This invention relates generally to fuses, and, more particularly, to fused disconnect switches.
Fuses are widely used as overcurrent protection devices to prevent costly damage to electrical circuits. Fuse terminals typically form an electrical connection between an electrical power source and an electrical component or a combination of components arranged in an electrical circuit. One or more fusible links or elements, or a fuse element assembly, is connected between the fuse terminals, so that when electrical current through the fuse exceeds a predetermined limit, the fusible elements melt and opens one or more circuits through the fuse to prevent electrical component damage.
In some applications, fuses are employed not only to provide fused electrical connections but also for connection and disconnection, or switching, purposes to complete or break an electrical connection or connections. As such, an electrical circuit is completed or broken through conductive portions of the fuse, thereby energizing or de-energizing the associated circuitry. Typically, the fuse is housed in a fuse holder having terminals that are electrically coupled to desired circuitry. When conductive portions of the fuse, such as fuse blades, terminals, or ferrules, are engaged to the fuse holder terminals, an electrical circuit is completed through the fuse, and when conductive portions of the fuse are disengaged from the fuse holder terminals, the electrical circuit through the fuse is broken. Therefore, by inserting and removing the fuse to and from the fuse holder terminals, a fused disconnect switch is realized.
Known fused disconnects are subject to a number of problems in use. For example, any attempt to remove the fuse while the fuses are energized and under load may result in hazardous conditions because dangerous arcing may occur between the fuses and the fuse holder terminals. Some fuseholders designed to accommodate, for example, UL (Underwriters Laboratories) Class CC fuses and IEC (International Electrotechnical Commission) 10X38 fuses that are commonly used in industrial control devices include permanently mounted auxiliary contacts and associated rotary cams and switches to provide early-break and late-make voltage and current connections through the fuses when the fuses are pulled from fuse clips in a protective housing. One or more fuses may be pulled from the fuse clips, for example, by removing a drawer from the protective housing. Early-break and late-make connections are commonly employed, for example, in motor control applications. While early-break and late-make connections may increase the safety of such devices to users when installing and removing fuses, such features increase costs, complicate assembly of the fuseholder, and are undesirable for switching purposes.
Structurally, the early-break and late-make connections can be intricate and may not withstand repeated use for switching purposes. In addition, when opening and closing the drawer to disconnect or reconnect circuitry, the drawer may be inadvertently left in a partly opened or partly closed position. In either case, the fuses in the drawer may not be completely engaged to the fuse terminals, thereby compromising the electrical connection and rendering the fuseholder susceptible to unintended opening and closing of the circuit. Especially in environments subject to vibration, the fuses may be jarred loose from the clips. Still further, a partially opened drawer protruding from the fuseholder may interfere with workspace around the fuseholder. Workers may unintentionally bump into the opened drawers, and perhaps unintentionally close the drawer and re-energize the circuit.
Additionally, in certain systems, such as industrial control devices, electrical equipment has become standardized in size and shape, and because known fused disconnect switches tend to vary in size and shape from the standard norms, they are not necessarily compatible with power distribution panels utilized with such equipment. For at least the above reasons, use of fused disconnect switches have not completely met the needs of certain end applications.
In the illustrative embodiment of
The housing 104 may be fabricated from an insulative or nonconductive material, such as plastic, according to known methods and techniques, including but not limited to injection molding techniques. In an exemplary embodiment, the housing 104 is formed into a generally rectangular size and shape which is complementary to and compatible with DIN and IEC standards applicable to standardized electrical equipment. In particular, for example, each housing 104 has lower edge 112, opposite side edges 114, side panels 116 extending between the side edges 114, and an upper surface 118 extending between the side edges 114 and the side panels 116. The lower edge 112 has a length L and the side edges 114 have a thickness T, such as 17.5 mm in one embodiment, and the length L and thickness T define an area or footprint on the lower edge 112 of the housing 104. The footprint allows the lower edge 112 to be inserted into a standardized opening having a complementary shape and dimension. Additionally, the side edges 114 of the housing 104 have a height H in accordance with known standards, and the side edges 114 include slots 120 extending therethrough for ventilating the housing 104. The upper surface 118 of the housing 104 may be contoured to include a raised central portion 122 and recessed end portions 124 extending to the side edges 114 of the housing 104.
The fuse 106 of each module 102 may be loaded vertically in the housing 104 through an opening in the upper surface 118 of the housing 104, and the fuse 106 may extend partly through the raised central portion 122 of the upper surface 118. The fuse cover 108 extends over the exposed portion of the fuse 106 extending from the housing 104, and the cover 108 secures the fuse 106 to the housing 104 in each module 102. In an exemplary embodiment, the cover 108 may be fabricated from a non-conductive material, such as plastic, and may be formed with a generally flat or planar end section 126 and elongated fingers 128 extending between the upper surface 118 of the raised central portion 122 of the housing 104 and the end of the fuse 106. Openings are provided in between adjacent fingers 128 to ventilate the end of the fuse 106.
In an exemplary embodiment, the cover 108 further includes rim sections 130 joining the fingers 128 opposite the end section 126 of the cover 108, and the rim sections 130 secure the cover 108 to the housing 104. In an exemplary embodiment, the rim sections 130 cooperate with grooves in the housing 104 such that the cover 108 may rotate a predetermined amount, such as 25 degrees, between a locked position and a release position. That is, once the fuse 106 is inserted into the housing 104, the fuse cover 108 may be installed over the end of the fuse 106 into the groove of the housing 104, and the cover 108 may be rotated 25 degrees to the locked position wherein the cover 108 will frustrate removal of the fuse 106 from the housing 104. The groove may also be ramped or inclined such that the cover 108 applies a slight downward force on the fuse 106 as the cover 108 is installed. To remove the fuse 106, the cover 108 may be rotated from the locked position to the open position wherein both the cover 108 and the fuse 106 may be removed from the housing 104.
The switch actuator 110 may be located in an aperture 132 of the raised upper surface 122 of the housing 104, and the switch actuator 110 may partly extend through the raised upper surface 122 of the housing 104. The switch actuator 100 may be rotatably mounted to the housing 104 on a shaft or axle 134 within the housing 104, and the switch actuator 110 may include a lever, handle or bar 136 extending radially from the actuator 110. By moving the lever 136 from a first edge 138 to a second edge 140 of the aperture 132, the shaft 134 rotates to an open or switch position and electrically disconnects the fuse 106 in each module 102 as explained below. When the lever 136 is moved from the second edge 140 to the first edge 138, the shaft 134 rotates back to the closed position illustrated in
A line side terminal element may 142 extend from the lower edge 112 of the housing 104 in each module 102 for establishing line and load connections to circuitry. As shown in
A lower conductive fuse terminal 156 may be located in a bottom portion of the fuse compartment 150 and may be U-shaped in one embodiment. One of the end caps 154 of the fuse 106 rests upon an upper leg 158 of the lower terminal 156, and the other end cap 154 of the fuse 106 is coupled to an upper terminal 160 located in the housing 104 adjacent the fuse compartment 150. The upper terminal 160 is, in turn, connected to a load side terminal 162 to accept a load side connection to the disconnect module 102 in a known manner. The load side terminal 162 in one embodiment is a known saddle screw terminal, although it is appreciated that other types of terminals could be employed for load side connections to the module 102. Additionally, the lower fuse terminal 156 may include fuse rejection features in a further embodiment which prevent installation of incorrect fuse types into the module 102.
The switch actuator 110 may be located in an actuator compartment 164 within the housing 104 and may include the shaft 134, a rounded body 166 extending generally radially from the shaft 134, the lever 136 extending from the body 166, and an actuator link 168 coupled to the actuator body 166. The actuator link 168 may be connected to a spring loaded contact assembly 170 including first and second movable or switchable contacts 172 and 174 coupled to a sliding bar 176. In the closed position illustrated in
While in an exemplary embodiment the stationary contact 178 is mounted to a terminal 142 having a bus bar clip, another terminal element, such as a known box lug or clamp terminal could be provided in a compartment 182 in the housing 104 in lieu of the bus bar clip. Thus, the module 102 may be used with a hard-wired connection to line-side circuitry instead of a line input bus. Thus, the module 102 is readily convertible to different mounting options in the field.
When the switch actuator 110 is rotated about the shaft 134 in the direction of arrow A, the siding bar 176 may be moved linearly upward in the direction of arrow B to disengage the switchable contacts 172 and 174 from the stationary contacts 178 and 180. The lower fuse terminal 156 is then disconnected from the line-side terminal element while the fuse 106 remains electrically connected to the lower fuse terminal 156 and to the load side terminal 162. An arc chute compartment 184 may be formed in the housing 104 beneath the switchable contacts 172 and 174, and the arc chute may provide a space to contain and dissipate arcing energy as the switchable contacts 172 and 174 are disconnected. Arcing is broken at two locations at each of the contacts 172 and 174, thus reducing arc intensity, and arcing is contained within the lower portions of the housing 104 and away from the upper surface 118 and the hands of a user when manipulating the switch actuator 110 to disconnect the fuse 106 from the line side terminal 142.
