Embodiments of the present disclosure relate to fuse assemblies, and, more particularly, to fuse assemblies having two-piece endbells.
Used in electrical systems to protect against excessive current, fuses are sacrificial devices which break when an overcurrent condition occurs. Fuses include a fuse element, such as a metal wire or strip, that links two metal contact terminals together, and which melts/breaks if too much current flows. The breakage causes an open circuit, thus protecting devices to which the fuse is connected. Fuses come in a variety of shapes and sizes and have many applications, from small circuit electronics to large-scale industrial applications. In addition to being a component protection device, fuses are also safety devices, such as when used in vehicles, as they protect against fires in response to vehicle accidents.
Some fuses may include endbells at either side of the fuse body, with a fuse element disposed in the fuse body. The endbells are designed to support and protect the fuse element from external forces and environmental stresses. The existing fuse technology utilizes two fully circular endbells, each of which is engaged such as by first press-fitting or brazing into its respective separate terminal before the fuse element is attached. This assembly method thus involves a secondary process, such as soldering or welding, to attach the fuse element between the two terminals, increasing the complexity of manufacture and risking quality deviation. Further, the sliding interface between conductive terminal and endbell during assembly is not designed to produce a sealed envelope between fuse contents and the environment.
The endbells are secured to the fuse body using insertion pins. Drilling holes in the endbells, which are typically made of a softer metal than the metal used for the fuse terminal, can be messy, resulting in contaminants being left inside the fuse body. Tight sealing of the endbells to the fuse body ensures that the fuse assembly operates as designed. Thus, the endbells may be sealed to the fuse body using adhesive materials, which can also be messy.
It is with respect to these and other considerations that the present improvements may be useful.
This Summary is provided to introduce a selection of concepts in a simplified form that are further described below in the Detailed Description. This Summary is not intended to identify key or essential features of the claimed subject matter, nor is it intended as an aid in determining the scope of the claimed subject matter.
An exemplary embodiment of a fuse assembly in accordance with the present disclosure may include a fuse body, a terminal assembly, and an endbell. The terminal assembly is within the fuse body and has first and second opposing surfaces with a fuse element extending between a first terminal and a second terminal. The endbell, to be connected to the fuse body, includes first and second endbell portions. Formed within the first endbell portion is a first receptacle and extending from the first endbell portion is a first protrusion. Formed within the second endbell portion is a second receptacle and extending from the second endbell portion is a second protrusion. When the two endbell portions are fastened to one another with the terminal assembly sandwiched between them, the first protrusion engages the second receptacle and the second protrusion engages the first receptacle.
An exemplary embodiment of an endbell in accordance with the present disclosure is adapted to secure a terminal assembly inside a fuse housing and may include a first endbell portion and a second endbell portion. The first endbell portion has a first crush rib. The first crush rib is adapted to engage with a first surface of a terminal assembly. The second endbell portion has a second crush rib. The second crush is adapted to engage with a second surface of the terminal assembly opposite a first surface.
Another exemplary embodiment of a fuse assembly in accordance with the present disclosure may include a fuse body, an endbell portion, and an insertion pin. The fuse body is molded with first and second holes. The endbell portion is molded with a slot formed radially into its circumferential edge, forming a radial cavity through the endbell. The insertion pin extends through the first hole and the slot.
Novel fuse assembly designs are disclosed herein. Two-piece endbell designs enable the terminals and fuse element of the fuse assembly to be formed as a single piece, eliminating the manufacturing variability caused by having to separately attach the fuse element between the two terminals. The two-piece endbells as well as the terminal assembly feature elements that enable engagement of the endbell portions to the terminal assembly without use of adhesives. The elements also provide positioning guidance for ease of assembly. The endbell portions feature slots rather than cylindrical holes for receipt of insertion pins used to secure the endbells to the fuse body, thus avoiding costly rework of molding tools.
For the sake of convenience and clarity, terms such as “top”, “bottom”, “upper”, “lower”, “vertical”, “horizontal”, “lateral”, “transverse”, “radial”, “inner”, “outer”, “left”, and “right” may be used herein to describe the relative placement and orientation of the features and components of the fuse assemblies, each with respect to the geometry and orientation of the assemblies as they appear in the perspective, exploded perspective, and cross-sectional views provided herein. Said terminology is not intended to be limiting and includes the words specifically mentioned, derivatives therein, and words of similar import.
