The present invention relates generally to contact blocks (auxiliary contacts), overload relays, and other electronic control devices. More specifically, the present invention relates to actuation of multiple electronic control devices by a single mechanical force or actuation, e.g., a mechanical button.
Existing electronic control devices, such as contactors and overload relays, may be engaged or disengaged by electrical or mechanical actuators. Unfortunately, the actuators typically have different actuation distances. For example, a mechanically-actuated contact block may have an actuation distance of 4 mm, while a mechanically-actuated overload relay may have an actuation distance of 11 mm. Accordingly, an existing mechanical actuator may provide a single actuation distance of 4 mm, which is sufficient for the contact block but insufficient for the overload relay. Thus, the existing actuator is incapable of actuating more than one electronic control device, where the actuation distances are different from one another.
For these reasons, a technique is needed for actuating multiple devices having different distances of actuation.
In certain embodiments, a system includes a mechanical actuator having a first member configured to engage a contact block to move a contact slide for a first distance between open and closed positions of an electrical contact pair. The mechanical actuator also has a second member configured to engage an auxiliary device to move an actuator for a second distance between first and second positions, wherein the first and second distances are substantially different from one another.
The foregoing and other advantages and features of the invention will become apparent upon reading the following detailed description and upon reference to the drawings in which:
In the illustrated embodiment, a user may depress a button or generally engage the dual-function operator 12, which simultaneously moves one or more mechanisms to operate contact blocks (e.g., auxiliary contacts) 14 and the overload relay 16. In other words, mechanical engagement of the dual-function operator 12 mechanically resets the overload relay 16 and, also, electrically changes the state of auxiliary devices or status indicators 28a, 28b, 28c, and 28d by mechanically changing the state of the contact pairs 14a/a′, 14b/b′, 14c/c′, and 14d,d′ of the contact block 14. For example, as discussed in further detail below, the dual-function operator 12 is configured to provide mechanical force over a first range of travel (e.g., 4 mm) sufficient to move the contact pairs 14a/a′, 14b/b′, 14c/c′, and 14d/d′ from a normally open position to a closed position or, alternatively, from a normally closed position to an open position. In addition, the dual-function operator 12 is configured to provide mechanical force over a second range of travel (e.g., 11 mm) sufficient to move a button or actuator 29 on the overload relay 16. Although these first and second ranges of travel are different for the contact block 14 and the overload relay 16, the dual-function operator 12 is configured to provide a degree of travel (e.g., 7 mm) during which the contact pairs 14a/a′, 14b/b′, and 14c/c′ are not being moved, yet the button or actuator of the overload relay 16 continued to be moved by the dual-function operator 12. In this manner, the dual-function operator 12 accommodates different ranges of travel of the contact block 14 and the overload relay 16, such that it can simultaneously actuate both the contact block 14 and the overload relay 16 by a single motion or depression of a button. In certain embodiments, the first and second ranges of travel are between about 1 to 8 mm and 5 to 15 mm, respectively. Accordingly, the difference between these first and second ranges of travel can be between 1 to 14 mm, or greater or lesser in other embodiments.
The first or contact block operator 32 includes a variety of mounting structures and mechanisms, which facilitate mounting to external devices, machinery, control units, and so forth. For example, the first or contact block operator 32 includes a housing 37, a mounting flange 38 disposed at the front of the housing 37, and a mounting nut 40 secured to threads 42 adjacent the mounting flange 38. The first or contact block operator 32 can be mounted to a device or panel 44 by inserting the housing 37 through an opening in the panel 44, and then securing the mounting nut 40 to the threads 42. The mounting nut 40 also includes serrations 46 to engage the device or panel 44, thereby resisting retro-threading of the mounting nut 40 away from the surface of the panel 44.
In addition, the first or contact block operator 32 includes mechanisms for mounting with electronic control devices, such as the contact block 30. For example, the housing 37 of the first or contact block operator 32 includes an operator latch recess 48, an operator latch lip 50, and a pair of diametrically opposite guide slots and/or latch slots 52. These mechanisms 48, 50, and 52 are engageable with mating structures on the mounting collar or latch assembly 34, which in turn is coupled to the contact block 30 as discussed in further detail below. Specifically, a mating latch snaps into or latches with the operator latch recess 48 and/or lip 50 on the housing 37 of the first or contact block operator 32. In addition, the mounting collar or latch assembly 34 includes a pair of diametrically opposite guides 56, which extend into the guide slots 52 disposed on the first or contact block operator 32. The snap-fitting or latching of the housing 37 with the mounting collar or latch assembly 34 is further guided by directional indicators or arrow labels 58 and 60, which are disposed on the housing 37 and the mounting collar or latch assembly 34, respectively. When desired, the housing 37 can be released and separated from the mounting collar or latch assembly 34 by pushing a latch actuator 62 (assisted by grips or serrations 64) to rotate the latch assembly 34 relative to the housing 37. As the latch assembly 34 rotates, the mating latch rotates free from the latch recess 48 and the latch lip 50 disposed on the housing 37. The housing 37 can then be pulled free and separated from the latch assembly 34.
