Embodiments of the present disclosure relate to fuses and, more particularly, to elements of fuse housing.
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 flow. 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.
The fuse may also have a housing, such as a socket connected to terminals for holding the fuse element and a cap to cover the fuse element. When the fuse breaks, an arc energy is created between its terminals, causing the metal of the fuse element, as well as other materials, to melt and deposit within the fuse housing.
There may be instances in which the cap blows off due to the overcurrent event. Due to this housing defect, the fuse may receive a lower rating than as otherwise designed. The blown fuse event may also be quite noisy, especially where the cap blows off.
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 element, a first terminal, a second terminal, a socket, and a capsule. The fuse element is disposed between first and second end bells. The first terminal includes a first bell portion, a first socket portion, and a first capsule portion, the first bell portion being connected to the first end bell. The second terminal includes a second bell portion, a second socket portion, and a second capsule portion, the second bell portion being connected to the second end bell. The first socket portion and the second socket portion are integrated through the socket. The first capsule portion and the second capsule portion are integrated through the capsule. The socket is seated atop the capsule to create an interior chamber inside which the fuse element is disposed.
Another exemplary embodiment of a fuse assembly in accordance with the present disclosure may include a capsule, a socket, and first and second terminals. The capsule includes a first inside surface disposed between first and second capsule terminal regions. The first inside surface includes capsule wedges. The socket includes a second inside surface with socket wedges and is located on the capsule to form an interior chamber. The capsule wedges are on a first side of the interior chamber and the socket wedges are on a second side of the interior chamber, the first side being opposite the second side. The first and second terminals are connected between a fuse element, which is inside the interior chamber. Each terminal includes a first portion integrated with the capsule and a second portion integrated with the socket.
A novel fuse assembly is disclosed herein. The fuse assembly includes a fuse element in a chamber surrounded by a socket and a capsule. In contrast to legacy fuse assemblies, the capsule is located on the bottom of the fuse assembly, with the socket being on the top. The terminals are shaped so as to be integrated with both the socket and the capsule. The socket and the capsule have surfaces that are wedged for increased surface area in the chamber. The wedges provide surfaces to which outgassing debris can attach and provide noise mitigation during breakage of the fuse element. The socket also includes an exhaust port having multiple pathways for exit of outgassing debris and for noise mitigation.
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 disclosed herein, each with respect to the geometry and orientation of other features and components appearing 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.
The fuse assembly 100 includes a fuse element 102 within an interior chamber 120 and disposed between two end bells 104a and 104b (collectively, “end bells 104”). Each end bell 104 is connected to a respective terminal: end bell 104a is connected to terminal 106a and end bell 104b is connected to terminal 106b (collectively, “terminals 106”). Because the fuse assembly 100 is an SMT device, each terminal 106 include respective SMT portions: terminal 106a includes SMT portion 114a and terminal 106b includes SMT portion 114b (collectively, “SMT portions 114”). The SMT portions 114 are to be soldered to a PCB 122.
The fuse assembly 100 features housing for the fuse element 102 consisting of a socket 116 and a capsule 118. In exemplary embodiments and in contrast to legacy fuses, the socket 116 is at a location remote from the PCB 122 (e.g., at the top portion of the fuse assembly 100 in
The terminals 106 are shaped to fit with the housing elements, the socket 116 and the capsule 118. In exemplary embodiments, each terminal 106 includes four separate portions for fitting with the housing elements. Terminal 106a includes a bell connection portion 108a, a socket connection portion 110a, a capsule portion 112a, and the already introduced SMT portion 114a; likewise, terminal 106b includes a bell portion 108b, a socket portion 110b, a capsule portion 112b, and the SMT portion 114b (collectively, “bell portions 108”, “socket portions 110”, and “capsule portions 112”). In exemplary embodiments, the socket 116 and the capsule 118 are made of a non-conductive material, such as plastic.