The housing 104 additionally may include a locking ring 186 which may be used cooperatively with a retention aperture 188 in the switch actuator body 166 to secure the switch actuator 110 in one of the closed position shown in
A bias element 200 may be provided beneath the sliding bar 176 and may force the sliding bar 176 upward in the direction of arrow B to a fully opened position separating the contacts 172, 174 and 178, 180 from one another. Thus, as the actuator body 166 is rotated in the direction of arrow A, the link 168 is moved past a point of equilibrium and the bias element 200 assists in opening of the contacts 172, 174 and 178, 180. The bias element 200 therefore prevents partial opening of the contacts 172, 174 and 178, 180 and ensures a full separation of the contacts to securely break the circuit through the module 102.
Additionally, when the actuator lever 136 is pulled back in the direction of arrow C to the closed position shown in
In one exemplary embodiment, and as illustrated in
The lever 136, when moved between the opened and closed positions of the switch actuator, does not interfere with workspace around the disconnect module 102, and the lever 136 is unlikely to be inadvertently returned to the closed position from the open position. In the closed position shown in
When the modules 102 are ganged together to form a multi-pole device, such as the device 100, one lever 136 may be extended through and connect to multiple switch actuators 110 for different modules. Thus, all the connected modules 102 may be disconnected and reconnected by manipulating a single lever 136. That is, multiple poles in the device 100 may be switched simultaneously. Alternatively, the switch actuators 110 of each module 102 in the device 100 may be actuated independently with separate levers 136 for each module.
Like the module 102, the module 220 may include the fuse 106, the fuse cover 108 and the switch actuator 110. Switching of the module is accomplished with switchable contacts as described above in relation to the module 102.
Unlike the modules 102 and 220, the module 250 may include a housing 252 configured or adapted to receive a rectangular fuse module 254 instead of a cartridge fuse 106. The fuse module 254 is a known assembly including a rectangular housing 256, and terminal blades 258 extending from the housing 256. A fuse element or fuse assembly may be located within the housing 256 and is electrically connected between the terminal blades 258. Such fuse modules 254 are known and in one embodiment are CubeFuse modules commercially available from Cooper Bussmann of St. Louis, Mo.
A line side fuse clip 260 may be situated within the housing 252 and may receive one of the terminal blades 258 of the fuse module 254. A load side fuse clip 262 may also be situated within the housing 252 and may receive the other of the fuse terminal blades 258. The line side fuse clip 260 may be electrically connected to the stationary contact 180. The load side fuse clip 262 may be electrically connected to the load side terminal 162. The line side terminal 142 may include the stationary contact 178, and switching may be accomplished by rotating the switch actuator 110 to engage and disengage the switchable contacts 172 and 174 with the respective stationary contacts 178 and 180 as described above. While the line terminal 142 is illustrated as a bus bar clip, it is recognized that other line terminals may be utilized in other embodiments, and the load side terminal 162 may likewise be another type of terminal in lieu of the illustrated saddle screw terminal in another embodiment.
The fuse module 254 may be plugged into the fuse clips 260, 262 or extracted therefrom to install or remove the fuse module 254 from the housing 252. For switching purposes, however, the circuit is connected and disconnected at the contacts 172, 174 and 178 and 180 rather than at the fuse clips 260 and 262. Arcing between the disconnected contacts may therefore contained in an arc chute or compartment 270 at the lower portion of the compartment and away from the fuse clips 260 and 262. By opening the disconnect module 250 with the switch actuator 110 before installing or removing the fuse module 254, any risk posed by electrical arcing or energized metal at the fuse and housing interface is eliminated. The disconnect module 250 is therefore believed to be safer to use than many known fused disconnect switches.
A plurality of modules 250 may be ganged or otherwise connected together to form a multi-pole device. The poles of the device could be actuated with a single lever 136 or independently operable with different levers.
The housing may also include connection openings 306 and access openings 308 in each side edge 310 which may receive a wire connection and a tool, respectively, to establish line and load connections to the fuses 106. A single switch actuator 110 may be rotated to connect and disconnect the circuit through the fuses between line and load terminals of the disconnect device 300.
Retention bars 328 may also be provided on the shaft 134 which extend to the fuses 106 and engage the fuses in an interlocking manner to prevent the fuses 106 from being removed from the device 300 except when the switch actuator 110 is in the open position. In the open position, the retention bars 328 may be angled away from the fuses 106 and the fuses may be freely removed. In the closed position, as shown in
A DIN rail mounting slot 418 may be formed in a lower edge 420 of the housing 412, and the DIN rail mounting slot 418 may be dimensioned, for example, for snap-fit engagement and disengagement with a 35 mm DIN rail by hand and without a need of tools. The housing 412 may also include openings 422 that may be used to gang the module 410 to other disconnect modules as explained below. Side edges 424 of the housing 412 may be open ended to provide access to wire lug terminals 426 to establish line and load-side electrical connections external circuitry. Terminal access openings 428 may be provided in recessed upper surfaces 430 of the housing 412. A stripped wire, for example, may be extended through the sides of the wire lug terminals 426 and a screwdriver may be inserted through the access openings 428 to tighten a terminal screw to clamp the wires to the terminals 426 and connect line and load circuitry to the module 410. While wire lug terminals 426 are included in one embodiment, it is recognized that a variety of alternative terminal configurations or types may be utilized in other embodiments to establish line and load side electrical connections to the module 410 via wires, cables, bus bars etc.
Like the foregoing embodiments, the housing 412 is sized and dimensioned complementary to and compatible with DIN and IEC standards, and the housing 412 defines an area or footprint on the lower edge 420 for use with standardized openings having a complementary shape and dimension. By way of example only, the housing 412 of the single pole module 410 may have a thickness T of about 17.5 mm for a breaking capacity of up to 32 A; 26 mm for a breaking capacity of up to 50 A, 34 mm for a breaking capacity of up to 125 A; and 40 mm for a breaking capacity of up to 150 A per DIN Standard 43 880. Likewise, it is understood that the module 410 could be fabricated as a multiple pole device such as a three pole device having a dimension T of about 45 mm for a breaking capacity of up to 32 A; 55 mm for a breaking capacity of up to 50 A, and 75 mm for a breaking capacity of up to 125 A. While exemplary dimensions are provided, it is understood that other dimensions of greater or lesser values may likewise be employed in alternative embodiments of the invention.
Additionally, and as illustrated in
Additionally, the housing 412 may also include horizontally extending ribs or shelves 434 spaced from one another and interconnecting the innermost flanges 432 in a lower portion of the housing side edges 424. The ribs or shelves 434 increase a surface area path length between the terminals 426 in a vertical plane of the housing 412 to meet external requirements for spacing between the terminals 426. The flanges 432 and ribs 434 result in serpentine-shaped surface areas in horizontal and vertical planes of the housing 412 that permit greater voltage ratings of the device without increasing the footprint of the module 410 in comparison, for example, to the previously described embodiments of
The cover 416, unlike the above-described embodiments, may include a substantially flat cover portion 436, and an upstanding finger grip portion 438 projecting upwardly and outwardly from one end of the flat cover portion 436 and facing the switch actuator 414. The cover may be fabricated from a nonconductive material or insulative material such as plastic according to known techniques, and a the flat cover portion 436 may be hinged at an end thereof opposite the finger grip portion 438 so that the cover portion 436 is pivotal about the hinge. By virtue of the hinge, the finger grip portion 438 is movable away from the switch actuator along an arcuate path as further explained below. As illustrated in
A cover lockout tab 444 extends radially outwardly from a cylindrical body 446 of the switch actuator 414, and when the switch actuator 414 is in the closed position illustrated in
A conductive path through the housing 412 and fuse 442 is established as follows. A rigid terminal member 458 is extended from the load side terminal 426 closest to the fuse 442 on one side of the housing 412. A flexible contact member 460, such as a wire may be connected to the terminal member 458 at one end and attached to an inner surface of the cover 416 at the opposite end. When the cover 416 is closed, the contact member 460 is brought into mechanical and electrical engagement with an upper ferrule or end cap 462 of the fuse 442. A movable lower fuse terminal 464 is mechanically and electrically connected to the lower fuse ferrule or end cap 466, and a flexible contact member 468 interconnects the movable lower fuse terminal 464 to a stationary terminal 470 that carries one of the stationary contacts 452. The switchable contacts 450 interconnect the stationary contacts 452 when the switch actuator 414 is closed as shown in
The fuse 442 in different exemplary embodiments may be a commercially available 10×38 Midget fuse of Cooper Bussmann of St. Louis, Mo.; an IEC 10x38 fuse; a class CC fuse; or a D/DO European style fuse. Additionally, and as desired, optional fuse rejection features may be formed in the lower fuse terminal 464 or elsewhere in the module, and cooperate with fuse rejection features of the fuses so that only certain types of fuses may be properly installed in the module 410. While certain examples of fuses are herein described, it is understood that other types and configurations of fuses may also be employed in alternative embodiments, including but not limited to various types of cylindrical or cartridge fuses and rectangular fuse modules.
A biasing element 474 may be provided between the movable lower fuse terminal 464 and the stationary terminal 470. The bias element 474 may be for example, a helical coil spring that is compressed to provide an upward biasing force in the direction of arrow G to ensure mechanical and electrical engagement of the movable lower fuse terminal 464 to the lower fuse ferrule 466 and mechanical and electrical engagement between the upper fuse ferrule 462 and the flexible contact member 460. When the cover 416 is opened in the direction of arrow E to the open position, the bias element 474 forces the fuse upward along its axis 441 in the direction of arrow G as shown in
The bias element 474 deflects when the cover 416 is opened after the actuator 414 is moved to the open position, and the bias element 474 lifts the fuse 442 from the housing 412 so that the upper fuse ferrule 462 is extended above the top surface 415 of the housing. In such a position, the fuse 442 may be easily grasped and pulled out of or extracted from the module 410 along the axis 441. Fuses may therefore be easily removed from the module 410 for replacement.