Fuse Assembly 100
The terminal assembly 200A (
The fuse terminal 204 optionally includes terminal apertures 206a and 206b (collectively, “terminal apertures 206”) for fixably attaching the fuse to an electrical circuit. Though they are shown as circular openings, the terminal apertures 206 may be any of a variety of shapes and sizes. As one example, the fuse terminal 204 may be attached to a busbar by inserting electrically conductive bolts through the terminal apertures 206, thus forming an electrical connection between the fuse and the busbar.
In an exemplary embodiment, the terminals 204 and the fuse element are formed as a unitary metallic, conductive material, such as zinc, copper, silver, aluminum, or alloys or combinations thereof, though the terminal assembly 200 shown and described herein is not limited to such a configuration. In other embodiments, the terminal assembly 200 of the fuse assembly 100 is formed by connecting the terminals 204 to either side of the fuse element 208, such as by soldering, welding, or other means.
In an exemplary embodiment, the terminal assembly 200 features protruding lips formed proximate to each terminal. A first lip 212a and a second lip 212b are located on opposing sides of the terminal assembly 200 close to the first terminal 204a; similarly, a third lip 212c and a fourth lip 212d are located on opposing sides of the terminal assembly 200, close to the second terminal 204b (collectively, “lips 212”). As illustrated in
Endbells 202a and 202b are shown in
In legacy fuse designs, the endbells are a single-piece design having a rectangular slot in each endbell. The fuse element is slid through the slots of each endbell, followed by the attachment of the terminals to each end of the fuse element, such as by soldering, welding, and the like. In exemplary embodiments, the two-piece endbell design of the fuse assembly 100 enables the terminals and fuse element to be formed as a single piece, eliminating the manufacturing variability caused by having to separately attach the fuse element between the two terminals.
In exemplary embodiments, the endbells 202 further include insertion pins (
Each endbell portion 210 includes a first diagonal surface 316, a second diagonal surface 318, a center (horizontal) surface 320, a semi-circular surface 322, and two flat side surfaces 324a and 324b (collectively, “side surfaces 324”). With the exception of the semi-circular surface 322, the other surfaces are substantially flat. The center surface 320 is formed on either side of the first and second diagonal surfaces 316, 318.
Each surface of the endbell portion 210 includes a feature. The side surfaces 324 show an endbell aperture 332, which is a transverse cylindrical void visible on either side of the endbell portion 210. The endbell aperture 332 is used to fill the fuse assembly 100 with sand or other material once the two endbells are connected to the fuse body, after which the aperture is sealed with plugs 338 on both sides (
Further, in exemplary embodiments, the first diagonal surface 316 features a receptacle 330 and the second diagonal surface 318 features a protrusion 328. The receptacle 330 of one endbell portion 210 is designed to mate with the protrusion 328 of a second endbell portion. In exemplary embodiments, when the mating occurs, the diagonal surface 316 of one endbell portion 210 will be flush against the diagonal surface 318 of the other endbell portion.
The receptacle 330 includes a flat surface, known herein as a lip seat 334, that extends from the center portion 320, and a block receiver 340 orthogonal to the lip seat. Likewise, the protrusion 328 has a flat surface, a lip seat 336, that extends from the center portion, and a block 342 orthogonal to the lip seat. In exemplary embodiments, two lips of the terminal assembly 200 mate with the endbell portion 210 so that one lip is disposed on the lip seat 334 of the receptacle 330, while the second lip is disposed on the lip seat 336 of the protrusion 328 (see
In exemplary embodiments, the center surface 320 features a crush rib 326 extending between (intermediate) the first diagonal surface 316 and the second diagonal surface 318. In one embodiment, the crush rib 326 is disposed, not in the center of the center surface 320, but to one side, closer to the side surface 324b than to the side surface 324a. The crush rib 326 is also placed so as to avoid the lip seats 334, 336, though the placement of the crush rib 326 may vary from what is illustrated. In an exemplary embodiment, when two endbell portions 210 are engaged with each other, the crush rib 326 of the upper endbell portion (e.g., endbell portion 210b,
In exemplary embodiments, when the two endbell portions 210 are engaged with and radially secured to one another, the crush ribs 326 mate with the terminal assembly 200 and deform. A first crush rib 326a for endbell portion 210a and a second crush rib 326b for endbell portion 210b is shown. The terminal assembly 200, which may be made from copper or copper alloy, is pressed firmly against the zinc or zinc alloy material of the endbell portions 210, such that some compression and possibly deformation of the two materials occurs. In an exemplary embodiment, the pressure of connecting the crush ribs 326 against the terminal assembly 200 produces a sealed envelope between the contents of the fuse assembly 100 and the external environment.