The bell portions 108 of the terminals 106 connect between respective end bells 104 and one end of respective socket portions 110, with the other end of socket portions being connected to respective capsule portions 112 at one end, with the other end of capsule portions being connected to respective SMT portions 114. In exemplary embodiments, the socket portions 110 are bent inside the socket 116 while the end bell portions 108 are somewhat parallel to the capsule portions 112, with the capsule portions being perpendicular to the socket and SMT portions. The terminals 106 are thus snake-like in configuration, in some embodiments. In exemplary embodiments, the capsule portions 112 are integrated with the capsule 118 and the socket portions 110 are integrated with the socket 116 of the fuse assembly 100. Capsule terminal regions 130a and 130b are the parts of the capsule 118 into which respective capsule portions 112 of the terminals 106 are disposed (collectively, “capsule terminal regions 130”).
In exemplary embodiments, socket wedges 124 are disposed on an inside surface of the socket 116 such that they are in the interior chamber 120 of the fuse assembly 100. Likewise, capsule wedges 126 are disposed on an inside surface of the capsule 118 such that they are in the interior chamber 120 of the fuse assembly 100. In exemplary embodiments, the socket wedges 124 are disposed on one side of the fuse element 102 while the capsule wedges 126 are disposed on the other side of the fuse element. In
In exemplary embodiments, the fuse assembly 100 also features an exhaust port 128 built into the socket 116. In exemplary embodiments, the exhaust port 128 is disposed between an inside surface of the socket 116 and an outside surface of the socket, where the inside surface is in the interior chamber 120. The exhaust port 128 provides a pathway for release of gasses and debris material away from the interior chamber 120 resulting from the breakage of the fuse element 102. The exhaust port 128 includes an entrance 132 in the interior chamber 120, providing a pathway for the exhausted materials, and an exit 134 located at an exterior surface of the socket 116.
In exemplary embodiments, the capsule 118 is substantially u-shaped, with an outside surface 136 (the surface opposite the capsule wedges 126) to be placed against the surface of the PCB 122. The socket 116 sits atop the capsule 118 to form the closed interior chamber 120. The capsule 118, including the capsule terminal regions 130, has a first width, w1, while the socket 116 has a second width, w2. The width of the interior of the capsule 118, that is, the distance (horizontal distance in
The fuse assembly 200 includes a fuse element 202 within an interior chamber 220 and disposed between two end bells 204a and 204b (collectively, “end bells 204”). Each end bell 204 is connected to a respective terminal: end bell 204a is connected to terminal 206a and end bell 204b is connected to terminal 206b (collectively, “terminals 206”). Because the fuse assembly 200 is a THT device, each terminal 206 include respective THT portions: terminal 206a includes THT portion 214a and terminal 206b includes THT portion 214b (collectively, “THT portions 214”). The THT portions 214 are to be inserted through dedicated holes drilled through a PCB 222 and soldered to the PCB on the side opposite the fuse assembly 200.
The fuse assembly 200 features housing for the fuse element 202 consisting of a socket 216 and a capsule 218. In exemplary embodiments and in contrast to legacy fuses, the socket 216 is at a location remote from the PCB 222 (e.g., at the top portion of the fuse assembly 200 in
The terminals 206 are shaped to fit with the housing elements, the socket 216 and the capsule 218. In exemplary embodiments, each terminal 206 includes four separate portions for fitting with the housing elements. Terminal 206a includes a bell connection portion 208a, a socket connection portion 210a, a capsule portion 212a, and the already introduced THT portion 214a; likewise, terminal 206b includes a bell portion 208b, a socket portion 210b, a capsule portion 212b, and the THT portion 214b (collectively, “bell portions 208”, “socket portions 210”, and “capsule portions 212”). In exemplary embodiments, the socket 216 and the capsule 218 are made of a non-conductive material, such as plastic.
The bell portions 208 of the terminals 206 connect between respective end bells 204 and one end of respective socket portions 210, with the other end of socket portions being connected to respective capsule portions 212 at one end, with the other end of capsule portions being connected to respective THT portions 214. In exemplary embodiments, the capsule portions 212 are substantially lined up with respective THT portions 214 while the end bell portions 208 are somewhat parallel to the capsule portions 212, with the capsule portions being perpendicular to the socket portions 210. The terminals 206 are thus snake-like in configuration, in some embodiments. In exemplary embodiments, the capsule portions 212 are integrated with the capsule 218 and the socket portions 210, which are bent, are integrated with the socket 216 of the fuse assembly 200. Capsule terminal regions 230a and 230b are the parts of the capsule 218 into which respective capsule portions 212 of the terminals 206 are disposed (collectively, “capsule terminal regions 230”).