Also when the actuator 414 is moved to the open position, an actuator lockout tab 476 extends radially outwardly from the switch actuator body 446 and may accept for example, a padlock to prevent inadvertent closure of the actuator 414 in the direction of arrow H that would otherwise cause the slider bar 456 to move downward in the direction of arrow I along the axis 475 and engage the switchable contacts 450 to the stationary contacts 452, again completing the electrical connection to the fuse 442 and presenting a safety hazard to operators. When desired, the cover 416 may be rotated back about the hinge 448 to the closed position shown in
While single pole modules 410 ganged to one another to form multiple pole devices has been described, it is understood that a multiple pole device having the features of the module 410 could be constructed in a single housing with appropriate modification of the embodiment shown in
Similar to the module 410, the module 500 may include a DIN rail mounting slot 512 formed in a lower edge 514 of the housing 502 for mounting of the housing 502 without a need of tools. The housing 502 may also include an actuator opening 515 providing access to the body of the switch actuator 504 so that the actuator 504 may be rotated between the open and closed positions in an automated manner and facilitate remote control of the module 500. Openings 516 are also provided that may be used to gang the module 500 to other disconnect modules. A curved or arcuate tripping guide slot 517 is also formed in a front panel of the housing 502. A slidable tripping mechanism, described below, is selectively positionable within the slot 517 to trip the module 500 and disconnect the current path therethrough upon an occurrence of predetermined circuit conditions. The slot 517 also provides access to the tripping mechanism for manual tripping of the mechanism with a tool, or to facilitate remote tripping capability.
Side edges 518 of the housing 502 may be open ended to provide access to line and load side wire lug terminals 520 to establish line and load-side electrical connections to the module 500, although it is understood that other types of terminals may be used. Terminal access openings 522 may be provided in recessed upper surfaces 524 of the housing 502 to receive a stripped wire or other conductor extended through the sides of the wire lug terminals 520, and a screwdriver may be inserted through the access openings 522 to connect line and load circuitry to the module 500. Like the foregoing embodiments, the housing 502 is sized and dimensioned complementary to and compatible with DIN and IEC standards, and the housing 502 defines an area or footprint on the lower surface 514 of the housing for use with standardized openings having a complementary shape and dimension.
Like the module 410 described above, the side edges 518 of the housing 502 may include opposed pairs of vertically oriented flanges or wings 526 spaced from one another and projecting away from the wire lug terminals 520 adjacent the housing upper surface 524 and the sides of the wire lug terminals 520. The housing 502 may also include horizontally extending ribs or shelves 528 spaced from one another and interconnecting the innermost flanges 526 in a lower portion of the housing side edges 518. The flanges 526 and ribs 528 result in serpentine-shaped surface areas in horizontal and vertical planes of the housing 502 that permit greater voltage ratings of the device without increasing the footprint of the module 500 as explained above.
The cover 508, unlike the above-described embodiments, may include a contoured outer surface defining a peak 530 and a concave section 532 sloping downwardly from the peak 530 and facing the switch actuator 504. The peak 530 and the concave section 532 form a finger cradle area on the surface of the cover 508 and is suitable for example, to serve as a thumb rest for an operator to open or close the cover 508. The cover 508 may be hinged at an end thereof closest to the peak 530 so that the cover 508 is pivotal about the hinge and the cover 508 is movable away from the switch actuator 504 along an arcuate path. As illustrated in
The wire lug terminals 520 and terminal screws 440 are positioned adjacent the side edges 518 of the housing 502. The fuse 442 is vertically loaded into the housing 502 beneath the cover 508, and the fuse 442 is situated in the non-movable fuse receptacle 437 formed in the housing 502. The cover 508 may be formed with a conductive contact member that may be, for example, cup-shaped to receive the upper fuse ferrule 462 when the cover 508 is closed.
A conductive circuit path is established from the line side terminal 520 and the terminal member 472, through the switch contacts 450 and 452 to the terminal member 470. From the terminal member 470, current flows through the contact member 468 to the lower fuse terminal 464 and through the fuse 442. After flowing through the fuse 442, current flows from the conductive contact member 542 of the cover 508 to the contact member 460 connected to the conductive contact member 542, and from the contact member 460 to the terminal member 458 and to the line side terminal 426.
A biasing element 474 may be provided between the movable lower fuse terminal 464 and the stationary terminal 470 as described above to ensure mechanical and electrical connection between the cover contact member 542 and the upper fuse ferrule 462 and between the lower fuse terminal 464 and the lower fuse ferrule 466. Also, the bias element 474 automatically ejects the fuse 442 from the housing 502 as described above when the cover 508 is rotated about the hinge 448 in the direction of arrow E after the switch actuator 504 is rotated in the direction of arrow F.
Unlike the module 410, the module 500 may further include a tripping mechanism 544 in the form of a slidably mounted trip bar 545 and a solenoid 546 connected in parallel across the fuse 442. The trip bar 545 is slidably mounted to the tripping guide slot 517 formed in the housing 502, and in an exemplary embodiment the trip bar 545 may include a solenoid arm 547, a cover interlock arm 548 extending substantially perpendicular to the solenoid arm 547, and a support arm 550 extending obliquely to each of the solenoid arm 547 and cover interlock arm 548. The support arm 550 may include a latch tab 552 on a distal end thereof. The body 446 of the switch actuator 504 may be formed with a ledge 554 that cooperates with the latch tab 552 to maintain the trip bar 545 and the actuator 504 in static equilibrium with the solenoid arm 547 resting on an upper surface of the solenoid 546.
A torsion spring 555 is connected to the housing 502 one end and the actuator body 446 on the other end, and the torsion spring 555 biases the switch actuator 504 in the direction of arrow F to the open position. That is, the torsion spring 555 is resistant to movement of the actuator 504 in the direction of arrow H and tends to force the actuator body 446 to rotate in the direction of arrow F to the open position. Thus, the actuator 504 is failsafe by virtue of the torsion spring 555. If the switch actuator 504 is not completely closed, the torsion spring 555 will force it to the open position and prevent inadvertent closure of the actuator switchable contacts 450, together with safety and reliability issues associated with incomplete closure of the switchable contacts 450 relative to the stationary contacts 452.
In normal operating conditions when the actuator 504 is in the closed position, the tendency of the torsion spring 555 to move the actuator to the open position is counteracted by the support arm 550 of the trip bar 545 as shown in
An actuator interlock 556 is formed with the cover 508 and extends downwardly into the housing 502 adjacent the fuse receptacle 437. The cover interlock arm 548 of the trip arm 545 is received in the actuator interlock 556 of the cover 508 and prevents the cover 508 from being opened unless the switch actuator 504 is rotated in the direction of arrow F as explained below to move the trip bar 545 and release the cover interlock arm 548 of the trip bar 545 from the actuator interlock 556 of the cover 508. Deliberate rotation of the actuator 504 in the direction of arrow F causes the latch tab 552 of the support arm 550 of the trip bar 545 to be pivoted away from the actuator and causes the solenoid arm 547 to become inclined or angled relative to the solenoid 546. Inclination of the trip bar 545 results in an unstable position and the torsion spring 555 forces the actuator 504 to rotate and further pivot the trip bar 545 to the point of release.
Absent deliberate movement of the actuator to the open position in the direction of arrow F, the trip bar 545, via the interlock arm 548, directly opposes movement of the cover 508 and resists any attempt by a user to rotate the cover 508 about the cover hinge 448 in the direction of arrow E to open the cover 508 while the switch actuator 504 is closed and the switchable contacts 450 are engaged to the stationary contacts 452 to complete a circuit path through the fuse 442. Inadvertent contact with energized portions of the fuse 442 is therefore prevented, as the fuse can only be accessed when the circuit through the fuse is broken via the switchable contacts 450, thereby providing a degree of safety to human operators of the module 500.
Upper and lower solenoid contact members 557, 558 are provided and establish electrical contact with the respective upper and lower ferrules 462, 466 of the fuse 442 when the cover 508 is closed over the fuse 442. The contact members 557, 558 establish, in turn, electrical contact to a circuit board 560. Resistors 562 are connected to the circuit board 560 and define a high resistance parallel circuit path across the ferrules 462, 466 of the fuse 442, and the solenoid 546 is connected to this parallel circuit path on the circuit board 560. In an exemplary embodiment, the resistance is selected so that, in normal operation, substantially all of the current flow passes through the fuse 442 between the fuse ferrules 462, 466 instead of through the upper and lower solenoid contact members 557, 558 and the circuit board 560. The coil of the solenoid 546 is calibrated so that when the solenoid 546 experiences a predetermined voltage, the solenoid generates an upward force in the direction of arrow G that causes the trip bar 545 to be displaced in the tripping guide slot 517 along an arcuate path defined by the slot 517.
As those in the art may appreciate, the coil of the solenoid 546 may be calibrated to be responsive to a predetermined undervoltage condition or a predetermined overvoltage condition as desired. Additionally, the circuit board 560 may include circuitry to actively control operation of the solenoid 546 in response to circuit conditions. Contacts may further be provided on the circuit board 560 to facilitate remote control tripping of the solenoid 546. Thus, in response to abnormal circuit conditions that are predetermined by the calibration of the solenoid coil or control circuitry on the board 560, the solenoid 546 activates to displace the trip bar 545. Depending on the configuration of the solenoid 546 and/or the board 560, opening of the fuse 442 may or may not trigger an abnormal circuit condition causing the solenoid 546 to activate and displace the trip bar 545.