Although a single crush rib 326 (per endbell portion 210) is shown, there may be multiple crush ribs 326 on each endbell portion. Further, these features may be presented in different locations on the respective endbell portions 210 without limitation.
In an exemplary embodiment, the endbell portions 210 are pressed around the terminal assembly 200 during manufacture, resulting in a concentric circular endbell on each end of the fuse (
In exemplary embodiments, once mated, the two endbell portions 210 become fixably attached without using an adhesive or sealant. This eliminates the need for endbell/terminal surface regularity. The crush ribs 326 in the endbell portions 210 bite into the terminal assembly 200, deforming material in both the endbell portions and the terminal assembly. Thus, if the surface of either the endbell portion 210 or the terminal assembly 200 is not perfectly flat, the deformed-fit interface can still make a firm seal between the two materials. In an exemplary embodiment, the intentional interference of the crush ribs 326 with terminal assembly 200 provides mechanical support and a fixed connection between endbell portions 210 and the terminal assembly 200. Further, in an exemplary embodiment, the pressure of connecting the crush ribs 326 with the terminal assembly 200 produces a sealed envelope between the fuse contents and the external environment. The mating elements of the novel fuse assembly 100 thus provide both secure affixation of the endbells to the fuse body and provide positioning guidance during assembly for ease of manufacturing the fuse assembly.
Fuse Assembly 500
The terminal assembly 600A (
In an exemplary embodiment, the terminal assembly 600 features recesses disposed proximate to each terminal. A recess 612a and a recess 612b are located on opposing sides of the terminal assembly 600 close to the first terminal 604a; similarly, a recess 612c and a recess 612d are located on opposing sides of the terminal assembly 600, close to the second terminal 604b (collectively, “recesses 612”). As illustrated in
Endbells 602a and 602b are shown in
Although
In exemplary embodiments, the endbells 602 further include insertion pins (
Each endbell portion 610 includes a feature surface 720, including a raised portion 718, a semi-circular surface 722 at a circumferential edge of the endbell portion, and two flat side surfaces 724a and 724b (collectively, “side surfaces 724”). Side surface 724a shows an endbell aperture 732, which is a transverse cylindrical void visible on either side of the endbell portion 610. The endbell aperture 732 is used to fill the fuse assembly 500 with sand or other material once the two endbells are connected to the fuse body, after which the aperture is sealed with plugs on both sides (
In exemplary embodiments, the feature surface 720 includes a protrusion 728 while the raised portion 718 of the feature surface 720 includes a receptacle 730. The receptacle 730 of one endbell portion 610 is designed to receive the protrusion 728 of a second endbell portion, thereby mating the two endbell portions. In exemplary embodiments, when the mating occurs, the raised portion 718 is raised up, relative to the feature surface 720, thus allowing room for the terminal assembly 600 to be disposed between the two endbell portions 610.
First introduced in
In exemplary embodiments, the feature surface 720 further features two crush ribs 726a and 726b disposed at the edges of the feature surface (collectively, “crush ribs 726”). In an exemplary embodiment, when two endbell portions 610 are engaged with one another, the crush rib 726a of the first endbell portion (e.g., endbell portion 610b,
In exemplary embodiments, the protrusion 728 of the endbell portion 610 further includes one or more ribs. Ribs 736a and 736b are visible in
In exemplary embodiments, as illustrated in the cross-sectional view of
In an exemplary embodiment, the endbell portions 610 are pressed around the terminal assembly 600 during manufacture, resulting in a concentric circular endbell on each end of the fuse (
In exemplary embodiments, once mated, the two endbell portions 610 become fixably attached without using an adhesive or sealant. This eliminates the need for endbell/terminal surface regularity. The crush ribs 726 in the endbell portions 610 bite into the terminal assembly 600, deforming material in both the endbell portions and the terminal assembly. Thus, if the surface of either the endbell portion 610 or the terminal assembly 600 is not perfectly flat, the engagement interface can still make a firm seal between the two materials. In an exemplary embodiment, the intentional interference of the crush ribs 726 with the surfaces of the terminal assembly 600 provides mechanical support and a fixed connection between endbell portions 610 and the terminal assembly. Further, in an exemplary embodiment, the pressure of connecting the crush ribs 726 the terminal assembly surfaces produces a sealed envelope between the fuse contents and the external environment.
