1. Field
The disclosed and claimed concept relates generally to circuit interrupters and, more particularly, to an improved tool and calibration machine employed in calibrating a thermal trip apparatus of a circuit interrupter.
2. Related Art
Numerous types of circuit interrupters are known for use in diverse applications. One type of a circuit interrupter is a circuit breaker having an operating mechanism that moves the circuit breaker between an ON condition, an OFF condition, and a TRIPPED condition. Such circuit breakers typically also include a trip mechanism that causes the operating mechanism to move the circuit breaker from the ON condition to the TRIPPED condition. The trip mechanism can include any one or more of a variety of components that can trigger the operating mechanism to open a set of separable contacts in any of a variety of overcurrent and under-voltage conditions. One type of known component of a trip mechanism is a thermal trip apparatus which includes a bimetal element that becomes heated in a persistent overcurrent condition and accordingly trips the circuit breaker.
While such thermal trip apparatuses have been generally effective for their intended purposes, they have not been without limitation. As is generally understood in the relevant art, a bimetal element deflects in a predetermined fashion upon heating. However, due to manufacturing variations and tolerances, the thermal trip apparatus of any given circuit breaker must be calibrated during the manufacturing process. That is, each circuit breaker's thermal trip apparatus is adjusted so that it causes the circuit breaker to trip in response to a predetermined persistent overcurrent condition, by way of example. In certain circuit breakers, the calibration process has involved an inelastic (i.e., plastic) deformation of a frame within the circuit breaker upon which the bimetal element is carried. Such an inelastic deformation occurs by receiving a rectangular-shaped object into an interior region of the circuit breaker and rotating the rectangular-shaped object to engage and inelastically deform the frame until the bimetal element has moved sufficiently that it is calibrated to trigger the operating mechanism at a predetermined current level.
However, if the frame has been deformed beyond the calibration point, the deformation of the frame cannot be reversed without substantial reworking of the circuit breaker, with the result that an unacceptably high number of rejected circuit breakers must be discarded because they were over-deformed during the calibration operating and cannot be easily calibrated thereafter. It thus would be desirable to provide an improved system for calibrating a thermal trip apparatus of a circuit interrupter.
An improved calibration machine for calibrating a thermal trip apparatus of a circuit interrupter employs a tool having an elongated shank and a pair of engagement elements. The engagement elements are engageable with a support that carried a bimetal element. The engagement elements can deform the support in opposite directions to either increase or decrease the thermal trip setting of the thermal trip apparatus. If the support is over-deformed in one direction, it can be deformed in an opposite direction to enable a circuit interrupter whose thermal trip apparatus has been deformed beyond a target thermal calibration setting to be deformed in an opposite direction to reach the target thermal calibration setting.
Accordingly, an aspect of the disclosed and claimed concept is to provide an improved calibration machine that employs an improved tool to perform a calibration operation on a thermal trip apparatus of a circuit interrupter.
Another aspect of the disclosed and claimed concept is to provide an improved method of performing such a calibration operation.
Another aspect of the disclosed and claimed concept is to provide an improved circuit breaker having components including a thermal trip apparatus that are capable of calibration through an inelastic deformation of a support in either of two directions and that permits the support to be returned to a calibration setting even after the support has been inelastically deformed beyond the calibration setting.
These and other aspects of the disclosed and claimed concept are provided by an improved method of employing a tool in calibrating a thermal trip apparatus of a circuit interrupter. The thermal trip apparatus can be generally stated as including a thermal trip element and a support upon which the thermal trip element is disposed. The tool has an elongated shank and at least a first engagement element extending from the shank in a direction generally perpendicular to the direction of elongation of the shank. The method can be generally stated as including detecting a thermal calibration setting of the thermal trip apparatus, engaging the thermal trip apparatus with the tool, deforming the support by applying one of a compressive force and a tensile force to the shank when the thermal calibration setting is higher than a target thermal calibration setting, and deforming the support by applying the other of a compressive force and a tensile force to the shank when the thermal calibration setting is lower than the target thermal calibration setting.
Other aspects of the disclosed and claimed concept are provided by an improved calibration machine that is structured to calibrate a thermal trip apparatus of a circuit interrupter. The thermal trip apparatus can be generally stated as including a thermal trip element and a support upon which the thermal trip element is disposed. The calibration machine can be generally stated as including a processor apparatus, an input apparatus connected, and an output apparatus. The processor apparatus can be generally stated as including a processor and a memory. The input apparatus is connected with the processor apparatus and can be generally stated as including at least a first sensor structured to detect a thermal calibration setting of the thermal trip apparatus. The output apparatus is connected with the processor apparatus and can be generally stated as including an actuator and a tool, the actuator being connected with the processor apparatus and with the tool, the tool having an elongated shank and having at least a first engagement element extending from the shank in a direction generally perpendicular to the direction of elongation of the shank. The memory has stored therein a number of routines which, when executed on the processor, cause the calibration machine to perform operations that can be generally stated as including detecting a thermal calibration setting of the thermal trip apparatus, engaging the thermal trip apparatus with the tool, deforming the support by applying one of a compressive force and a tensile force to the shank when the thermal calibration setting is higher than a target thermal calibration setting, and deforming the support by applying the other of a compressive force and a tensile force to the shank when the thermal calibration setting is lower than the target thermal calibration setting.
A further understanding of the disclosed and claimed concept can be gained from the following Description when read in conjunction with the accompanying drawings in which:
Similar numerals refer to similar parts throughout the specification.
