Pursuant to 35 U.S.C. § 119(a), this application claims the benefit of earlier filing date and right of priority to Korean Application No. 10-2016-0184409, filed on Dec. 30, 2016, the contents of which are incorporated by reference herein in its entirety.
The present invention relates to a molded-case circuit breaker for direct current (DC), and more particularly, to a molded-case circuit breaker for DC that contains an internal connecting conductor connecting adjacent terminals to improve insulation performance and assemblability and reduce occupied space.
2. Description of the Conventional Art
In general, a molded-case circuit breaker (MCCB) is an electrical device that protects a circuit and a load by automatically interrupting the circuit when there is an electrical overload or short circuit. The circuit breaker includes a terminal portion provided on the front and rear and forming a circuit connection, a mechanism divided into a fixed contact and a movable contact and mechanically opening and closing a circuit, a trip portion detecting an over-current or short-circuit current in the circuit and causing the mechanism to trip, and an extinguisher for extinguishing an arc produced when interrupting a fault current.
Such a circuit breaker is generally used for alternating current (AC) and may be converted for use in DC applications. In order to convert a circuit breaker for AC to one for DC, in the conventional art, connecting conductors (also referred to as “externally connected conductors or common bus bars”) may be added to the terminal portion of the existing circuit breaker to configure and use circuits in series.
A molded-case circuit breaker for DC according to the conventional art will now be described. A molded-case circuit breaker including an even number of poles (units) and a molded-case circuit breaker including an odd number of poles (units) will be discussed separately.
First of all, a molded-case circuit breaker with an even number of poles (e.g., four poles) will be described.
As is generally known, a molded-case circuit breaker for AC according to the conventional art includes a switch mechanism 3, a contact portion 7, a trip portion 5, and a terminal portion 2a, 2b, 2c, 2d, 2e, 2f, 2g, and 2h which is placed within an outer casing consisting of a case 1a and a cover 1b. Other internal components than the switch mechanism 3 are provided for each phase (unit). That is, in the four-unit circuit breaker, these components are provided for each of four phases: R phase, S phase, T phase, and N phase. The terminal portion 2a, 2b, 2c, 2d, 2e, 2f, 2g, and 2h includes a front terminal portion 2a, 2b, 2c, and 2d on the front of the circuit breaker and a rear terminal portion 2e, 2f, 2g, and 2h on the rear of the circuit breaker. For better comprehension, each unit will be described with respect to the R phase, S phase, T phase, and N phase of a circuit breaker for AC). A power source and a load may be connected to the rear terminal portion 2e, 2f, 2g, and 2h.
In order to use the circuit breaker for DC applications, externally connected conductors 4a and 4b are attached to the rear terminal portion 2e, 2f, 2g, and 2h and the front terminal portion 2a, 2b, 2c, and 2d.
Referring mainly to
Next, a molded-case circuit breaker with an odd number of poles (e.g., three poles) will be described.
In the three-phase (three-unit) circuit breaker, three phases: R phase, S phase, T phase are provided. I-shaped externally connected conductors 4b are provided at the T-phase rear terminals 2f, 2g, and 2h (on the power source side) and the R-phase front terminal 2b (on the load side). A U-shaped externally connected conductor 4a is provided at the S-phase and T-phase front terminals 2c and 2d to connect them together. The I-shaped externally connected conductors 4b are optionally mounted in order to ensure consistency with the externally connected conductor 4a in terms of the arrangement of terminals or the amount of current carried. If the I-shaped externally connected conductors 4b are omitted, the power source or load may be connected directly to the terminal portion 2b, 2c, 2d, 2f, 2g, and 2h.