As the trip bar 545 traverses the arcuate path in the guide slot 517 when the solenoid 546 operates, the solenoid arm 547 is pivoted and becomes inclined or angled relative to the solenoid 546. Inclination of the solenoid arm 547 causes the trip bar 545 to become unstable and susceptible to force of the torsion spring 555 acting on the trip arm latch tab 552 via the ledge 554 in the actuator body 446. As the torsion spring 555 begins to rotate the actuator 504, the trip bar 545 is further pivoted due to engagement of the trip arm latch tab 552 and the actuator ledge 554 and becomes even more unstable and subject to the force of the torsion spring. The trip bar 545 is further moved and pivoted by the combined action of the guide slot 517 and the actuator 504 until the trip arm latch tab 552 is released from the actuator ledge 554, and the interlock arm 548 of the trip bar 545 is released from the actuator interlock 556. At this point, each of the actuator 504 and the cover 508 are freely rotatable.
As
The auxiliary contact module 602 may include a housing 603 generally complementary in shape to the housing 502 of the module 500, and may include an actuator 604 similar to the actuator 508 of the module 500. An actuator link 606 may interconnect the actuator 604 and a sliding bar 608. The sliding bar 608 may carry, for example, two pairs of switchable contacts 610 spaced from another. One of the pairs of switchable contacts 610 connects and disconnects a circuit path between a first set of auxiliary terminals 612 and rigid terminal members 614 extending from the respective terminals 612 and each carrying a respective stationary contact for engagement and disengagement with the first set of switchable contacts 610. The other pair of switchable contacts 610 connects and disconnects a circuit path between a second set of auxiliary terminals 616 and rigid terminal members 618 extending from the respective terminals 616 and each carrying a respective stationary contact for engagement and disengagement with the second set of switchable contacts 610.
By joining or tying the actuator lever 620 of the auxiliary contact module 602 to the actuator lever 510 of the disconnect module 500 with a pin or a shim, for example, the actuator 604 of the auxiliary contact module 602 may be moved or tripped simultaneously with the actuator 508 of the disconnect module 500. Thus, auxiliary connections may be connected and disconnected together with a primary connection established through the disconnect module 500. For example, when the primary connection established through the module 500 powers an electric motor, an auxiliary connection to a cooling fan may be made to the auxiliary contact module via one of the sets of terminals 612 and 616 so that the fan and motor will be powered on and off simultaneously by the device 600. As another example, one of the auxiliary connections through the terminals 612 and 616 of the auxiliary contact module 602 may be used for remote indication purposes to signal a remote device of the status of the device as being opened or closed to connect or disconnect circuits through the device 600.
While the auxiliary contact features have been described in the context of an add-on module 602, it is understood that the components of the module 602 could be integrated into the module 500 if desired. Single pole or multiple pole versions of such a device could likewise be provided.
The monitoring module 652 may include a housing 654 generally complementary in shape to the housing 502 of the module 500. A sensor board 656 is located in the housing 652, and flexible contact members 658, 660 are respectively connected to each of the ferrules 462, 466 (
Optionally, an input signal port 678 may be included in the monitoring module 652. The input signal port 678 may be interconnected with an output signal port 672 of another monitoring module, such that signals from multiple monitoring modules may be daisy chained together to a single communications device 674 for transmission to the remote system 676. Interface plugs (not shown) may be used to interconnect one monitoring module to another in an electrical system.
In one embodiment, the sensor 662 is a voltage sensing latch circuit having first and second portions optically isolated from one another. When the primary fuse element 680 of the fuse 442 opens to interrupt the current path through the fuse, the sensor 662 detects the voltage drop across the terminal elements T1 and T2 (the solenoid contact members 557 and 558) associated with the fuse 442. The voltage drop causes one of the circuit portions, for example, to latch high and provide an input signal to the input/output element 664. Acceptable sensing technology for the sensor 662 is available from, for example, SymCom, Inc. of Rapid City, S. Dak.
While in the exemplary embodiment, the sensor 662 is a voltage sensor, it is understood that other types of sensing could be used in alternative embodiments to monitor and sense an operating state of the fuse 442, including but not limited to current sensors and temperature sensors that could be used to determine whether the primary fuse element 680 has been interrupted in an overcurrent condition to isolate or disconnect a portion of the associated electrical system.
In a further embodiment, one or more additional sensors or transducers 682 may be provided, internal or external to the monitoring module 652, to collect data of interest with respect to the electrical system and the load connected to the fuse 442. For example, sensors or transducers 682 may be adapted to monitor and sense vibration and displacement conditions, mechanical stress and strain conditions, acoustical emissions and noise conditions, thermal imagery and thermalography states, electrical resistance, pressure conditions, and humidity conditions in the vicinity of the fuse 442 and connected loads. The sensors or transducers 682 may be coupled to the input/output device 664 as signal inputs. Video imaging and surveillance devices (not shown) may also be provided to supply video data and inputs to the input/output element 664.
In an exemplary embodiment, the input/output element 664 may be a microcontroller having a microprocessor or equivalent electronic package that receives the input signal from the sensor 662 when the fuse 442 has operated to interrupt the current path through the fuse 442. The input/output element 664, in response to the input signal from the sensor 662, generates a data packet in a predetermined message protocol and outputs the data packet to the signal port 672 or the communications device 674. The data packet may be formatted in any desirable protocol, but in an exemplary embodiment includes at least a fuse identification code, a fault code, and a location or address code in the data packet so that the operated fuse may be readily identified and its status confirmed, together with its location in the electrical system by the remote system 676. Of course, the data packet could contain other information and codes of interest, including but not limited to system test codes, data collection codes, security codes and the like that is desirable or advantageous in the communications protocol.
Additionally, signal inputs from the sensor or transducer 682 may be input the input/output element 664, and the input/output element 664 may generate a data packet in a predetermined message protocol and output the data packet to the signal port 672 or the communications device 674. The data packet may include, for example, codes relating to vibration and displacement conditions, mechanical stress and strain conditions, acoustical emissions and noise conditions, thermal imagery and thermalography states, electrical resistance, pressure conditions, and humidity conditions in the vicinity of the fuse 442 and connected loads. Video and imaging data, supplied by the imaging and surveillance devices 682 may also be provided in the data packet. Such data may be utilized for troubleshooting, diagnostic, and event history logging for detailed analysis to optimize the larger electrical system.
The transmitted data packet from the communications device 674, in addition to the data packet codes described above, also includes a unique transmitter identifier code so that the overview and response dispatch system 676 may identify the particular monitoring module 652 that is sending a data packet in a larger electrical system having a large number of monitoring modules 652 associated with a number of fuses. As such, the precise location of the affected disconnect module 500 in an electrical system may be identified by the overview and response dispatch system 676 and communicated to responding personnel, together with other information and instruction to quickly reset affected circuitry when one or more of the modules 500 operates to disconnect a portion of the electrical system.
In one embodiment, the communications device 674 is a low power radio frequency (RF) signal transmitter that digitally transmits the data packet in a wireless manner. Point-to-point wiring in the electrical system for fuse monitoring purposes is therefore avoided, although it is understood that point-to-point wiring could be utilized in some embodiments of the invention. Additionally, while a low power digital radio frequency transmitter has been specifically described, it is understood that other known communication schemes and equivalents could alternatively be used if desired.
Status indicators and the like such as light emitting diodes (LED's) may be provided in the monitoring module 652 to locally indicate an operated fuse 442 or a tripped disconnect condition. Thus, when maintenance personnel arrives at the location of the disconnect module 500 containing the fuse 442, the status indicators may provide local state identification of the fuses associated with the module 500.
Further details of such monitoring technology, communication with the remote system 676, and response and operation of the system 676 are disclosed in commonly owned U.S. patent application Ser. No. 11/223,385 filed Sep. 9, 2005 and entitled Circuit Protector Monitoring Assembly, Kit and Method.
While the monitoring features have been described in the context of an add-on module 652, it is understood that the components of the module 652 could be integrated into the module 500 if desired. Single pole or multiple pole versions of such a device could likewise be provided. Additionally, the monitoring module 652 and the auxiliary contact module could each be used with a single disconnect module 500 if desired, or alternative could be combined in an integrated device with single pole or multiple pole capability.
In use, the resistance alloy strip is joined to the contact members 557 and 558 and defines a high resistance parallel connection across the ferrules 462 and 466 of the fuse 442. The resistance alloy is heated by current flowing through the resistance alloy and the resistance alloy, in turn heats the bimetal strip. When a predetermined current condition is approached, the differing rates of coefficients of thermal expansion in the bimetal strip causes the overload element 702 to bend and displace the trip bar 545 to the point of release where the spring loaded actuator 504 and sliding bar 456 move to the opened positions to disconnect the circuit through the fuse 442.
The module 700 may be used in combination with other modules 500 or 700, auxiliary contact modules 602, and monitoring modules 652. Single pole and multiple pole versions of the module 700 may also be provided.
The module 702 may be used in combination with other modules 500 or 700, auxiliary contact modules 602, and monitoring modules 652. Single pole and multiple pole versions of the module 700 may also be provided.