The mounting collar or latch assembly 34 is also removeably securable to the contact block 30 by one or more latching members. For example, the mounting collar or latch assembly 34 includes hook or latch members 66, which interlock with mating hook or latch members 68 on the contact block 30. The contact block 30 and latch assembly 34 also may include other latches, snap-fit mechanisms, or fasteners to secure the contact block 30 with the latch assembly 34 after engaging the hook or latch members 66 and 68. Accordingly, the contact block 30 can be attached and detached without the use of any tools by simply snapping together or disengaging the latch assembly 34 by rotating the collar 62. In other embodiments, a variety of latches, snaps, screws, bolts, hooks, adhesives, pins, or other fastening mechanisms can be used to secure the first or contact block operator 32 to the contact block 30.
The contact block 30 may have a variety of electrical and/or mechanical features and connectors as understood by those of skill in the art. In the illustrated embodiment, the contact block 30 includes a plurality of wire or conductor receptacles 70 to enable wires to be coupled to one or more internal electrical contact pairs, which are either normally open or normally closed. The contact block 30 also includes a contact slide assembly 72, which is moveable to change the position of the internal electrical contact pairs from normally open to closed or, alternatively, to move the position of the internal electrical contact pairs from normally closed to open. In the illustrated embodiment, the contact slide assembly 72 is moveable by an internal portion of the first or contact block operator 32 in response to movement or depression of a button or actuator 74 disposed in the mounting flange 38.
As discussed in further detail below, the button or actuator 74 has a range of movement that extends inside the device or panel 44, such that the mounting flange 38 can have a relatively low profile depth 76. For example, the low profile depth 76 may be on the range of 1 to 8 mm, e.g., 4.5 mm. Moreover, the range of movement of the button or actuator 74 can be greater than 4 mm, e.g., 5 to 20 mm, such that the button or actuator 74 substantially moves into and through the device or panel 44. In operation, movement of the button or actuator 74 moves the contact slide assembly 72 within the contact block 30, such that the electrical contact pairs are moved between open and closed positions, or vice versa. For example, the movement of contact slide assembly 72 may be between 1 and 8 mm, e.g., 4 mm. Simultaneously, the movement of the button or actuator 74 moves the threaded shaft 78 as illustrated in
Advantageously, the threaded shaft 78, the lock nut 80, and the cylindrical member or sleeve 82 cooperatively facilitate positional adjustment of a head or second engagement portion 84 of the reset operator 36. In other words, the threaded shaft 78 can be threaded to a greater or lesser extent into the reset operator 36, thereby changing or adjusting the distance of the head or second engagement portion 84 relative to a reference, e.g., the contact block operator 32, an auxiliary device (e.g., overload relay), etc. In this manner, the adjustable distance can accommodate different ranges of movement desired for the head 84 to actuate an auxiliary device, such as an overload relay. The illustrated head 84 also includes ridges or gears 86 to facilitate rotation of the threads 78 into mating threads within the reset operator 32. In alternative embodiments, the housing 37 can include different structures, attachment mechanisms, and so forth.
Turning now to
Inside the second annular structure 92 of reset operator 32, the button 74 also includes internal threads or a threaded hole 106, which threadingly receives the threaded shaft 78 coupled to the head or second engagement portion (e.g., overload relay pusher). At an exterior end 108 of the second annular structure 92, an interior end 110 of the cylindrical member or sleeve 82 engages and abuts against the second annular structure 92. As discussed in detail above, the lock nut 80 may be rotated about the threaded shaft 78 to lock the cylindrical member or sleeve 82 against the second annular structure 92, thereby securing the threaded shaft 78 within the second annular structure 92. Again, the threaded shaft 78 may be threaded into the internal threads or threaded hole 106 of the second annular structure 92 to an adjustable length or distance before securement by the lock nut 80. Therefore, the position of the head or second engagement portion (e.g., overload relay pusher) 84 may be positioned at a desired distance relative to the dual-function reset operator assembly 12, thereby varying the distance of travel for engaging an auxiliary device, e.g. an overload relay.