When the above circuit breaker with an odd number of poles is connected in series, the input and output are not easily distinguishable in terms of position. That is, both poles 9a and 9b of the power source and one pole, i.e., the minus pole 8b in this case, of the load are aligned in the same direction. In other words, both poles 8a and 8b of the load are arranged respectively on the front and rear of the outer casing 1. Thus, an externally connected conductor, i.e., a connecting conductor 4c, is mounted to the outside of the outer casing 1 (see
Since the DC circuit breaker according to the conventional art requires an U-shaped externally connected conductor 4a or a connecting conductor 4c on the outside of the outer casing 1, additional user operation is needed. Moreover, the conductive connection structure exposed out of the outer casing 1 may cause a possible insulation breakdown and take up more space. Additionally, even when adjacent phases (poles) are integrally connected by a U-shaped externally connected conductor, two tripping mechanisms (trip portions) still exist, and this redundancy leads to a waste of components.
The present invention has been made in an effort to solve the above-described problems, and an aspect of the present invention is to provide a molded-case circuit breaker for DC that contains an internal connecting conductor connecting adjacent terminals to improve insulation performance and assemblability and reduce occupied space.
An exemplary embodiment of the present invention provides a molded-case circuit breaker for DC that contains a plurality of interruption units within an outer casing, the DC circuit breaker including a two-unit connecting heater that connects fixed contacts of adjacent interruption units, the two-unit connecting heater being placed within the outer casing.
The two-unit connecting heater may be formed in a U-shape, and may include: a pair of head portions respectively connected to the fixed contacts of the adjacent interruption units; a pair of body portions extending downward from the head portions; and a leg portion connecting the pair of body portions.
The head portions and the leg portion may be horizontal planes, and the body portions may be vertical planes.
One of the pair of body portions may have a tripping mechanism that detects an over-current in a circuit and interrupts the circuit.
Front terminal receiving portions and rear terminal receiving portions may be provided on the front and rear of the outer casing, and insulation covers may be provided to close the front terminal receiving portions or the rear terminal receiving portions.
A trip portion case for receiving the two-unit connecting heater and the tripping mechanism may be placed within the outer casing, and a trip portion insulation cover may be provided on the front of the trip portion case.
Assembly holes may be formed in the leg portion so as to couple with the trip portion case.
The trip portion case may have a partition for insulation between the interruption units, and a cut groove may be formed on a part of the partition to insert the leg portion.
The DC circuit breaker may further include a connecting conductor, one end of which is connected to a rear terminal of an interruption unit on one side, and the other end of which is mounted in the front terminal receiving portion of the interruption unit on one side, with the connecting conductor being mounted within the outer casing.
The connecting conductor may include: a first terminal attached to the rear terminal of the interruption unit on one side; a second terminal mounted in the front terminal receiving portion of the interruption unit on one side; and a connecting portion connecting the first terminal and the second terminal.
The outer casing may include: a box-shaped case with the top and part of the front and rear being open; and a cover attached to the top of the case, wherein the case may have a first protrusion protruding from the bottom of one sidewall, the first protrusion may have a first receiving slot formed along the length, the cover may have a second protrusion protruding out from one sidewall, and the second protrusion may have a second receiving slot formed along the length to communicate with the first receiving slot, with the connecting conductor being inserted into the first and second receiving slots.
An extension may extend downward along the outer wall of the second protrusion, and the extension may have such a length at which it can adjoin the first protrusion.
The second protrusion may have the same width as the first protrusion.
A cut groove may be formed on one sidewall of the case to insert part of the connecting conductor.
According to a molded-case circuit breaker for DC according to an embodiment of the present invention, a U-shaped two-unit connecting heater is provided to connect a pair of adjacent units and therefore no front terminals and no externally connected conductors are required. Accordingly, the user does not need to add more connecting conductors, and the assemblability of the power source and load is improved.
Moreover, external insulation breakdown is prevented since a connecting conductor is configured within the outer casing. In addition, no front terminal portion is needed, thus improving insulation performance and reducing occupied space.
Further, the number of tripping mechanisms can be reduced, thus leading to a reduction in parts and production cost.
According to a molded-case circuit breaker for DC according to another embodiment of the present invention, the circuit breaker has a connecting conductor within it, the power source terminals and the load terminals are configured on the front and rear of the DC circuit breaker in an easily distinguishable manner. Thus, the user does not need to add more connecting conductors, and the assemblability of the power source and load is improved.