In exemplary embodiments, socket wedges 224 are disposed on an inside surface of the socket 216 such that they are in the interior chamber 220 of the fuse assembly 200. Likewise, capsule wedges 226 are disposed on an inside surface of the capsule 218 such that they are in the interior chamber 220 of the fuse assembly 200. In exemplary embodiments, the socket wedges 224 are disposed on one side of the fuse element 202 while the capsule wedges 226 are disposed on the other side of the fuse element. In
In exemplary embodiments, the fuse assembly 200 also features an exhaust port 228 built into the socket 216. In exemplary embodiments, the exhaust port 228 is disposed between an inside surface of the socket 216 and an outside surface of the socket, where the inside surface is in the interior chamber 220. The exhaust port 228 provides a pathway for release of gasses and debris material away from the interior chamber 220 resulting from the breakage of the fuse element 202. The exhaust port 228 includes an entrance 232 in the interior chamber 220, providing a pathway for the exhausted materials, and an exit 234 located at an exterior surface of the socket 216.
In exemplary embodiments, the capsule 218 is substantially u-shaped, with an outside surface 236 (the surface opposite the capsule wedges 226) to be placed against the surface of the PCB 222. The socket 216 sits atop the capsule 218 to form the closed interior chamber 220. The capsule 218, including the capsule terminal regions 230, has a first width, w4, while the socket 216 has a second width, w5. The width of the interior of the capsule 218, that is, the distance (horizontal distance in
When a fuse is broken, due to an overcurrent condition, hot gases are created by the sudden appearance of an arc. The suddenly increased air temperature, hot gases, and molten material create a significant pressure increase (shock wave) inside the fuse housing that will try to exit the housing very quickly, if possible. The molten material results from the breaking of the fuse element or the heating of the fuse terminals or other conductive material nearby. The plastic material of the socket 116/216 and capsule 118/218, when exposed to these same violent gases, will turn into carbon, which is semi-conductive. The resulting explosion of outgassing materials inside the fuse is thus a combination of hot gases, molten materials, and carbonized plastic materials.
The fuse may operate without vents, such that all the outgassing material stays within the housing of the fuse. This may be preferred in some environments where the messy aftereffects of the blown fuse are to be avoided. However, all molten material (from the copper element to the housing walls) will stay in the fuse. If there is an opening somewhere in the fuse housing, the outgassing will exit at the opening and the gases will transport molten and vaporized copper and carbonized semi-conductive plastic materials of the housing to locations external to the fuse housing.
So, while some outgassing is acceptable (and even unavoidable) when the fuse breaks, the outgassing of the fuse should be reduced or controlled as much as possible. The socket wedges, 124/224, capsule wedges 126/226, and exhaust port 128/228 of the fuse assemblies 100/200 are designed to strategically control the outgas sing that occurs when the fuse breaks such that the rating of the fuse remains very high. The socket wedges 124/224 and capsule wedges 126/226 provide additional surface area in the interior chamber 120/220 to which the outgassing material can stick. The exhaust port 128/228 provides a serpentine path for the outgassing to flow out of the fuse assembly 100/200.
