wires to other wires and/or external circuits. Terminals are used widely in many industries because of their versatility in connecting various sizes, types (e.g., solid-core vs. stranded wire), and/or number of wires. There are many different terminal designs that may be used to securely hold and establish an electrical connection to a wire. For example, some terminals may accept wires prepared with ring or spade terminal lugs on their ends. Other terminals may secure the stripped end of a wire with a metal clamp that is manually actuated by a screw. Yet other terminals may clamp a wire in place via a spring force that may be actuated manually or automatically.
There are also differing methods to connect one terminal to another and/or to external circuits. For example, multiple terminals may be mounted to a common base (e.g., a DIN rail) to secure the terminals relative to one another and then connected with various connecting pieces (e.g., bridge bars) designed to engage and connect individual terminals. Other terminals are designed to mount directly to a printed circuit board via pins soldered directly into the printed circuit board to establish the desired electrical connection(s).
Electrical terminals and methods of manufacturing the same are disclosed. An example terminal comprises a housing and a wire clamp positioned within the housing to secure a wire in electrical contact with a connector pin, the connector pin extending out a bottom surface of the housing to be electrically connected to a printed circuit board, the housing is to have one or more feet to separate the bottom surface of the housing from the printed circuit board.
Another example terminal comprises a body having an opening to receive an end of a wire, a wire holder within the body to secure the end of the wire, a connector pin extending out a bottom surface of the body to be electrically connected to a circuit board, where the wire holder is to secure the end of the wire in electrical connection with the connector pin, the body comprises a spacer extending out the bottom surface of the body adjacent the connector pin to provide a space between the bottom surface of the body and the circuit board.
Another example terminal comprises a housing having an opening to receive an end of a wire, a first connector pin extending out from a bottom surface of the housing via a hole in the bottom surface of the housing, the connector pin to connect to a circuit board via a solder joint, a first clamp enclosed by the housing to secure the end of the wire in electrical contact with the first connector pin, and a riser extending from the bottom surface of the housing to raise the bottom surface of the housing away from the circuit board to enable access beneath the housing around the solder joint.
A terminal may be constructed to enable the connection of one or more wires. For example, as shown in the illustrated examples, the terminal 100 has two wire entry points, apertures, or openings 104, 106, corresponding to two separate wire termination points 108, 110 for two separate wires. Each wire position 108, 110 may contain a corresponding internal mechanism to receive a bare end of a wire and secure it to be electrically connected to other components connected with the terminal 100. In particular, the illustrated examples in
Unlike many known cage clamp terminal bodies or housings, which are formed from a single piece of material (i.e., are unitary) and which have an opening in the bottom to insert the internal mechanisms, the housing 102 of the example terminal 100 is made of a base or bottom portion 126 and a separate cap or top portion 128. The base portion 126 includes holes 130, 132 in the bottom surface 124 through which the pins 116, 118 may be inserted. Other than the holes 130, 132, the base portion 126 is closed off on the bottom surface 124. In some examples, each hole 130, 132 is substantially fitted (e.g., sized for a press-fit) to the respective connector pin 116, 118 to reduce the possibility of external materials entering the housing 102 via the bottom of the housing 102 and causing an electrical leakage path.
After the internal mechanisms (e.g., the cages 112, 114) are inserted into the base portion 126 with the connector pins 116, 118 extending out through the holes 130, 132, the top portion 128 is placed on the base portion 126 over the internal mechanisms. In the illustrated examples, the base and top portions 126, 128 are shaped to securely mate with each other along a seam 134, thereby completely enclosing the internal mechanisms of the example terminal 100. In some examples, the base and top portions 126, 128 may be sealingly mated along the seam 134 via ultrasonic welding to bond the base and top portions 126, 128 and achieve a tight seal around the internal mechanisms of the terminal 100. In this manner, the potential for contaminants from an external environment ingressing, via the interfacing surfaces of the base and top portions 126, 128, and disrupting the electrical connections established via the terminal 100 is reduced. Additionally or alternatively, a tight seal may be accomplished via an over-molding process, in which a separate piece is attached with an adhesive and/or a sealant and/or via any other suitable method.
In addition to a sealing joint along the seam 134 around the exterior of the housing 102, in some examples, the mated base and top portions 126, 128 form an internal wall that extends between the wire termination points 108, 110. In this way, the internal mechanisms (e.g., the cages 112, 114) of the example terminal 100 may not only be substantially isolated from an outside environment (and any associated contaminants) surrounding the bottom and/or sides of the housing 102, but each internal mechanism may also be isolated from the other internal mechanisms. The separation of the internal mechanisms serves to reduce (e.g., prevent) the potential for corrosion and/or an electrical leakage path from developing between the two wire termination points 108, 110 from trapped moisture and/or contaminants resulting in an undesirable and/or unexpected electrical connection. As described above, the bonding of the base and top portions 126, 128 to form the internal wall may be accomplished via ultrasonic welding, an adhesive, and/or any other suitable method.
