Abstract:
This invention relates to a high ampere-rated circuit breaker which meets the electrical code requirements of the world market. The charging of the powerful operating springs controlling the circuit breaker contacts is made automatically by means of an electric motor. The circuit breaker operating handle connects with the operating springs through a motor operator interface unit to allow manual charging of the operating springs upon stalling of the electric motor.

Description:
BACKGROUND OF THE INVENTION 
     U.S. Pat. No. 4,001,742 entitled &#34;Circuit Breaker Having Improved Operating Mechanism&#34; describes a circuit breaker capable of interrupting several thousand amperes of circuit current at several hundred volts potential. As described therein, the operating mechanism is in the form of a pair of powerful operating springs that are restrained from separating the circuit breaker contacts by means of a latching system. Once the operating mechanism has responded to separate the contacts, the operating springs must be recharged to supply sufficient motive force to the movable contact arms that carry the contacts. 
     U.S. patent application Ser. No. 08/202,140 filed Feb. 25, 1994 entitled &#34;Operating Mechanism for High Ampere-Rated Circuit breaker&#34; describes an operating mechanism capable of immediately resetting the circuit breaker operating mechanism to reclose the contacts without having to recharge the circuit breaker operating springs immediately after opening the circuit breaker contacts. 
     U.S. patent application Ser. No. 08/203,062 filed Feb. 28, 1994 entitled &#34;Rating Module for High Ampere-Rated Circuit Breaker&#34; describes a circuit breaker closing spring modular unit whereby the circuit breaker operating springs are contained within a separate unit from the operating mechanism and can be installed within the circuit breaker enclosure without disturbing the operating mechanism assembly. 
     U.S. patent application Ser. No. 08/214,522 filed Mar. 18, 1994 entitled &#34;Handle Operator Assembly for High Ampere-Rated Circuit Breaker&#34; describes a handle operator unit capable of generating large spring charging forces by means of an externally-accessible manually operated handle. A ratchet and pawl assembly allows the manually-applied charging forces to be applied to the operating springs. Once the circuit breaker operating mechanism closing springs are fully-charged, some means must be employed to release the pawl to allow the closing springs to become fully operational 
     U.S. Pat. No. 4,649,244 describes the use of an electric motor to automatically charge the circuit breaker closing springs. The motor connects with the closing spring shaft through a planetary gear assembly and a complex cam arrangement. 
     The present invention describes a simplified arrangement for interfacing between the electric motor and the circuit breaker closing springs charging assembly with less components and at a lower cost. 
     SUMMARY OF THE INVENTION 
     The circuit breaker operating mechanism closing springs are charged both automatically by means of an electric motor as well as manually by means of an externally accessible operating handle. A friction clutch arrangement allows the circuit breaker closing springs to be manually charged by operation of the operating handle. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a top perspective view of a high ampere-rated circuit breaker with a portion of the circuit breaker cover removed to depict the operating springs motor operator interface unit according to the invention; 
     FIG. 2 is an end view in partial section of the motor operator interface unit of FIG. 1; 
     FIG. 3 is an enlarged top perspective view of the motor operator interface unit of FIG. 1 with the components in isometric projection; 
     FIG. 4 is an enlarged side view of the motor operator interface unit of FIG. 1 at the start of the charging cycle; 
     FIG. 5 is an enlarged side view of the motor operator interface unit of FIG. 1 during the charging cycle; and 
     FIG. 6 is an enlarged side view of the motor operator interface unit of FIG. 1 at the close of the charging cycle. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
     The high ampere-rated circuit breaker 10 shown in FIG. 1 is capable of transferring several thousand amperes quiescent circuit current at several hundred volts potential without overheating. The Circuit breaker consists of an electrically insulated base 11 to which an intermediate cover 12 of similar insulative material is attached prior to attaching the top cover 13, also consisting of an electrically-insulative material. Electrical connection with the interior current-carrying components is made by load terminal straps 14 extending from one side of the base and line terminal straps (not shown) extending from the opposite side thereof. The interior components are controlled by an electronic trip unit contained within a recess 16 on the top surface of the top cover 13. Although not shown herein, the trip unit is similar to that described within U.S. Pat. No. 2,581,181 and interacts further with an accessory contained within the accessory recess 15 to provide a range of protection and control functions such as described, for example within U.S. Pat. No. 4,801,907. The operating mechanism 17 as described within the aforementioned U.S. patent application Ser. No. 8/203,062 includes the means required to charge the powerful closing springs 21 through a motor operator interface unit 20 which includes a clutch assembly 23. Manual forces to charge the closing springs are provided through operation of the operating handle 18 arranged within the handle recess 19. 