Moreover, external insulation breakdown is prevented since the connecting conductor is configured within the outer casing. In addition, part of the terminal portion is eliminated, thus enhancing insulation from the outside.
Further, unlike a heater provided at the R phase, a U-shaped, two-unit connecting heater is provided at the S phase and the T phase to directly connect them, and therefore the number of tripping mechanisms can be reduced, thus leading to a reduction in parts and production cost.
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate exemplary embodiments and together with the description serve to explain the principles of the invention.
In the drawings:
While the invention has been shown and described with respect to the preferred embodiments, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention as defined in the following claims.
A molded-case circuit breaker for DC according to embodiments of the present invention will be described in detail with reference to the drawings.
A molded-case circuit breaker for DC with a plurality of interruption units according to an embodiment of the present invention includes: a two-unit connecting heater 41 that connects fixed contacts 33b of adjacent interruption units, with the two-unit connecting heater 41 being placed within an outer casing of the circuit breaker.
A molded-case circuit breaker for DC according to an embodiment of the present invention includes a plurality of interruption units. The interruption units correspond to interruption units applied to respective phases (poles) of a molded-case circuit breaker for AC. Therefore, for better comprehension, a four-unit molded-case circuit breaker will be described with respect to the R phase, S phase, T phase, and N phase. A DC four-unit circuit breaker 10 according to an embodiment of the present invention includes a case 11 and a cover 18 that constitute an outer casing, a switch mechanism 30 (see
The case 11 forms the bottom of the outer casing. The case 11 may have the approximate shape of a box with its top and part of its front and rear being open. The base assembly 35 is accommodated in the internal space of the case 11. Since the four-unit circuit breaker has a four-unit circuit of the R phase, S phase, T phase, and N phase, it contains four base assemblies 35. The case 11 may be divided into four segments.
The cover 18 is attached to the top of the case 11. The top side of the cover 18 is partially open, with a top cover 19 mounted on it. A handle 31 of the switch mechanism 30 is exposed through a hole at the center of the top cover 19, thereby allowing the user to manually apply an actuating force to it.
The front terminal receiving portions 12 may be covered with insulation covers 26. As the front terminal receiving portions 12 have no terminals mounted in them, they are covered with the insulation covers 26, thus improving insulation performance.
In the rear terminal receiving portions 13, terminals of the respective phases are mounted and exposed. That is, an N phase terminal 36a, an R phase terminal 36b, an S phase terminal 36c, and a T phase terminal 36d are provided in terminal receiving portions of the respective phases, respectively.
An insulation barrier 25 may be provided between each externally connected conductor 20. The insulation barrier 25 improves insulation between each phase.
The base assembly 35 and the trip portion assembly 40 will be described with reference to
The movable contacts 34 are mounted on a shaft 37 and rotate with the shaft 37. Each shaft 37 is connected by a shaft pin 38 and all the shafts 37 rotate together, thereby causing the contact portions of the four units to open and close simultaneously. The switch mechanism 30 is mounted on the base assembly 35 of a certain phase, typically, the S phase base assembly, and transfers actuating force to the shaft pin 38 that is attached to a part of the switch mechanism 30. The operations of the movable contacts and switch mechanism 30 are identical to those in the conventional art, so any further detailed descriptions of them will be omitted.
The trip portion assembly 40 is mounted on the front of the base assembly 35. The trip portion assembly 40 detects an over-current flow in a circuit and interrupts it, and may include a trip portion case 45, a two-unit connecting heater 41 connected to a pair of adjacent front fixed contacts, bimetal 42 that can be bent by heat, a crossbar 43 that is rotated by the bimetal 42, and a chute 44 that rotates when released from the crossbar 43 to strike a nail 32 of the switch mechanism 30 and allow the switch mechanism 30 to perform an off operation.