As with the endbell 610 (
Further, in exemplary embodiments, the endbell 810 features troughs which are adjacent to the crush ribs 826. Trough 844a is adjacent to crush rib 826a while trough 844b is adjacent to crush rib 826b (collectively, “troughs 844”). In the cross-sectional view of
The endbell portions 910 feature both a protrusion 928 and a receptacle 930. The protrusion 928 of one endbell portion 910 is designed to fit into the receptacle of a second endbell portion. The terminal assembly 902 features a recess 912a and a recess 912b (collectively, “recesses 912”), which are disposed on opposing edges of the terminal assembly. The bottom endbell portion 910a shows a projection 916, and the endbell portion 910b, which is substantially similar to endbell portion 910a, also includes a projection. These projections 916 are designed to mate with respective recesses 912 of the terminal assembly 902, in exemplary embodiments. When the two endbell portions 910 are engaged with one another, the projection 916 of the endbell portion 910a will fit into the recess 912a, with the recess (not shown) of the endbell portion 912b fitting into the recess 912b.
In exemplary embodiments, the endbell portion 910a further includes a pair of crush ribs 926a and 926b (collectively, “crush ribs 926”). On either side of each crush rib 926 are troughs. Thus, crush rib 926a is disposed on either side of trough 944a and 944b, while crush rib 926b is disposed on either side of trough 944c and 944d (collectively, “troughs 944”). When the endbell portions 910 are engaged with one another, sometimes the crush ribs 926 are substantially compressed and/or deformed, such that the excess material of the compression/deformation is able to fit into the troughs 944, whether to one side of the crush rib, to a second side of the crush rib, or to both sides of the crush rib. Where the compression/deformation causes a smaller interference, there may be less excess material, rendering one or more of the troughs 944 unused.
In exemplary embodiments, the terminal assembly 902 includes mating grooves for coupling with the crush ribs 926 of the endbell portions 910. On a first surface of the terminal assembly 902, a first mating groove 942a is in one side of the recesses 912 and a second mating groove 942b is in another side of the recesses; on a second surface of the terminal assembly, a third mating groove 942c is in one side of the recesses and a second mating groove 942d is in another side of the recesses (collectively, “mating grooves 942”). In exemplary embodiments, the mating grooves 942 are spaced a distance, d, apart and the crush ribs 926 are also spaced a distance, d, apart. The mating grooves 942 of the terminal assembly 902 are thus receiving structures for mating with the crush ribs 926 of the endbell portions 910.
The terminal assembly 902, which may be made from copper or copper alloy, is pressed firmly against the zinc or zinc alloy material of the endbell portions 910, such that some compression and possibly deformation of the two materials occurs. In an exemplary embodiment, the pressure of connecting the crush ribs 926 against respective mating grooves 942 of the terminal assembly 910 produces a sealed envelope between the contents of the fuse assembly and the external environment. The crush ribs 926 and the mating grooves 942 facilitate melding of the respective components together, resulting in an air-tight coupling into the endbells without use of adhesive. The recesses 912 and projections 916 similarly help seal the endbell portions 910 against the terminal assembly 902.
In exemplary embodiments, the projection 916 of the endbell portions 910 and the recesses 912 of the terminal assembly 902 provide positioning guidance during manufacture of the fuse assembly 500. With the addition of mating grooves 942 in the terminal assembly 902, this positioning guidance is enhanced, in exemplary embodiments, as the crush ribs 926 of the endbell portions 910 are able to “find” the mating grooves of the terminal assembly 902 for ease of manufacturing the fuse assembly.
Insertion Pin Slots
The fuse assemblies described above feature insertion pins, which are used to secure the endbells to the fuse body. In legacy fuse assemblies, cylindrical holes are drilled into both the endbells and the fuse body. The holes retain the endbells axially within the cylindrical tube of the fuse body.
To retain the endbells at opposing ends of the fuse, holes are to be drilled radially to a specified depth through the fuse body and into the endbells. Metal pins are then inserted into the holes, rigidly retaining the endbells in place. Drilling into most fuse body materials is fast, efficient, and does not easily dull the drill bit. Drilling a blind hole into the endbell portion is risky because there is uncertainty about whether the drill hole is in the correct location. Further, drilling a blind hole into zinc is difficult, slow, and dulls the drill bit quickly and damages the drill bit with high regularity, which poses a problem for mass production. Because they are made from zinc or zinc alloy, drilling holes in the endbell portions 210, 610, or 910 is problematic, in some embodiments.
As an alternative to drilling, the endbell portions may be made using molding operations, such as injection molding. The core and cavity are the shaped sections in either half of the mold tool that give the endbell portion its final shape. The cylindrical holes used for the insertion pins can be molded in this way.