     The circuit breaker 10 is shown in FIG. 2 to depict the location of the handle 18 relative to the handle closing shaft 26 within the operating mechanism 17. The drive shaft 24 which operates to open the circuit breaker contacts is biased by means of a separate pair of operating springs 25 as described within the aforementioned U.S. Pat. No. 4,001,742. The closing shaft 26 which connects with the closing springs 21 by means of the closing crank 30 also connects with the motor operator interface unit 20 by means of a pivot sleeve 34. The automatic operation of the motor operator interface under the operation of the electric motor 58 as well as by manual operation of the operating handle 18 to charge the closing springs 21 is best seen by referring to both FIGS. 2 and 3 at the same time. The operator interface unit 20 consists of a pair of closing shaft links 31, 32 which attach the unit to the closing shaft by means of the shaped apertures 43. The pivot sleeve 34 is accurately positioned within the unit by capture of the positioning tabs 39, 40 extending from opposite ends of the sleeve within corresponding slots 41, 42 formed within the closing shaft links. A pair of motor drive plates 35, 36 are positioned over the pivot sleeve 34 by insertion of the sleeve within the clearance openings 44 formed within one end of each of the motor drive plates and the clearance opening 51 formed within the motor operator interface unit support plate 50. In accordance with the teachings of the invention, a friction clutch 37 is sandwiched between the motor drive plates and interacts with the clutch drive pin 33 extending between the drive plates by means of the triangular slot 45 in the manner to be described below. The elongated drive link 54 which is attached to the drive plates by means of the drive link pivot 55 interacts with bell crank 56 by means of the drive link post 57 extending from the end of the drive link. The drive link 54 is broken to depict the positioning track 47 formed within the mounting plate 50 which track receives the clutch positioning pin 46 extending from one end of the friction clutch 37. The positioning pin is driven within the positioning track in cam-follower relation along the ramped edge 48 and the narrow end 49 thereof. The bell crank 56 is attached to a pulley 63 for rotation about the bell crank and pulley pivot 64. The assembled motor operator unit is completely contained and supported on the mounting plate 50 which is attached to the closing spring sideframe 53 by means of a pair of thru-holes 52 and associated screws 67 (FIG. 4). When assembled thereto, the motor drive shaft 60 (FIG. 4) extends through the opening 59 formed in the mounting plate 50 and a pulley 62 attached to the motor shaft operatively interacts with the motor operator interface unit 20 by means of the drive belt 61 and the motor operator interface unit pulley 63. 
     The operation of the motor operator interface unit 20 is shown in FIG. 4 with the motor drive pulley 62 on the motor shaft 60 on the electric motor 58 connected with the pulley 63 attached to the bell crank 56 on the bell crank pivot and pulley pivot 64 by means of the drive belt 61. The mounting plate 50 is attached to the closing spring sideframe by means of screws 67 above the drive shaft 24. Although the connection between the pulleys 62, 63 by means of the drive belt 61 is simple and economically advantageous, other more costly means of connection such as planetary gears can also be employed. One of the motor drive plates 35, and one of the closing shaft links 31, is removed to depict the location of the other motor drive plate 36 on the closing shaft 26 and the location Of the clutch drive pin 33 at the end of the other closing shaft link 32 relative to the V-shaped slot 45 at one end of the friction clutch 37. It is noted that the clutch release spring 65 biases the friction clutch slot 45, at the one end the friction clutch 37, away from the clutch drive pin 33, and the clutch position pin 46, at the other end of the friction clutch 37, within the narrow dwell region 49 of the positioning track slot 47 formed in the mounting plate 50 at the start of the closing spring charging cycle. The drive link 54 that connects between the motor drive plates and the bell crank 56 on the pulley 63 by means of the drive link post 57 effectively controls the transfer of charging force from the motor drive shaft 60 to the closing shaft 26 via the bell crank pivot 64 in the manner to be described below. 
     With the electric motor 58 operational, the bell crank 56 is rotated counter-clockwise about the bell crank and pulley pivot 64 moving the drive link 54, motor drive plate 36 and the friction clutch 37 in the clockwise direction and forcing the friction clutch slot 45 against the clutch drive pin 33 against the bias of the clutch release spring 65. The clutch position pin 46 remains within the narrow dwell region of the positioning track slot 47. The friction generated between the friction clutch slot 45 and the clutch drive pin 33 holds the motor operator interface unit in the condition depicted in FIG. 5 allowing the motor 58 to deliver charging force to the closing shaft 26 and from there to the closing springs, as described earlier. 
     Should the motor stall during the charging cycle, the friction generated between the friction clutch slot 45 and the clutch drive pin 33 ceases as soon as manual force is applied to the handle thereby allowing the friction clutch 37 to rotate in the clockwise direction away from the clutch drive pin under the urgence of the clutch release spring 65. When operating-power is supplied by the handle, the drive link 54 rotates the bell crank 56 clockwise about the bell crank and pulley pivot 64 and the clutch positioning pin 46 is against the positioning ramp 48 within the positioning track slot 47. Upon completion of the charging of the closing springs, the motor operator interface unit 20 returns to the starting configuration shown earlier in FIG. 4.