The crossbar 43 may have a plurality of contact regions 43a and 43c that protrude to make contact with the bimetal 42. Each contact region may be formed at only one of two adjacent phases. For example, the first contact region 43a is provided at one of the S and T phases, and the second contact region 43c is provided at one of the N and R phases. That is, no contact region may be provided at the other of the S and T phases and the other of the N and R phases.
A tripping mechanism is common to two adjacent phases. For example, a tripping mechanism may be provided for a pair of interruption units connecting the N phase and the R phase and also for a pair of interruption units connecting the S phase and the T phase.
The trip portion case 45 has a partition 45a for insulation between each phase (unit). The partition 45a may be made from a double wall to improve insulation performance. A cut groove 45b may be formed by partially cutting away the bottom of the partition 45a. A leg portion 41c of the two-unit connecting heater 41 may be inserted into the cut groove 45b.
A trip portion insulation cover 54 is provided on the front of the trip portion case 45. The trip portion insulation cover 54 may be formed to completely close the front of the trip portion case 45. Insulation performance can be improved because the trip portion is insulated by the trip portion insulation cover 54. Insulation performance can be greatly improved because the front terminal receiving portions 12 each have a double wall that is formed by an insulation cover 26 and the trip portion insulation cover 54.
Referring further to
The two-unit connecting heater 41 may include a pair of head portions 41a connectable to a pair of adjacent front fixed contacts 33b, a pair of body portions 41b extending downward from the head portions 41a, and a leg portion 41c connecting the pair of body portions 41b. The head portions 41a and the leg portion 41c may be horizontal planes, and the body portions 41b may be vertical planes. The body portions 41b may be partially bent so as to keep a certain distance from the tripping mechanism. Center holes 41d and 41e may be formed in the regions of contact between the head portions 41a and the body portions 41b and the regions of contact between the body portions 41b and the leg portion 41c, in order to improve strength and facilitate the formation of bends. Also, assembly holes 41f may be formed in the leg portion 41c so as to couple with the trip portion.
A pair of adjacent phases (e.g., the S phase and the T phase) are connected by the two-unit connecting heater 41, and it means that two phases may be covered by one heater. Moreover, the two-unit connecting heater 41 serves as a current-carrying path. Therefore, the two-unit connecting heater 41 requires no front terminals (2a, 2b, 2c, and 2d in the conventional art) (compare
Since a pair of adjacent phases are directly connected by the two-unit connecting heater 41, a pair of adjacent terminals and an externally connected conductor connecting them are unnecessary. Thus, there are no components that are exposed out of the front terminal receiving portions 12. Accordingly, insulation performance is improved.
Moreover, since the front terminal receiving portions 12 have no terminals within them and therefore no components are exposed externally, the front terminal receiving portions 12 may be covered by the insulation covers 26. Accordingly, insulation performance is further improved.
In addition, the tripping mechanism 41A (which collectively refers to 42, 46, 47, 48, and 49) is provided on any one of a pair of adjacent phases, thus reducing the number of parts and cutting costs.
A wiring diagram of a four-unit molded-case circuit breaker for DC according to an embodiment of the present invention will be described with reference to
The power source 60a and 60b and the load 70 are connected to the terminals of respective phases provided on the rear of the DC circuit breaker 10. For example, the plus pole 60a of the power source 60a and 60b is connected to the T phase terminal 36a, and the minus pole of the power source 60a and 60b is connected to the N phase terminal 36b on the power source side. Also, the plus pole of the load 70 is connected to the S phase terminal 36c, and the minus pole of the load 70 is connected to the R phase terminal 36b.
To connect a pair of adjacent phases, the two-unit connecting heater 41 is attached to the pair of adjacent front fixed contacts. Since the pair of adjacent phases is connected directly by the two-unit connecting heater 41, no front terminals and no externally connected conductors are required. Also, the two-unit connecting heater 41 is contained within the outer casing of the DC circuit breaker 10, it is closed off from the outside, thus improving insulation performance.
Only one trip mechanism 41A is provided for a pair of adjacent phases (units), but without a heater.