In contrast to the fuse assemblies 100 and 200, the socket 310 of the fuse assembly 300 is disposed near a PCB 316 (e.g., at the bottom portion of the fuse assembly 300 in the illustrations), while the capsule 312 is at a location farther away from the PCB (e.g., at the top portion of the fuse assembly 300 in the illustrations). While the socket 310 is in proximity to the PCB 316 along one surface, the capsule 312 is proximate the PCB at join regions 318a and 318b (collectively, “join regions 318”), as shown in
In exemplary embodiments, the features of the fuse assemblies 100 and 200 solve the deficiencies of the legacy fuse assembly 300. By reversing the disposition of the socket 116/216 and the capsule 118/218, the capsule is not able to be thrust away from the fuse assembly. Further, the serpentine shape of the terminals 106/206, in which the socket portion 110/210 is integrated with the socket 116/216, the capsule portion 112/212 is integrated with the capsule 118, and the terminals are soldered onto the PCB (whether SMT or THT), ensures that the capsule and socket remain in place once the fuse element breaks. The socket wedges 124/224 and capsule wedges 126/226 disposed in the interior chamber 120/220 provide mitigation of explosive noise, in exemplary embodiments, as well an increased surface area for receipt of debris. The exhaust port 128/228 provides a serpentine pathway for the travel of debris, which both prevents conductive material from remaining in the interior chamber 120/220 and provides another soundproofing or sound-mitigating mechanism, in exemplary embodiments.
In exemplary embodiments, each capsule section 402 features a projection: capsule section 402a includes projection 404a and capsule section 402b includes projection 404b (collectively, “projections 404”). As the terminals 114 are soldered onto the PCB, the capsule 118 will be strongly fixed in place by the soldered terminals. In exemplary embodiments, the projections 404 further prevent the terminal 106 from moving inside the fuse assembly 100. The white dashed circles at the top of
In exemplary embodiments, each capsule section 502 features a projection: capsule section 502a includes projection 504a and capsule section 502b includes projection 504b (collectively, “projections 504”). As the terminals 206 are affixed to the PCB using through-hole technology, the capsule 218 will be strongly fixed in place by the terminals. In exemplary embodiments, the projections 504 further prevent the terminal 206 from moving inside the fuse assembly 200. As with the fuse assembly 100 (
The socket 116/216 is substantially rectangular cube-shaped having six sides, in exemplary embodiments, with inside surface 602 featuring the socket wedges 124/224. The inside surface 602 forms one surface of the interior chamber 120/220 (
Exhaust ports 128/228, including the entrance 132/232 and exit 134/234 are also shown in
The capsule 118/218 is a generally u-shaped structure having an inside surface 702 which is populated with the capsule wedges 126/226. The capsule wedges 126/226 provide both 1) increased surface area for catching debris once the fuse element breaks and 2) a mechanism to muffle or mitigate the explosive sounds resulting from the breakage. Opposite the inside surface 702, a PCB attach surface 704 is the part of the housing of the fuse assembly 100/200 that contacts the PCB. Side surfaces 706a, 706b, 706c, and 706d surround the inside surface 702 with the capsule wedges 126/226 (collectively, “side surfaces 706”), as shown in
The capsule terminal regions 130/230 introduced in
The exhaust port 128/228 further includes several pathways which are perpendicular to the chambers 802. First pathways 804a, 804b, 804c, and 804d are disposed between chambers 802a and 802b; second pathway 806 is disposed between chambers 802b and 802c; and third pathways 808a, 808b, 808c, and 808d are disposed between chambers 802c and 802d (collectively, “first pathways 804” and “third pathways 808”). Although four pathways 804 are disposed between chambers 802 and 802b and four pathways 808 are disposed between chambers 802c and 802d, the number of pathways may be larger or smaller. Similarly, although one pathway 806 is disposed between chambers 802b and 802c, the exhaust port 128/228 may be designed with a larger number of pathways between the chambers. In exemplary embodiments, the exhaust port 128/228 is designed to provide multiple pathways for outgassing of debris from the interior chamber 120/220 of the fuse assembly 100/200.
Off-gassing debris leaving the interior chamber 120/220 of the fuse assembly 100/200 would first enter chamber 802a, then enter chamber 802b, then chamber 802c, and finally chamber 802d, before reaching exit 134/234. The exhaust port 128/228 is designed to provide multiple paths for egress of the explosive debris, as well as many surfaces to which some of the debris may attach. As compared to a cylindrical tube, the exhaust port 128/228 provides an increased surface area, which also mitigates the noise caused by the fuse element explosion, in exemplary embodiments.
In
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 claims the benefit of priority to, U.S. Provisional Patent Application No. 63/300,422, filed Jan. 18, 2022, entitled “NOVEL FUSE DESIGN,” which application is incorporated herein by reference in its entirety.
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