Furthermore, in some examples, the terminal 100 may include one or more feet, risers, or spacers 136 extending from the bottom surface 124 of the housing 102 to raise the terminal 100 and provide a space or gap 138 between the bottom surface 124 of the terminal 100 and a printed circuit board (not shown) to which the connector pins 116, 118 may be soldered. In such examples, the gap 138 enables access to the solder joints to encapsulate the printed circuit board including the solder joints to achieve environmental exclusion. Additionally, such an encapsulation process may be performed without concern for the encapsulant entering the housing 102 of the terminal 100 and potentially affecting the internal mechanisms because the bottom surface 124 of the housing 102 is closed except for where the connector pins 116, 118 extend through the holes 130, 132 of the bottom surface 124. Furthermore, the holes 130, 132 may be sized to provide a tight fit (e.g., a press-fit, an interference fit, etc.) around the connector pins 116, 118 to reduce the possibility of encapsulant (or other contaminants) around the bottom of the housing 102 from entering the terminal 100, especially where the encapsulant has a high viscosity. In addition, an over-molding process would achieve an even tighter seal between the connector pins 116, 118 and the holes 130, 132.
Additionally or alternatively, the gap 138 created by the feet 136, in the illustrated example, also enables access to the solder joints for more effective cleaning, thereby reducing the chance of accumulation of contaminants and/or corrosion. As a result, the example terminal 100 may last significantly longer without replacement and/or provide substantially increased reliability and/or may be used in less benign environments (e.g., corrosive atmospheres and/or high temperature and humid environments) than many known terminal blocks. Additionally, even when cleaning is not frequently performed, the feet 136 of the illustrated example may also serve as a wall to at least partially isolate the adjacent connector pins 116, 118 from each other, thereby reducing the possibility of an electrical leakage path developing between the pins 116, 118 from moisture and/or contamination build up. Similarly, the example feet 136 may also serve as a wall to separate the connector pins 116, 118 from other adjacent circuitry (e.g., circuitry on a printed circuit board).
While the feet 136 are shown in the illustrated examples of
In addition to the number of wire termination points 108, 110, 202, 204, 206, a terminal constructed in accordance with the teachings disclosed herein may vary in other respects as well. For example, the angle of the screws 120, 122 and wire entry points 104, 106 can be varied relative to one another and/or relative to the surface of the printed circuit board. The dimensions and/or size of the terminals and corresponding components may be appropriately varied. Furthermore, as previously stated, the feet 136 as well as the two-part body 102 to enclose the internal mechanisms of a terminal may be incorporated into different types of terminals other than cage clamp terminals.
The example process of
The example process of
With the base and top portions thus formed, the example process then joins the base and top portion to enclose the internal mechanisms (block 404). Additionally, the example process involves sealing the mating surface of the top portion and the base portion (block 406). In some examples, the sealing process may include ultrasonic welding. In such examples, when the base portion and/or the top portion are formed (blocks 400, 402), the mating surfaces may include one or more weld lines defined by an excess portion of plastic to be melted and provide a tight seal between the top and base portions. Such an example may apply to the exterior perimeter of the terminal or to an internal wall when there is more than one wire termination point. The seal along the perimeter of the terminal helps to reduce the chance for contaminants, moisture, or encapsulant from the outside environment from entering the housing through the interface between the base and top portions while the seal along an internal wall serves to reduce the possibility of corrosion and/or an electrical leakage path from developing between adjacent internal mechanisms. Additionally or alternatively, the base portion and the top portion may be sealed (block 406) via any other suitable process such as an over-molding process, an adhesive, a sealant, etc. Once the base portion and the top portion have been sealingly mated, the example process of
Although certain example methods, apparatus and articles of manufacture have been described herein, the scope of coverage of this patent is not limited thereto. Such examples are intended to be non-limiting illustrative examples. On the contrary, this patent covers all methods, apparatus and articles of manufacture fairly falling within the scope of the appended claims either literally or under the doctrine of equivalents.
The Abstract included herewith is provided to comply with 37 C.F.R. ยง1.72(b) to allow the reader to quickly ascertain the nature of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.
This patent claims the benefit of provisional application Ser. No. 61/544,084, which was filed on Oct. 6, 2011, and which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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61544084 | Oct 2011 | US |