According to a molded-case circuit breaker for DC according to an embodiment of the present invention, a U-shaped two-unit connecting heater is provided to connect a pair of adjacent units and therefore no front terminals and no externally connected conductors are required. Accordingly, the user does not need to add more connecting conductors, and the assemblability of the power source and load is improved.
Moreover, external insulation breakdown is prevented since a connecting conductor is configured within the outer casing. In addition, no front terminal portion is needed, thus improving insulation performance and reducing occupied space.
Further, the number of tripping mechanisms can be reduced, thus leading to a reduction in parts and production cost.
Next, a molded-case circuit breaker with an odd number of poles (three poles) according to a second embodiment will be described. The same components as the foregoing embodiment will be denoted by the same reference numerals.
A DC circuit breaker 10A according to an aspect of the present invention includes a plurality of interruption units, an outer casing with front and rear terminal receiving portions 12 and 13 for each interruption unit provided on the front and rear, and a front terminal 55 and rear terminals 36b, 36c, and 36d for respective phases provided in the front and rear terminal receiving portions 12 and 13, with fixed contacts (not shown) of a unit on one side and an adjacent unit being connected together, and a power source 60 being connected to the rear terminals 36c and 36d of a unit on the other side and an adjacent unit. The DC circuit breaker 10A includes a connecting conductor 50, one end of which is connected to the rear terminal 36b of the unit on one side, and the other end of which is mounted in the front terminal receiving portion 12 of the unit on one side, with the connecting conductor 50 being mounted within the outer casing, and the load 70 being connected to the front terminal 55 of the unit on the other side and the other end of the connecting conductor 50.
A DC circuit breaker 10A according to another aspect of the present invention includes a plurality of interruption units, an outer casing with front and rear terminal receiving portions 12 and 13 for each interruption unit provided on the front and rear, and a front terminal 55 and rear terminals 36b, 36c, and 36d for respective phases provided in the front and rear terminal receiving portions 12 and 13, with fixed contacts (not shown) of a unit on one side and an adjacent unit being connected together, and a power source 60 being connected to the rear terminals 36c and 36d of a unit on the other side and an adjacent unit. The outer casing includes a case 11A with the top, front, and rear being open, and a cover 18A attached to the top of the case 11A, wherein the case 11A has a first protrusion 15 protruding from the bottom of one sidewall 14, the first protrusion 15 has a first receiving slot 16 formed along the length, the cover 18A has a second protrusion 22 protruding out from one sidewall 21, and the second protrusion 22 has a second receiving slot 23 formed along the length to communicate with the first receiving slot 16.
First, reference will be made with respect to
The case 11A forms the bottom of the outer casing. The case 11A may have the approximate shape of a box with its top and part of its front and rear being open. The base assembly 35 is contained in the internal space of the case 11A. Since the three-unit circuit breaker has a three-phase circuit of the R phase, S phase, and T phase, it contains three base assemblies 35. Front terminal receiving portions 12 and rear terminal receiving portions 13 are provided on the front and rear of the case 11A. The front terminal receiving portions 12 and the rear terminal receiving portions 13 provide a space where a front terminal or rear terminal (a load terminal or power source terminal) can be mounted.
One sidewall (e.g., the outer wall of the R phase) 14 protrudes from the bottom and forms the first protrusion 15. The first protrusion 15 may be formed longitudinally along the sidewall 14. The first receiving slot 16 is formed along the length within the first protrusion 15. The connecting conductor 50 may be partially inserted into the first receiving slot 16.
An insertion slot 17 is formed on the front and rear ends of the sidewall 14. The insertion slot 17 communicates with the front terminal receiving portion 12 of the R phase or the rear terminal receiving portion 13 of the R phase.
