As used herein, a fuse is an electrical safety device essentially comprising a strip of metal or wire, which melts and thus breaks an electric circuit when the amount of current passing through the wire causes the wire's temperature to increase to a temperature at which the wire melts. When the wire melts, it effectively disconnects a power source from a load. The wire's characteristics are thus selected to melt and break before the current flowing through the fuse wire exceeds a safe level for circuitry or other electrical devices “downstream” of the fuse.
Most prior art fuses are designed to fit into fuse receptacles that are arranged to be horizontal. A problem with mounting a fuse horizontally on a circuit board is that it takes up valuable circuit board space. The area or space required to accommodate a fuse on a densely packed printed circuit board often necessitates omitting the fuse device altogether or, locating it somewhere else, i.e., remotely, and connecting the circuit board to the remote fuse using a wiring harness. A fuse and connector that requires less area would be an improvement over the prior art.
Referring now to
First and second terminal plates 110 and 112, which also resemble parallelepipeds but with tapered ends 113, extend away from the housing 104 in opposite directions (vertically, in
A “fork” is generally known as an implement with two or more substantially parallel prongs that extend from a handle. In
The connection fork 114 is stamped from thin sheet metal and is generally planar. When a terminal plate 112 is inserted between the tines, the tines 116, 118 are urged away from each other by the terminal plate 112.
Those of ordinary skill in the mechanical arts know that the term, “fit” is the general term used to signify or describe the range of tightness that may result from the application of a specific combination of allowances and tolerances in the design of mating parts. An interference fit, which is also known as a press fit or friction fit, is a fastening between two parts achieved by friction after the parts are pushed or forced together, rather than by any other means of fastening.
In
Inasmuch as the tines are formed from a planar or substantially planar metal, they expand and contract in what is essentially a geometric plane. That plane, and the tines' expansion and contraction is in a direction substantially orthogonal to the surfaces of the terminal plates.
The hole 124 in the circuit board 126 is sized and shaped to receive the handle portion 120 of the connection fork and to also provide an interference between them. In a preferred embodiment, the handle portion 120 is also soldered to a conductive trace on the circuit board or inside the connection hole 124 providing an improved electrical and mechanical connection there between. The interference fit between the hole 124 and handle portion 120 holds the connection fork 114 substantially upright or vertical, relative to the circuit board such that the tines 116 and 118 are held vertical and orthogonal to the surface of the printed circuit board.
As mentioned above, the tines 116, 118 have a first end 129 proximate or near to the handle 120. They also have a second or distal end 130 situated as far away from the handle 120 as possible. The distal end 130 is considered herein as including the aforementioned protuberances 128.
As used herein, a detent is considered to be a device for positioning and holding one mechanical part in relation to another in a manner such that the devices can be released from each other by force applied to one of the parts. In one alternate embodiment, the terminal plates 112 are provided with either a hole or an indentation 132 sized and shaped to receive at least part of the protuberances 128 and thus provide a detent. The detent will of course help retain the terminal plate in the connection fork and will help maintain its vertical alignment as shown in
The embodiment 200 shown in
As best seen in
Referring now to both
Those of ordinary skill in the art will recognize that the barbs 216 of the clamping arms 214 can instead be configured to engage a block of material attached directly to the top surface of the main housing 204.
Those of ordinary skill in the art should recognize that the in-line blade fuse system described above and depicted in the figures provides a mechanically and electrically reliable and repeatable interconnection using a compliant fuse fork. It also significantly reduces the surface area required on a printed circuit board below what is required of a prior art fuse. Multiple in-line blade fuse devices can be placed within the same footprint of a prior art horizontally-oriented fuse.
In addition to a reduced footprint or surface area use, the vertical blade fuse system allows air to circulate around fuses 105 and thus increases heat dissipation from them. The systems depicted above are far less expensive than a prior art fuse holder and mechanically and electrically more reliable.
The foregoing description is for purposes of illustration only. The true scope of the invention is set forth in the following claims.