Embodiments of fusible disconnect devices are therefore described herein that may be conveniently switched on and off in a convenient and safe manner without interfering with workspace around the device. The disconnect devices may be reliably switch a circuit on and off in a cost effective manner and may be used with standardized equipment in, for example, industrial control applications. Further, the disconnect modules and devices may be provided with various mounting and connection options for versatility in the field. Auxiliary contact and overload and underload tripping capability is provided, together with remote monitoring and control capability.
The device 750 includes a disconnect housing 752 fabricated from an electrically nonconductive or insulative material such as plastic, and the fuse module housing 752 is configured or adapted to receive a retractable rectangular fuse module 754. While a rectangular fuse module 754 is shown in the exemplary embodiment illustrated, it is recognized that the disconnect housing 754 may alternatively be configured to receive and engage another type of fuse, such as cylindrical or cartridge fuses familiar to those in the art and as described above. The disconnect housing 752 and its internal components described below, are sometimes referred to as a base assembly that receives the retractable fuse module 754.
The fuse module 754 in the exemplary embodiment shown includes a rectangular housing 756 fabricated from an electrically nonconductive or insulative material such as plastic, and conductive terminal elements in the form or terminal blades 758 extending from the housing 756. A primary fuse element or fuse assembly is located within the housing 756 and is electrically connected between the terminal blades 758 to provide a current path therebetween. Such fuse modules 754 are known and in one embodiment the rectangular fuse module is a CUBEFuse™ power fuse module commercially available from Cooper Bussmann of St. Louis, Mo. The fuse module 754 provides overcurrent protection via the primary fuse element therein that is configured to melt, disintegrate or otherwise fail and permanently open the current path through the fuse element between the terminal blades 758 in response to predetermined current conditions flowing through the fuse element in use. When the fuse element opens in such a manner, the fuse module 754 must be removed and replaced to restore affected circuitry.
A variety of different types of fuse elements, or fuse element assemblies, are known and may be utilized in the fuse module 754 with considerable performance variations in use. Also, the fuse module 754 may include fuse state indication features, a variety of which are known in the art, to identify the permanent opening of the primary fuse element such that the fuse module 754 can be quickly identified for replacement via a visual change in appearance when viewed from the exterior of the fuse module housing 756. Such fuse state indication features may involve secondary fuse links or elements electrically connected in parallel with the primary fuse element in the fuse module 754.
A conductive line side fuse clip 760 may be situated within the disconnect housing 752 and may receive one of the terminal blades 758 of the fuse module 754. A conductive load side fuse clip 762 may also be situated within the disconnect housing 752 and may receive the other of the fuse terminal blades 758. The line side fuse clip 760 may be electrically connected to a first line side terminal 764 provided in the disconnect housing 752, and the first line side terminal 764 may include a stationary switch contact 766. The load side fuse clip 762 may be electrically connected to a load side connection terminal 768. In the example shown, the load side connection terminal 768 is a box lug terminal operable with a screw 770 to clamp or release an end of a connecting wire to establish electrical connection with load side electrical circuitry. Other types of load side connection terminals are known, however, and may be provided in alternative embodiments.
A rotary switch actuator 772 is further provided in the disconnect housing 752, and is mechanically coupled to an actuator link 774 that, in turn, is coupled to a sliding actuator bar 776. The actuator bar 776 carries a pair of switch contacts 778 and 780. In an exemplary embodiment, the switch actuator 772, the link 774 and the actuator bar 778 may be fabricated from nonconductive materials such as plastic. A second conductive line side terminal 782 including a stationary contact 784 is also provided, and a line side connecting terminal 785 is also provided in the disconnect housing 752. In the example shown, the line side connection terminal 785 is a box lug terminal operable with a screw 786 to clamp or release an end of a connecting wire to establish electrical connection with line side electrical circuitry. Other types of line side connection terminals are known, however, and may be provided in alternative embodiments. While in the illustrated embodiment the line side connecting terminal 785 and the load side connecting terminal 768 are of the same type (i.e., both are box lug terminals), it is contemplated that different types of connection terminals could be provided on the line and load sides of the disconnect housing 752 if desired.
Electrical connection of the device 750 to power supply circuitry, sometimes referred to as the line side, may be accomplished in a known manner using the line side connecting terminal 785. Likewise, electrical connection to load side circuitry may be accomplished in a known manner using the load side connecting terminal 768. As mentioned previously, a variety of connecting techniques are known (e.g., spring clamp terminals and the like) and may alternatively be utilized to provide a number of different options to make the electrical connections in the field. The configuration of the connecting terminals 784 and 768 accordingly are exemplary only.
In the position shown in
Specifically, and referring again to
Disconnect switching to temporarily open the current path in the device may be accomplished in multiple ways. First, and as shown in
When the circuit path in the device 750 is opened in such a manner via rotational displacement of the switch actuator 772, the fuse module 754 becomes electrically disconnected from the first line side terminal 782 and the associated line side connecting terminal 785. In other words, an open circuit is established between the line side connecting terminal 785 and the first terminal blade 758 of the fuse module 754 that is received in the line side fuse clip 760. The operation of switch actuator 772 and the displacement of the sliding bar 776 to separate the contacts 780 and 778 from the stationary contacts 784 and 766 may be assisted with bias elements such as the springs described in embodiments above with similar benefits. Particularly, the sliding bar 776 may be biased toward the open position wherein the switch contacts 780 and 778 are separated from the contacts 784 and 786 by a predetermined distance. The dual switch contacts 784 and 766 mitigate electrical arcing concerns as the switch contacts 784 and 766 are engaged and disengaged.
Once the switch actuator 772 of the disconnect device 750 is switched open to interrupt the current path in the device 750 and disconnect the fuse module 754, the current path in the device 750 may be closed to once again complete the circuit path through the fuse module 754 by rotating the switch actuator 772 in the opposite direction indicated by arrow C in
Additionally, the fuse module 754 may be simply plugged into the fuse clips 760, 762 or extracted therefrom to install or remove the fuse module 754 from the disconnect housing 752. The fuse housing 756 projects from the disconnect housing 752 and is open and accessible from an exterior of the disconnect housing 752 so that a person simply can grasp the fuse housing 756 by hand and pull or lift the fuse module 754 in the direction of arrow B to disengage the fuse terminal blades 758 from the line and load side fuse clips 760 and 762 until the fuse module 754 is completely released from the disconnect housing 752. An open circuit is established between the line and load side fuse clips 760 and 762 when the terminal blades 758 of the fuse module 754 are removed as the fuse module 754 is released, and the circuit path between the fuse clips 760 and 762 is completed when the fuse terminal blades 758 are engaged in the fuse clips 760 and 762 when the fuse module 754 is installed. Thus, via insertion and removal of the fuse module 754, the circuit path through the device 750 can be opened or closed apart from the position of the switch contacts as described above.
Of course, the primary fuse element in the fuse module 754 provides still another mode of opening the current path through the device 750 when the fuse module is installed in response to actual current conditions flowing through the fuse element. As noted above, however, if the primary fuse element in the fuse module 754 opens, it does so permanently and the only way to restore the complete current path through the device 750 is to replace the fuse module 754 with another one having a non-opened fuse element. As such, and for discussion purposes, the opening of the fuse element in the fuse module 754 is permanent in the sense that the fuse module 750 cannot be reset to once again complete the current path through the device. Mere removal of the fuse module 754, and also displacement of the switch actuator 772 as described, are in contrast considered to be temporary events and are resettable to easily complete the current path and restore full operation of the affected circuitry by once again installing the fuse module 754 and/or closing the switch contacts.
The fuse module 754, or a replacement fuse module, can be conveniently and safely grasped by hand via the fuse module housing 756 and moved toward the switch housing 752 to engage the fuse terminal blades 758 to the line and load side fuse clips 760 and 762. The fuse terminal blades 758 are extendable through openings in the disconnect housing 752 to connect the fuse terminal blades 758 to the fuse clips 760 and 762. To remove the fuse module 754, the fuse module housing 756 can be grasped by hand and pulled from the disconnect housing 752 until the fuse module is completely released. As such, the fuse module 754 having the terminal blades 758 may be rather simply and easily plugged into the disconnect housing 752 and the fuse clips 760, 762, or unplugged as desired.
Such plug-in connection and removal of the fuse module 754 advantageously facilitates quick and convenient installation and removal of the fuse module 754 without requiring separately supplied fuse carrier elements and without requiring tools or fasteners common to other known fusible disconnect devices. Also, the fuse terminal blades 758 extend through and outwardly project from a common side of the fuse module body 756, and in the example shown the terminal blades 758 each extend outwardly from a lower side of the fuse housing 756 that faces the disconnect housing 752 as the fuse module 754 is mated to the disconnect housing 752.
In the exemplary embodiment shown, the fuse terminal blades 758 extending from the fuse module body 756 are generally aligned with one another and extend in respective spaced-apart parallel planes. It is recognized, however, that the terminal blades 758 in various other embodiments may be staggered or offset from one another, need not extend in parallel planes, and can be differently dimensioned or shaped. The shape, dimension, and relative orientation of the terminal blades 758, and the receiving fuse clips 760 and 762 in the disconnect housing 752 may serve as fuse rejection features that only allow compatible fuses to be used with the disconnect housing 752. In any event, because the terminal blades 758 project away from the lower side of the fuse housing 756, a person's hand when handling the fuse module housing 756 for plug in installation (or removal) is physically isolated from the terminal blades 758 and the conductive line and load side fuse clips 760 and 762 that receive the terminal blades 758 as mechanical and electrical connections therebetween are made and broken. The fuse module 754 is therefore touch safe (i.e., may be safely handled by hand to install and remove the fuse module 754 without risk of electrical shock).