There may be drawbacks with using molding operations for the cylindrical holes, however.
The upward vertical arrow indicates tool cavity pull while the downward vertical arrow indicates tool core pull of the molding operation. The diagonal arrows indicate tooling slide for the holes 1104. Unfortunately, during the tooling of the holes 1104, an interrupted surface profile, given by parting lines 1106a and 1106b, adds risk for consistent assembly to the fuse body.
Adding diecast/molded holes (as opposed to slots) require additional slides to be added to the tool, which in turn create an inconsistent surface due to the additional parting-lines. As this is the mating surface between the endbell exterior and the body interior, a consistent surface for the endbell is preferred.
As an alternative, in exemplary embodiments, the endbells are formed in a molding operation with slots, rather than cylindrical holes. The slots are designed specifically to eliminate the need to add side actions in the molding tool and maintain a smooth uninterrupted endbell surface.
Parting lines 1114a and 1114b are shown in slot 1112a and parting lines 1114c and 1114d are shown in slot 1112b (collectively, “parting lines 1114”). In contrast to the parting lines 1106 in
Fuse Assembly 1200
The fuse body 1206 includes fuse body holes 1216a, 1216b, 1216c, and 1216d, shown in the cross-section of the endbell 1202, as well as fuse body hole 1216e, shown on the opposing side of the fuse body, for securing a second endbell (not shown) (collectively “fuse body holes 1216”).
In exemplary embodiments, diecast/molded slots of predetermined size and orientation are located on each endbell 1202, removing the need to drill. Alignment slots 1212a, 1212b, 1212c, and 1212d are pre-molded into the circumferential surface of the endbell 1202, such as is shown in
Visible in the alignment slot 1212b, a slot bottom 1218 is circular, in some embodiments, though shown as a semi-circle in the cross-sectional view.
Also featured in the fuse assembly 1200 are insertion pins 1214a, 1214b, and 1214d for securing the endbell 1202 as well as insertion pins 1214e, 1214f, and 1214g, for securing the second unshown endbell (collectively, “insertion pins 1214”). Not visible insertion pins 1214 are presumed to be insertable in the fuse body hole 1216c and slot 1212c for the endbell 1202 and for the not visible endbell. In one embodiment, the insertion pins 1214 are made of a metal or metal alloy material, such as stainless steel. In an exemplary embodiment, four insertion pins 1214 are used to secure each endbell, though the number of insertion pins may vary.
Together, the fuse body holes 1216 and the slots 1212 receive the insertion pins 1214 to secure the endbell 1202 and not visible endbell to the fuse body 1206. The pre-cast/pre-molded alignment slots 1212 significantly simplify the fuse manufacturing process by removing the need to drill into the fuse endbells without adding tooling complexity. Using slots 1212 in the endbells 1202 (rather than cylindrical holes) allow the endbell tooling to remain basic with simple core/cavity blocks, avoiding costly side-action features in the tooling. The use of slots thus minimally impacts tooling cost and piece part cycle time, in some embodiments. Further, having pre-cast/pre-molded endbell slots allow for the fuse body to be independently drilled prior to assembly.
Further, in exemplary embodiments, the presence of the pre-cast/pre-molded alignment slots 1212 eliminates the risk of metal particulate entering the functional region of the fuse due to endbell drilling. The endbell slot design of
As used herein, an element or step recited in the singular and proceeded with the word “a” or “an” should be understood as not excluding plural elements or steps, unless such exclusion is explicitly recited. Furthermore, references to “one embodiment” of the present disclosure are not intended to be interpreted as excluding the existence of additional embodiments that also incorporate the recited features.
While the present disclosure makes reference to certain embodiments, numerous modifications, alterations, and changes to the described embodiments are possible without departing from the sphere and scope of the present disclosure, as defined in the appended claims. Accordingly, it is intended that the present disclosure not be limited to the described embodiments, but that it has the full scope defined by the language of the following claims, and equivalents thereof.
This application is a continuation of, and claims the benefit of priority to, U.S. patent application Ser. No. 17/314,277, filed May 7, 2021, entitled “TWO-PIECE ENDBELL WITH PRE-CAST/PRE-MOLDED ALIGNMENT SLOTS AND OPTIONAL INTERFACE CRUSH RIBS,” which application is incorporated herein by reference in its entirety.
Number | Date | Country | |
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Parent | 17314277 | May 2021 | US |
Child | 17530038 | US |