An improved tool 4 is depicted in
As can further be understood from
The input apparatus 36 includes at least one sensor 54 that is configured to detect a thermal trip setting of the circuit interrupter 12. By way of example, the sensor 52 may be configured to detect the level of current flow over time in the circuit interrupter 12 and to further detect a point at which the circuit interrupter 12 experiences a thermal trip, at which point current typically ceases to flow. The sensor 54 in conjunction with one or more of the routines 52 can thus be said to detect a thermal trip setting of the circuit interrupter 12. Other input devices may be employed in the input apparatus 36 without departing from the present concept.
The output apparatus 40 of the depicted exemplary embodiment includes an actuator 56 which physically moves the tool 4 in a number of predetermined fashions. The actuator 56 is schematically depicted in
As can be understood from
The circuit interrupter 12 further includes a pair of separable contacts that include a movable contact 64 connected with the line terminal 60 and a stationary contact 68 connected with the load terminal 62. The circuit interrupter 12 is depicted in
In particular, the trip mechanism 74 advantageously includes an improved thermal trip apparatus 76 that is depicted at least in part in
As can further be understood from
As can be understood from
As can further be seen from
The calibration operation can be stated to generally begin with the tool 4 being situated at the exterior of the circuit interrupter 12, as is indicated generally in
The portion of the tool 4 that includes the engagement elements 20A and 20B is translated by the actuator 56 to be received through the opening 92 until the engagement elements 20A and 20B are situated generally between the first conductor 88 and the support 82. In such position, the tool 4 can be rotated by the actuator 56 about the direction of elongation of the shank 16, if needed. That is, depending upon the orientation in which the tool 4 was received through the opening 92, such as with the engagement elements 20A and 20B being disposed above and below one another as is indicated generally in
In such an orientation, a compressive force can be applied by the actuator 56 to the shank 16 to cause the engagement elements 20A and 20B to engage the first surface 96, as is indicated generally in
On the other hand, if the calibration routine 52 determines that the thermal trip setting of the thermal trip apparatus 76 is too high, the actuator 56 can pivot the tool 4 about the direction of elongation of the shank 16, as needed, to align the engagement elements 20A and 20B with the hole 94 formed in the thermal trip apparatus 76. The shank 16 can then be translated by the actuator 56 to receive that portion of the tool 4 through the hole 94. The tool 4 can thereafter be pivoted by the actuator 56 about the direction of elongation of the shank 16 through an angle of about ninety degrees and can thereafter apply a tensile force to the shank 16 to cause the engagement elements 20A and 20B to engage the second surface 98, as is indicated generally in
While the deformations of the support 82 through engagement of the tool 4 with the support 82 (by operation of the actuator 56) causes inelastic, i.e., plastic, deformation of the support 82 which changes the thermal trip setting of the thermal trip apparatus 76, it can be understood that such deformation can be reversed by applying a deformation force to the support 82 in an opposite direction. That is, if the support 82 is deformed as is indicated generally in
It thus can be seen that the advantageous configuration of the thermal trip apparatus 76 and the circuit interrupter 12 enable the calibration machine 8 and the tool 4 to adjust and readjust the thermal trip setting of the circuit interrupter 12 without the need to heavily rework the circuit interrupter 12 and without the need to discard circuit interrupters that have been deformed past the target thermal calibration setting. Advantageously, therefore, the circuit interrupter 12 is relatively less expensive to manufacture than previously known circuit breakers due to the avoidance of waste in the manufacturing process. Other advantages will be apparent to those of ordinary skill in the art.
An improved method in accordance with another aspect of the disclosed and claimed concept is depicted with a flowchart in
Processing then continues, as at 110, where the tool 4 is engaged with the thermal trip apparatus 76. Processing can then be said to continue, as at 114, with the deforming of the support 82 by applying a compressive force to the shank 16 when the thermal calibration setting is one of higher and lower than the target thermal calibration setting, and, as at 118, deforming the support 82 by applying a tensile force to the shank 16 when the thermal calibration setting is the other of higher and lower than the thermal calibration setting. In the exemplary embodiment set forth herein, the compressive force is applied to the shank 16 when the thermal trip setting is lower than the target thermal calibration setting, and the distal engagement surfaces 24A and 24B are engaged with the support 82. Similarly, the tensile force is applied to the shank 16 when the thermal calibration setting is higher than the target thermal calibration setting and the proximal engagement surfaces 28A and 28B are engaged with the second surface 98 of the thermal trip apparatus 76. It is reiterated that if the deformation of the support 82 causes the thermal trip apparatus to be over-calibrated, i.e., too high or too low in comparison with the target thermal calibration setting, the support 82 can simply be deformed in the opposite direction to reverse the over-calibration of the thermal trip apparatus 76, which avoids having to reject and discard circuit interrupters as was done using previously known methodologies.
The improved calibration machine 8 with its improved tool 4 thus can be used to calibrate the thermal trip apparatus 76 of the circuit interrupter 12. Such calibration can be done efficiently and rapidly and without the need to discard circuit breakers that have been over-calibrated and cannot be brought back into calibration. Other advantages will be apparent to those of ordinary skill in the art.
While specific embodiments of the disclosed concept have been described in detail, it will be appreciated by those skilled in the art that various modifications and alternatives to those details could be developed in light of the overall teachings of the disclosure. Accordingly, the particular arrangements disclosed are meant to be illustrative only and not limiting as to the scope of the disclosed concept which is to be given the full breadth of the claims appended and any and all equivalents thereof.