The disconnect device 750 is rather compact and occupies a reduced amount of space in an electrical power distribution system including the line side circuitry 790 and the load side circuitry 794, than other known fusible disconnect devices and arrangements providing similar effect. In the embodiment illustrated in
In another embodiment, the device 750 may be configured for panel mounting by replacing the line side terminal 785, for example, with a panel mounting clip. When so provided, the device 750 can easily occupy less space in a fusible panelboard assembly, for example, than conventional in-line fuse and circuit breaker combinations. In particular, CUBEFuse™ power fuse modules occupy a smaller area, sometimes referred to as a footprint, in the panel assembly than non-rectangular fuses having comparable ratings and interruption capabilities. Reductions in the size of panelboards are therefore possible, with increased interruption capabilities.
In ordinary use, the circuit path or current path through the device 750 is preferably connected and disconnected at the switch contacts 784, 780, 778, 766 rather than at the fuse clips 760 and 762. By doing so, electrical arcing that may occur when connecting/disconnecting the circuit path may be contained at a location away from the fuse clips 760 and 762 to provide additional safety for persons installing, removing, or replacing fuses. By opening the switch contacts with the switch actuator 772 before installing or removing the fuse module 754, any risk posed by electrical arcing or energized conductors at the fuse and disconnect housing interface is eliminated. The disconnect device 750 is accordingly believed to be safer to use than many known fused disconnect switches.
The disconnect switching device 750 includes still further features, however, that improve the safety of the device 750 in the event that a person attempts to remove the fuse module 754 without first operating the actuator 772 to disconnect the circuit through the fuse module 754, and also to ensure that the fuse module 754 is compatible with the remainder of the device 750. That is, features are provided to ensure that the rating of the fuse module 754 is compatible with the rating of the conductive components in the disconnect housing 752.
As shown in
In the exemplary embodiment shown in
In contemplated embodiments, the base of the device 750 (i.e., the disconnect housing 752 and the conductive components therein) has a rating that is ½ of the rating of the fuse module 754. Thus, for example, a base having a current rating of 20 A may preferably be used with a fuse module 754 having a rating of 40 A. Ideally, however, fuse rejection features such as those described above would prevent a fuse module of a higher rating, such as 60 A, from being installed in the base. The fuse rejection features in the disconnect housing 752 and/or the fuse module 754 can be strategically coordinated to allow a fuse of a lower rating (e.g., a fuse module having a current rating of 20 A) to be installed, but to reject fuses having higher current ratings (e.g., 60 A and above in the example being discussed). It can therefore be practically ensured that problematic combinations of fuse modules and bases will not occur. While exemplary ratings are discussed above, they are provided for the sake of illustration rather than limitation. A variety of fuse ratings and base ratings are possible, and the base rating and the fuse module rating may vary in different embodiments and in some embodiments the base rating and the fuse module rating may be the same.
As a further enhancement, the disconnect housing 752 includes an interlock element 806 that frustrates any effort to remove the fuse module 754 while the circuit path through the first and second line terminals 782 and 764 via the switch contacts 784, 780, 778, 766 is closed. The exemplary interlock element 806 shown includes an interlock shaft 808 at a leading edge thereof, and in the locked position shown in
The interlock element 806 is coordinated with the switch actuator 772 so that the interlock element 806 is moved to an unlocked position wherein the first fuse terminal blade 758 is released for removal from the fuse clip 760 as the switch actuator 772 is manipulated to open the device 750. More specifically, a pivotally mounted actuator arm 810 is provided in the disconnect housing 752 at a distance from the switch actuator 772, and a first generally linear mechanical link 812 interconnects the switch actuator 772 with the arm 810. The pivot points of the switch actuator 772 and the arm 810 are nearly aligned in the example shown in
A second generally linear mechanical link 814 is also provided that interconnects the pivot arm 810 and a portion of the interlock element 806. As the arm 810 is rotated in the direction of arrow E, the link 814 is simultaneously displaced and pulls the interlock element 806 in the direction of arrow F, causing the projecting shaft 808 to become disengaged from the first terminal blade 758 and unlocking the interlock element 806. When so unlocked, the fuse module 754 can then be freely removed from the fuse clips 760 and 762 by lifting on the fuse module housing 756 in the direction of arrow B. The fuse module 754, or perhaps a replacement fuse module 754, can accordingly be freely installed by plugging the terminal blades 758 into the respective fuse clips 760 and 762.
As the switch actuator 772 is moved back in the direction of arrow C to close the disconnect device 750, the first link 812 causes the pivot arm 810 to rotate in the direction of arrow G, causing the second link 814 to push the interlock element 806 in the direction of arrow H until the projecting shaft 808 of the interlock element 806 again passes through the opening of the first terminal blade 758 and assumes a locked position with the first terminal blade 758. As such, and because of the arrangement of the arm 810 and the links 812 and 814, the interlock element 806 is slidably movable within the disconnect housing 752 between locked and unlocked positions. This slidable movement of the interlock element 806 occurs in a substantially linear and axial direction within the disconnect housing 752 in the directions of arrow F and H in
In the example shown, the axial sliding movement of the interlock element 806 is generally perpendicular to the axial sliding movement of the actuator bar 766 that carries the switchable contacts 778 and 780. In the plane of
The interlock element 806 may be fabricated from a nonconductive material such as plastic according to known techniques, and may be formed into various shapes, including but not limited to the shape depicted in
The pivot arm 810 is further coordinated with a tripping element 820 for automatic operation of the device 750 to open the switch contacts 778, 780. That is, the pivot arm 810, in combination a tripping element actuator described below, and also in combination with the linkage 774, 812, and 814 define a tripping mechanism to force the switch contacts 778, 780 to open independently from the action of any person. Operation of the tripping mechanism is fully automatic, as described below, in response to actual circuit conditions, as opposed to the manual operation of the switch actuator 772 described above. Further, the tripping mechanism is multifunctional as described below to not only open the switch contacts, but to also to displace the switch actuator 772 and the interlock element 806 to their opened and unlocked positions, respectively. The pivot arm 810 and associated linkage may be fabricated from relatively lightweight nonconductive materials such as plastic.
In the example shown in
In the example shown in
It is therefore seen that a single pivot arm 810 and the linkage 812 and 814 mechanically couples the switch actuator 772 and the interlock element 806 during normal operation of the device, and also mechanically couples the switch actuator 772 and the interlock element 806 to the tripping element 820 for automatic operation of the device. In the exemplary embodiment shown, an end of the link 774 connecting the switch actuator 772 and the sliding bar 776 that carries the switch contacts 778, 780 is coupled to the switch actuator 772 at approximately a common location as the end of the link 812, thereby ensuring that when the tripping element 820 operates to pivot the arm 810, the link 812 provides a dynamic force to the switch actuator 772 and the link 774 to ensure an efficient separation of the contacts 778 and 780 with a reduced amount of mechanical force than may otherwise be necessary. The tripping element actuator 820 engages the pivot arm 810 at a good distance from the pivot point of the arm 810 when mounted, and the resultant mechanical leverage provides sufficient mechanical force to overcome the static equilibrium of the mechanism when the switch contacts are in the opened or closed position. A compact and economical, yet highly effective tripping mechanism is therefore provided. Once the tripping mechanism operates, it may be quickly and easily reset by moving the switch actuator 772 back to the closed position that closes the switch contacts.
Suitable solenoids are commercially available for use as the tripping actuator element 820. Exemplary solenoids include LEDEX® Box Frame Solenoid Size B17M of Johnson Electric Group (www.ledex.com) and ZHO-0520L/S Open Frame Solenoids of Zohnen Electric Appliances (www.zonhen.com). In different embodiments, the solenoid 820 may be configured to push the arm 810 and cause it to rotate, or to pull the contact arm 810 and cause it to rotate. That is, the tripping mechanism can be operated to cause the switch contacts to open with a pushing action on the pivot arm 810 as described above, or with a pulling action on the pivot arm 810. Likewise, the solenoid could operate on elements other than the pivot arm 810 if desired, and more than one solenoid could be provided to achieve different effects.
In still other embodiments, it is contemplated that actuator elements other than a solenoid may suitably serve as a tripping element actuator to achieve similar effects with the same or different mechanical linkage to provide comparable tripping mechanisms with similar benefits to varying degrees. Further, while simultaneous actuation of the components described is beneficial, simultaneous activation of the interlock element 806 and the sliding bar 776 carrying the switch contacts 778, 780 may be considered optional in some embodiments and these components could accordingly be independently actuated and separately operable if desired. Different types of actuator could be provided for different elements.
Moreover, while in the embodiment shown, the trip mechanism is entirely contained within the disconnect housing 752 while still providing a relatively small package size. It is recognized, however, that in other embodiments the tripping mechanism may in whole or in part reside outside the disconnect housing 752, such as in separately provided modules that may be joined to the disconnect housing 752. As such, in some embodiments, the trip mechanism could be, at least in part, considered an optional add-on feature provided in a module to be used with the disconnect housing 752. Specifically, the trip element actuator and linkage in a separately provided module may be mechanically linked to the switch actuator 772, the pivot arm 810 and/or the sliding bar 776 of the disconnect housing 752 to provide comparable functionality to that described above, albeit at greater cost and with a larger overall package size.