The cover 18A is attached to the top of the case 11A. The top side of the cover 18A is open at the center, with a top cover 19 mounted to the open part. A handle 31 of the switch mechanism 30 is exposed through a hole at the center of the top cover 19, thereby allowing the user to manually apply an actuating force to it. One sidewall (e.g., the outer wall of the R phase) 21 of the cover 18A may protrude outward, thereby forming a second protrusion 22. The second protrusion 22 has the same width as the first protrusion 15 of the case 11A. The second protrusion 22 has a second receiving slot 23 formed within it that communicates with the first receiving slot 16. The first receiving slot 16 may be longitudinally formed along the length of the cover 18A. The connecting conductor 50 may be partially inserted into the first receiving slot 16.
An extension 24 extends downward along the outer wall of the second protrusion 22. The extension 24 may be referred to as a skirt. The extension 24 has such a length at which it can adjoin the first protrusion 15 of the case 11A. The cover 18A is symmetrical with respect to a vertical cross-section since the second protrusion 22 and the extension 24 are formed on one side of the cover 18A.
The first protrusion 15 is provided on the case 11A, and the second protrusion 22 is provided on the cover 18A. Thus, the connecting conductor 50 is inserted and mounted into the first receiving slot 16 of the first protrusion 15 and the second receiving slot 23 of the second protrusion 22 and therefore not exposed to the outside.
The base assembly 35 and the trip portion assembly 40 will be described with reference to
The movable contacts 34 are mounted on a shaft 37 and rotate with the shaft 37. Each shaft 37 is connected by a shaft pin 38 mounted to pass through the three phases and all the shafts 37 rotate together, thereby causing the contact portions of the three units to open and close simultaneously. The switch mechanism 30 is mounted on the base assembly 35 of a certain phase, typically, the S phase base assembly, and transfers actuating force to the shaft pin 38 that is attached to a part of the switch mechanism 30. The operations of the movable contacts and switch mechanism 30 are identical to those in the conventional art, so any further detailed descriptions of them will be omitted.
The trip portion assembly 40 is mounted on the load side of the base assembly 35. The trip portion assembly 40 interrupts an over-current flow in a circuit, and may include heaters 41 and 46 connected to fixed contacts on the load side, bimetal 42 that can be bent by heat, a crossbar 43 that is rotated by the bimetal 42, and a chute 44 that rotates when released from the crossbar 43 to strike a nail 32 of the switch mechanism 30 and allow the switch mechanism 30 to perform an off operation. In this case, the T-phase trip mechanism may be identical to the conventional trip mechanism. That is, the heater 46 and bimetal 42 of the T phase trip mechanism may be identical to the heater and bimetal according to the conventional art (see
The crossbar 43 has a plurality of contact regions 43a and 43c that protrude to make contact with the bimetal 42. The contact regions may be formed at two phases. For example, the first contact region 43a is provided at the T phase, and the second contact region 43c is provided at the R phase or the S phase. That is, no contact region may be provided at one of the R and S phases.
Referring further to
The S phase and the T phase are connected by the two-unit connecting heater 41, and it means that the two phases may be covered by one heater. Moreover, the two-unit connecting heater 41 serves as a current-carrying path. Since the R phase and the S phase are directly connected by the two-unit connecting heater 41, the two-unit connecting heater 41 has no terminals on the load side. Referring to
Referring further to
Although not listed and depicted separately herein, the connecting conductor 50 may exist in various embodiments. The connecting conductor 50 may be formed in various shapes and placed at appropriate positions within a range in which it comes with a compact design to be contained in the DC circuit breaker 10. For example, the connecting conductor 50 may be placed in a slot formed at the bottom of the case 11A.
The first terminal 51 is attached with a screw to the R phase terminal 36b. The second terminal 52 is inserted and mounted into the R phase front terminal receiving portion 12 through the insertion slot 17 on the sidewall 14 of the case 11A. The second terminal 52 serves as the R phase front terminal (load terminal). The connecting portion 53 is received in the first receiving slot 16 of the first protrusion 15 and the second receiving slot 23 of the second protrusion 22.