When the button or actuator 74 is depressed as indicated by arrow 112, the dual-function reset operator assembly 12 begins to move an end or first engagement portion 114 of the first annular structure 90 as indicated by arrows 116. Simultaneously, movement of the button 74 begins to move the head or second engagement portion 84 as indicated by arrow 118. In certain application, this movement 118 of the head or second engagement portion 84 begins to move or actuate an auxiliary device, such as an overload relay, immediately or soon after initial engagement of the button or actuator 74. However, the end or first engagement portion 114 of the first annular structure 90 does not immediately engage the contact slide assembly 72 disposed within the contact block 30. Instead, the dual-function reset operator assembly 12 provides a range of non-actuating travel or pre-travel 120 between the first engagement portion 114 and a tip or mating portion 122 of the contact slide assembly 72. This range of pre-travel 120 is selected to provide additional travel to operate the auxiliary device, e.g. overload relay, by the head or second engagement portion 84.
Upon reaching the tip or mating portion 122 of the contact slide assembly 72, the first engagement portion 114 of the first annular structure 90 pushes the contact slide assembly 72 over a range of travel 124 to change positions or states of one or more contact pairs 126 riding on spanners disposed within the contact slide assembly 72. For example, the movement of the contact slide assembly 72 over the range of travel 124 may change the position of these contact pairs 126 from a normally open position to a closed position or, alternatively, from a normally closed position to an open position.
In addition to actuating the contact block 30, the additional movement over the range of travel 124 also continues to move the head or second engagement portion 84, thereby completing the actuation or operation of the auxiliary device, e.g. the overload relay. Altogether, a single motion or movement of the button 74 causes the first engagement portion 114 to actuate the contact block 30 over the range of travel 124, while also causing the head or second engagement portion 84 to actuate an auxiliary device, e.g. an overload relay, over a total range of travel 128 (e.g., the sum of ranges of travel 120 and 124). In certain embodiments, the auxiliary device may be actuated by less than the full range of travel 128, e.g., a part of the first range of travel 120 and a part of the second range of travel 124. For example, the auxiliary device may be offset by a distance from the head or second engagement portion 84, such that the auxiliary device is actuated by the range of travel 128 minus the offset distance. Other configurations are also within the scope of the present technique.
Upon release of the button or actuator 74, the spring 94 disposed within the first or contact block operator 32 biases the first and second annular structures 90 and 92 and the second or overload operator 36 outwardly toward a normal position having the button or actuator 74 disposed at the mounting flange 38. In addition, as the button or actuator 74 returns to its normal state, a spring within the contact slide assembly 72 biases the contact slide assembly 72 upwardly to its original position. Other spring configurations and return mechanisms are also within the scope of the present technique.
Turning now to
Each device node 152 typically may include a networked sensor or actuator unit, as can be appreciated by those skilled in the art. Depending upon the particular application (e.g., an industrial control system) in which network 150 is installed, nodes 152 may include such devices as push-button switches, proximity sensors, flow sensors, speed sensors, actuating solenoids, overload relays, etc. The nodes 152 can be coupled to network cable 154 in a variety of topologies, including branch drop structures, zero drop connections, short drop connections, and daisy chain arrangements.
As can be appreciated by those skilled in the art, each node 152 can transmit and receive data signals via the data conductors of cable 154 in accordance with various standard protocols. For example, the data conductors can conduct pulsed data signals in which levels of electrical pulses are identified by the nodes as data representative of node addresses and parameter information. Each node device generally is programmed to recognize data signals transmitted over cable 154 that are required for executing a particular node function. Hardware and software of generally known types are provided at sensing nodes for encoding sensed parameters and for transmitting digitized data signals over cable 154 representative of a node address and of a value of the sensed parameters.
Cable 154 also includes power conductors for providing electrical power to nodes 152. For example, the power conductors may form a direct current bus of predetermined voltage, such as 24 VDC. Electrical power is applied to the power conductors by power supply circuits, such as a power supply 160, electrically connected to the power conductors of cable 154 via power taps, such as a power tap 162. The configuration and circuitry for such power supply circuits are generally known in the art. Each power tap 162 may include protective devices, such as fuses, that may be removed from the power taps to isolate a portion of the network if desired.
As illustrated in
While the invention may be susceptible to various modifications and alternative forms, specific embodiments have been shown by way of example in the drawings and have been described in detail herein. However, it should be understood that the invention is not intended to be limited to the particular forms disclosed. Rather, the invention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the following appended claims.