The tripping element 820 and associated mechanism may further be coordinated with a detection element and control circuitry, described further below, to automatically move the switch contacts 778, 780 to the opened position when predetermined electrical conditions occur. In one exemplary embodiment, the second line terminal 782 is provided with an in-line detection element 830 that is monitored by control circuitry 850 described below. As such, actual electrical conditions can be detected and monitored in real time and the tripping element 820 can be intelligently operated to open the circuit path in a proactive manner independent of operation of the fuse module 754 itself and/or any manual displacement of the switch actuator 772. That is, by sensing, detecting and monitoring electrical conditions in the line terminal 782 with the detection element 830, the switch contacts 778, 780 can be automatically opened with the tripping element 820 in response to predetermined electrical conditions that are potentially problematic for either of the fuse module 754 or the base assembly (i.e., the disconnect housing 752 and its components).
In particular, the control circuitry 850 may open the switch contacts in response to conditions that may otherwise, if allowed to continue, cause the primary fuse element in the fuse module 754 to permanently open and interrupt the electrical circuit path between the fuse terminals 758. Such monitoring and control may effectively prevent the fuse module 754 from opening altogether in certain conditions, and accordingly save it from having to be replaced, as well as providing notification to electrical system operators of potential problems in the electrical power distribution system. Beneficially, if permanent opening of the fuse is avoided via proactive management of the tripping mechanism, the device 750 becomes, for practical purposes, a generally resettable device that may in many instances avoid any need to locate a replacement fuse module, which may or may not be readily available if needed, and allow a much quicker restoration of the circuitry than may otherwise be possible if the fuse module 754 has to be replaced. It is recognized, however, that if certain circuit conditions were to occur, permanent opening of the fuse 754 may be unavoidable.
As shown in
The terminals 782 and 764 shown in
As shown in
The second board 856 is sometimes referred to as a processing board. In the exemplary embodiment shown, the processing board 856 includes a processor-based microcontroller including a processor 862 and a memory storage 864 wherein executable instructions, commands, and control algorithms, as well as other data and information required to satisfactorily operate the disconnect device 750 are stored. The memory 864 of the processor-based device may be, for example, a random access memory (RAM), and other forms of memory used in conjunction with RAM memory, including but not limited to flash memory (FLASH), programmable read only memory (PROM), and electronically erasable programmable read only memory (EEPROM).
As used herein, the term “processor-based” microcontroller shall refer not only to controller devices including a processor or microprocessor as shown, but also to other equivalent elements such as microcomputers, programmable logic controllers, reduced instruction set (RISC) circuits, application specific integrated circuits and other programmable circuits, logic circuits, equivalents thereof, and any other circuit or processor capable of executing the functions described below. The processor-based devices listed above are exemplary only, and are thus not intended to limit in any way the definition and/or meaning of the term “processor-based”.
While the circuitry 850 is shown in
The detecting element 830 senses the line side current path in the first line terminal 830 and provides an input to the processing board 856. Thus, the control circuitry 850, by virtue of the detecting element 830, is provided with real time information regarding current passing through the line terminal 782. The detected current is then monitored and compared to a baseline current condition, such as a time-current curve as further explained below, that is programmed into the circuitry (e.g., stored in the memory 864). By comparing the detected current with the baseline current, decisions can be made by the processor 862, for example, to operate a trip mechanism 866 such as the tripping element actuator 820 and related linkage described above in response to predetermined electrical conditions as further described below.
As shown in
As also shown in
The remote signal device 880 may be especially useful for coordinating different loads that may be connected to the control circuitry. In one such example, the load 794 may include a motor and a separately powered fan provided to cool the motor in use. If the device 750 is connected in series with the motor but not the fan, and if the device 750 operates to open the switch contacts to the motor, the signal device 880 can be used to switch the fan off. Likewise, if the fan ceases to operate, a signal can be sent with the remote signal device 880 to open the switch contacts in the device 750 and disconnect the motor in the load circuitry 794.
As further shown in
While multiple fuses are plotted in the example of
It can be seen from the exemplary time-current curves of
By virtue of the detection element 830 providing a control input signal, the control circuitry 850 can compare not only the magnitude of actual current flowing through the device 750 (and hence flowing through the fuse module 754) at any given point in time, but can measure the duration of the current flow in order to make control decisions. That is, the control circuitry 850 is configured to make time-based and magnitude-based decisions by comparing elapsed duration of actual current conditions (i.e., actual levels of current) to the predetermined time-current curve expectation for the fuse in use with the device 750. Based on the magnitude and time duration of detected electrical current conditions, the control circuitry 850 can intelligently monitor and control operation of the device 750 in response to current conditions actually detected before the fuse module 754 permanently opens.
For example, default rules can be implemented with the processor 862 to determine one or more time-based and magnitude-based tripping points causing the circuitry 850 to operate the tripping mechanism 866 in response to detected electrical current conditions. In one exemplary scenario, if detected current conditions reach 150% of the rated current of the fuse module 754 actually used in the device 750 for a predetermined amount of time, which may be a predetermined percentage of the time indicated in the time-current curve at the detected current level, the trip mechanism may be actuated. As such, the trip mechanism 866 may be actuated in anticipation of the fuse module 754 opening. Alternatively, stated, the control circuitry 850 may open the switch contacts with the tripping mechanism 866, based on the time-current curve as compared to detected current durations, in less time than the fuse module 754 would otherwise take to operate and open the circuit through the device 750. The tripping of the mechanism 866 under such circumstances, which can be indicated with the indicator 870, may serve as a prompt to troubleshoot the electrical system to determine the cause of the overcurrent, if possible. Once the device 750 is tripped in such a fashion, the fuse module 754 may or may not need to be replaced, depending on how close the tripping points are to the actual opening points of the fuse based on the applicable time-current curve.
Likewise, tripping points can be set at a point higher than the time-current curve may otherwise indicate to ensure that the switch contacts in the device 750 are opened in the event that a fuse module 754 withstands a given current level for a duration longer than would be expected from the time-current curve. Thus, considering the exemplary time-current curve for the 40 A rated fuse in
In accordance with the foregoing examples, the control circuitry 850 can respond to threshold deviations between actual detected current and the baseline current from the time-current curve, either directly or indirectly utilizing tripping points offset from the time-current curve. By monitoring time and current conditions, and by comparing actual current conditions to the time-current curve, and also with some strategic selection of the threshold tripping points, the control circuitry 850 can be tailored to different sensitivities for different applications, and may even detect unusual or unexpected operating conditions and accordingly trip the device 750 to prevent any associated damage to the load side circuitry 794.
Of course, the comparison of detected time and current parameters to the predetermined time-current curve can confirm also an unremarkable or normal operating state of the fuse 754 and the device 750. For example, a 40 A rated fuse could operate at a 40 A current level or below indefinitely without opening, and the control circuitry 850 would in such circumstances take no action to operate the trip mechanism 866.
Having now described the control circuitry 850 functionally, it is believed those in the art could implement the functionality described with appropriate circuitry and appropriately programmed operating algorithms without further explanation.
Unlike the device 750, the device 900 has a different detecting element 902. That is, the shunt element 830 is replaced with another and different type of detecting element 902 in the form of a Hall Effect sensor. As shown in
As still another option, and as also shown in
While the control circuitry 850 described is responsive to current sensing using resistive shunts, Hall Effect sensors or current transformers providing control inputs to the circuitry 850, similar functionality could be provided using sensor or detection elements corresponding to other electrical circuit conditions. For example, because voltage and current are linearly related, voltage sensing inputs could be used and current values could be readily calculated therefrom for use by the control circuitry 850. Still further, voltage sensors could be used to make time-based and magnitude-based comparisons in a similar manner to those described above without first having to calculate current values. In such embodiments, time-current curves and data sets may be omitted in favor of other baseline curves or data sets, which may or may not be conversions of time-current curves, that may be used to directly or indirectly set time-based and magnitude-based threshold tripping points. As such, tripping points utilized by the control circuitry need not be derived from time-current curves, but can be established in light of other considerations for specific end uses or to meet different specifications.
The advantages and benefits of the invention are now believed to have been amply demonstrated in the exemplary embodiments disclosed.
An embodiment of a fusible switch disconnect device has been disclosed including: a disconnect housing adapted to receive and engage at least a portion of a removable electrical fuse, the fuse including first and second terminal elements and a fusible element electrically connected therebetween, the fusible element defining a circuit path and being configured to permanently open the circuit path in response to predetermined electrical current conditions experienced in the circuit path; line side and load side terminals in the disconnect housing and electrically connecting to the respective first and second terminal elements of the fuse when the fuse is received and engaged with the disconnect housing; at least one switchable contact in the disconnect housing, the at least one switchable contact provided between one of the line side terminal and load side terminal and a corresponding one of the first and second terminal elements of the fuse, the at least one switchable contact selectively positionable in an open position and a closed position to respectively connect or disconnect an electrical connection between the line side terminal and the load side terminal and through the circuit path of the fusible element; and a mechanism contained within the disconnect housing, the mechanism operable to automatically cause the at least one switchable contact to move to the open position upon an occurrence of a predetermined threshold operating condition.