Since the connecting conductor 50 is contained and mounted within the outer casing, i.e., the case 11A and the cover 18A, of the DC circuit breaker 10, it is not exposed to the outside, thereby improving insulation performance. Moreover, the presence of the connecting conductor 50 allows for configuring the power source terminals and the load terminals on the front and rear of the DC circuit breaker, respectively, thus making it easy to recognize and use them. That is, a power source connecting terminal portion and a load connecting terminal portion are clearly and distinctively recognizable, and it is easy to connect a load without having to add an externally connected conductor, thereby improving assemblability.
Meanwhile, due to the presence of the two-unit connecting heater 41, an externally connected conductor for connecting load terminals of the R and S phases is unnecessary, and the number of components exposed out of the front terminal receiving portions 12 is reduced. This contributes to improvement in insulation performance.
Referring to
Referring to
Moreover, an insulation barrier 25 may be provided between the R phase and the S phase, thereby ensuring the insulation between the phases.
Referring to
The power source 60 is connected to terminals on the rear of the DC circuit breaker 10A. The power source 60 is connected to the rear terminals of two phases (units) located on the other side of the DC circuit breaker 10A which are farthest from the phase (unit) where the connecting conductor 50 is provided.
In this embodiment, the plus pole of the power source 60 is connected to the T phase rear terminal 36d, and the minus pole of the power source 60 is connected to the S phase rear terminal 36c.
The load 70 is connected to front terminal (load terminal) on the front of the DC circuit breaker 10A. The load 70 is connected to the load terminals of two phases (units) located on both sides of the DC circuit breaker 10A. In this embodiment, the plus pole of the load 70 is connected to the T phase front terminal 55, and the minus pole of the load 70 is connected to the R phase front terminal, i.e., the second terminal 52 of the connecting conductor 50.
An externally connected conductor 20 may be provided at the terminals connected to the power source and load. The externally connected conductor 20 is for providing assemblability to the user and regulating the amount of current carried, and may be optionally used.
Since the connecting conductor 50 and the two-unit connecting heater 41 are contained in the DC circuit breaker 10, insulation performance is greatly improved. The tripping mechanism 41A (which collectively refers to 42, 46, 47, 48, and 49), except the heater, may be provided at one of the two phases connected to the two-unit connecting heater 41. That is, no tripping mechanism is provided at one of the R and S phases.
The R phase- and S phase terminals are eliminated from the front terminals (load terminals). The second terminal 52 of the connecting conductor 50 is substituted for the R phase terminal.
While this embodiment has been described with respect to a three-phase (three-unit) molded case circuit breaker for DC, it is needless to say that the present invention may be applied to a DC circuit breaker with an odd number of phases (units) more than or equal to three phases (units). In this case, it should be noted that the power source (or load) is connected to two adjacent rear terminals on one side, and the load (or power source) is connected to two front terminals on both sides (one of which that is located on the other side is the second terminal of the connecting conductor). For the other terminals, a two-unit connecting heater is used between adjacent terminals.
According to a molded-case circuit breaker for DC according to an embodiment of the present invention, the circuit breaker has a connecting conductor within it, the power source terminals and the load terminals are configured on the front and rear of the DC circuit breaker in an easily distinguishable manner. Thus, the user does not need to add more connecting conductors, and the assemblability of the power source and load is improved.
Moreover, external insulation breakdown is prevented since the connecting conductor is configured within the outer casing. In addition, part of the terminal portion is eliminated, thus enhancing insulation from the outside.
Further, unlike the heater provided at the T phase, a U-shaped, two-unit connecting heater is provided at the R phase and the S phase to directly connect them, and therefore the number of tripping mechanisms can be reduced, thus leading to a reduction in parts and production cost.
As the present features may be embodied in several forms without departing from the characteristics thereof, it should also be understood that the above-described embodiments are not limited by any of the details of the foregoing description, unless otherwise specified, but rather should be construed broadly within its scope as defined in the appended claims, and therefore all changes and modifications that fall within the metes and bounds of the claims, or equivalents of such metes and bounds are therefore intended to be embraced by the appended claims.
Number | Date | Country | Kind |
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10-2016-0184409 | Dec 2016 | KR | national |