Optionally, the fusible switch disconnect device of claim 1 may further include a detecting element configured to detect the occurrence of the predetermined threshold operating condition. A microcontroller may be provided in communication with the detection element and may cause the mechanism to move the switchable contact in response to the occurrence of the predetermined threshold operating condition. The microcontroller may be configured to compare an actual electrical condition as detected with the detection element to a baseline operating condition, and when the compared electrical condition deviates from the baseline electrical condition by a predetermined threshold, the microcontroller may operate the mechanism to move to the open position. The baseline operating condition may include a time-current curve.
The mechanism may include optionally a solenoid, and the solenoid may be responsive to the microcontroller and cause displacement of the switchable contact from the closed position. A first pivotally mounted actuator arm may be provided in the fusible switch disconnect device proximate the solenoid, and the solenoid may displace the actuator arm when activated by the microcontroller. A movable element may further be provided carrying the switchable contact, and a first link may be provided and connect the first actuator arm and the movable element. The movable element may include a slidable element movable along a linear axis within the disconnect housing to position the switchable contact between the open and closed position. A rotatably mounted switch actuator may be provided in the fusible switch disconnect device and may be accessible from an exterior of the disconnect housing, and a second link may further be provided and may connect the switch actuator with the first actuator arm. A fuse terminal interlock element may further be provided in the fusible switch disconnect device, and a third link may be provided and may connect the terminal interlock element to the first actuator arm.
The detecting element in the fusible switch disconnect device may be configured to monitor current flow through the closed switchable contact. The detecting element may be one of a Hall Effect sensor, a current transformer, and a shunt. The detecting element may monitor a current path in the disconnect device at a location between the at least one switchable contact and one of the line and load side terminals. The at least one switchable contact may optionally include a pair of movable contacts, and the movable contacts may be biased to an open position.
The fuse may optionally a rectangular fuse module having plug-in terminal blades engageable with the disconnect housing. The fuse may be directly receivable and engageable with the disconnect housing without utilizing a separately provided fuse carrier. The electrical condition may include one of a voltage condition and a current condition. The detecting element may be configured to monitor one of an undervoltage condition and an overvoltage condition.
The mechanism in the fusible switch disconnect device may include an electromagnetic coil having a cylinder extendable or retractable along an axis of the coil. A rotatable arm may be positioned proximate the electromagnetic coil and may be displaced when the cylinder is extended or retracted. A rotatably mounted switch actuator and mechanical linkage may be provided and may interconnect the rotatable arm and the switch actuator, wherein the switch actuator and the rotatable arm may be simultaneously rotated by extension or retraction of the cylinder. A movable terminal interlock element may optionally be provided in the disconnect housing, the interlock element independently provided from the rotatable arm, and mechanical linkage may interconnect the rotatable arm and the terminal interlock element, wherein the terminal interlock element and the rotatable arm may be simultaneously displaced by extension or retraction of the cylinder. In one embodiment, the fusible switch disconnect device of claim 22 may include: a rotatably mounted switch actuator in the disconnect housing at a location spaced from the rotatable arm; a movable terminal interlock element in the disconnect housing at a location spaced from each of the switch actuator and the switch actuator; a sliding bar carrying the at least one switchable contact; and mechanical linkage interconnecting the rotatable arm, the switch actuator, the terminal interlock element and the sliding bar; whereby the rotatable arm, the switch actuator, the terminal interlock element and the sliding bar are simultaneously displaced by extension and retraction of the cylinder.
The mechanism in the fusible switch disconnect device may include an actuator arm and the device further include at least one of a rotatably mounted switch actuator, a sliding bar carrying the at least one switchable contact, and a terminal interlock element; wherein displacement of the actuator arm simultaneously displaces the at least one of the rotatably mounted switch actuator, the sliding bar carrying the at least one switchable contact, and the terminal interlock element. The mechanism may include an actuator causing displacement of the actuator arm. The actuator may be an electromagnetic coil.
An embodiment of a fusible switch disconnect device has been disclosed including: a disconnect housing adapted to receive and engage at least a portion of a removable electrical fuse, the fuse including first and second terminal elements and a fusible element electrically connected therebetween, the fusible element defining a circuit path and being configured to permanently open the circuit path in response to predetermined electrical current conditions experienced in the circuit path; line side and load side terminals in the disconnect housing and electrically connecting to the respective first and second terminal elements of the fuse when the fuse is received and engaged with the disconnect housing; at least one switchable contact in the disconnect housing, the at least one switchable contact provided between one of the line side terminal and load side terminal and a corresponding one of the first and second terminal elements of the fuse, the at least one switchable contact selectively positionable in an open position and a closed position to respectively connect or disconnect an electrical connection between the line side terminal and the load side terminal and through the circuit path of the fusible element; and a mechanism including an electromagnetic coil operable to automatically cause the at least one switchable contact to move to the open position in response to a predetermined electrical condition when the line side terminal is connected to energized line circuitry.
The coil may include a plunger that is extendable and retractable along an axis of the coil. A pivotally mounted actuator arm may be provided, and the plunger may cause the pivotally mounted actuator arm to pivot when the plunger is extended or retracted. A sliding bar may carry the at least one switchable contact along a linear axis, with the linear axis extending substantially perpendicular to the axis of the coil. An interlock arm movable along a linear axis within the disconnect housing, with the linear axis of the interlock element extending substantially parallel to the axis of the coil. A detecting element and control circuitry may optionally be provided and configured to perform a time-based and magnitude-based comparison of a detected electrical parameter with predetermined time-based and magnitude-based parameters. The predetermined time-based and magnitude-based parameters may include a time-current curve corresponding to the electrical fuse. A rotatably mounted switch actuator and mechanical linkage may cause the switch actuator to rotate when the plunger is extended or retracted. A sliding bar may carrying the at least one switchable contact, and the mechanical linkage may further cause the sliding bar to move when the plunger is extended or retracted. A fuse interlock element may also be provided, and the mechanical linkage may further cause the fuse interlock element to move when the plunger is extended or retracted.
The mechanism may be entirely contained in the disconnect housing. The at least one switchable contact may include first and second switchable contacts simultaneously movable along a linear axis. The electrical fuse may include a rectangular fuse module having plug-in terminal blades, and the linear axis extends generally parallel to a longitudinal axis of the plug-in terminal blades. The electrical fuse may include a rectangular fuse module having plug-in terminal blades, and the coil may include a plunger extendable and retractable along an axis of the coil, wherein the axis of the coil extends generally perpendicular to a longitudinal axis of the plug-in terminal blades. The mechanism may also include at least one element slidable along a linear axis and at least one rotational element, the slidable element and the rotational element mechanically positionable with the coil and collectively causing the at least one switch contact to move to the open position.
Another embodiment of a fusible switch disconnect device has been disclosed including: a housing configured to receive a removable overcurrent protection fuse; terminals establishing a circuit path through the housing, the circuit path being completed by the fuse when the fuse is received; switch contacts positionable relative to one another to open and close a portion of the circuit path; and an electromagnetic coil operable to cause the switch contacts to separate in response to a predetermined electrical condition.
Optionally, a processor-based control element may be provided in communication with the electromagnetic coil, and the processor-based control element may be configured to undertake a time-based and magnitude-based comparison of the sensed electrical condition in the current path and a predetermined time-based and magnitude-based electrical condition baseline, and in response to the result of the comparison, decide whether to cause the switch contacts to operate. The predetermined electrical condition may be a current condition. A detecting element may be configured to sense current in the circuit path. The electrical condition baseline comprises a set of current magnitude values and time values for each current magnitude level. The set of current magnitude values and time values may be derived from a time-current curve for the overcurrent protection fuse.
While the invention has been described in terms of various specific embodiments, those skilled in the art will recognize that the invention can be practiced with modification within the spirit and scope of the claims.
This application is a continuation in part application of U.S. application Ser. No. 12/277,051 filed Nov. 24, 2008 and entitled Fusible Switching Disconnect Modules and Devices, which is a divisional application of U.S. application Ser. No. 11/274,003 filed Nov. 15, 2005 and now issued U.S. Pat. No. 7,474,194 entitled Fusible Switching Disconnect Modules and Devices, which is a continuation-in-part application of U.S. application Ser. No. 11/222,628 filed Sep. 9, 2005 and now issued U.S. Pat. No. 7,495,540 entitled Fusible Switching Disconnect Modules and Devices, which claims the benefit of U.S. Provisional Application Ser. No. 60/609,431 filed Sep. 13, 2004, the disclosures of which are hereby incorporated herein by reference in their entirety. This application also relates to subject matter disclosed in U.S. patent application Ser. No. ______, filed herewith and entitled Electronically Controlled Fusible Switching Disconnect Modules and Devices; U.S. patent application Ser. No. ______, filed herewith and entitled Fusible Switching Disconnect Modules and Devices With In-Line Current Detection; and U.S. patent application Ser. No. ______, filed herewith and entitled Fusible Switching Disconnect Modules and Devices with Multi-Functional Trip Mechanism.
Number | Date | Country | |
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60609431 | Sep 2004 | US |
Number | Date | Country | |
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Parent | 11274003 | Nov 2005 | US |
Child | 12277051 | US |
Number | Date | Country | |
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Parent | 12277051 | Nov 2008 | US |
Child | 13008988 | US | |
Parent | 11222628 | Sep 2005 | US |
Child | 11274003 | US |