ES2790873T3 - Magnetothermic protection device, thermal protection component and magnetic protection component - Google Patents

Abstract

A magneto-thermal protection apparatus applicable to a multi-pole circuit breaker, wherein the magneto-thermal protection apparatus comprises: a housing comprising an upper casing (101) and a base (112); a multi-pole protection unit (105) installed inside the housing, where: the multi-pole protection unit (105) comprises a plurality of magneto-thermal protection devices (104), each magneto-thermal protection device (104) corresponds to one pole of the circuit breaker of a multi-pole circuit, each magnetothermic protection device (104) is assembled by a thermal protection component (102) and a magnetic protection component (103), the multi-pole protection unit (105) comprises a rod (501), the component Thermal protection (102) comprises a double metal sheet (121), the double metal sheet (121) is bent to an L-shape, a transverse part of the double L-shaped metal sheet (121) is installed directly on a busbar (123), an upper end of a longitudinal part of the double L-shaped sheet metal (121) is a work surface (122), the work surface (122) of the double sheet metal The (121) is an inclined surface, and the magnetic shield component (103) comprises a movable iron core (302), a static iron core (302), a movable iron core bracket (301) to install the movable iron core (302) thereon, a static iron core bracket (305) to install the static iron core (302) thereon, an adjustment bracket (306) arranged on a rotating stem (304 ), and a torsion spring (308), wherein between the static iron core (302) and the movable iron core (302) an air clearance is provided, the air clearance is adjustable, the core angle of Movable iron (301) is rotatably mounted on the static iron core bracket (305) by the rotation stem (304), the adjustment bracket (306) is in contact with the movable iron core bracket (301), The torsion spring (308) fits over the rotation stem (304), one end of the spring d The torsion (308) is fixed on the adjustment bracket (306), the torsion spring (308) applies a fixed internal counter force to the movable iron core bracket (301) through the adjustment bracket (306), The torsion spring (308) also maintains the existing air gap between the movable iron core (302) and the static iron core (302), the magnetic protection component (103) is coupled with the rod (501), the rod (501) is provided with an inclined surface (502), the adjustment bracket (306) is in contact with different positions of the inclined surface (502); an energy storage component (106) installed within the housing, wherein: the energy storage component (106) couples with the thermal protection component (102), and, when an overload current occurs, the energy storage (106) is activated by the thermal protection component (102) and strikes an operating mechanism of the multi-pole circuit breaker, the energy storage component (106) comprises an energy storage rod (602), a double metal adjusting rod (601), energy storage springs (603, 610) and an adjusting screw (604), the double metal adjusting rod (601) comprises a locking rod (601A) and contact rods (601B), in normal operation, the lock rod (601A) and the energy storage rod (602) form a latch, the adjusting screw (604) adjusts a latch amount, each contact rod (601B) is couple With the work surface (122) at an upper end of the double metal sheet (121), in normal operation, each contact rod (601B) is spaced from the work surface (121), when overload occurs, the sheet double metal (122) deforms so that work surface (122) is in contact with each contact rod (601B); an adjustment component (107) mounted on the housing, wherein the adjustment component (107) comprises a mounting bracket (173), a first adjustment rod (171) and a second adjustment rod (172), the first Adjusting rod (171) and second adjusting rod (172) are rotatably mounted on mounting bracket (173), the first adjusting rod (171) is provided with a first adjusting gear (704) in the middle and a conical protrusion (701) at the bottom, at the conical end of the conical protrusion (701) a positioning rod is provided, the positioning rod is inserted into an adjustment groove (601F) of the double metal adjustment rod (601), the second adjusting rod (172) is provided with a second adjusting gear (703) in the middle and a third adjusting gear (702) at the bottom, the third adjusting gear (702) meshes with a gear member (504) on the rod (501), on the square of m On mounting (173) a stepped bracket is provided, both ends of the stepped bracket are tooth-shaped ends, one tooth-shaped end is in contact and meshed with the first adjusting gear (704), the other tooth-shaped end is in contact and meshed with the second adjusting gear (703), when the first adjusting rod (171) or the second adjusting rod (172) rotates, the tooth-shaped ends and adjusting gears allow the first adjusting rod (171) or second adjusting rod (172) rotate in a stepwise fashion one tooth at a time; When the first adjusting rod (171) is rotated, the locating rod of the conical boss (701) is driven to move, and the locating rod urges the double metal adjusting rod (601) to move transversely through the adjustment groove (601E), so that a distance is changed between each contact rod (601B) and the work surface (122) to adjust a scale of the overload current, when the second is rotated adjusting rod (172), the rod (501) is driven to move transversely through the engagement of the third adjusting gear (702) and the gear member (504), changes a contact position between the inclined surface (502) of the rod (501) and the adjustment bracket (306), and through the adjustment bracket (306) a size of the air gap is adjusted between the movable iron core (302) and the static iron core (302 ).

Description

DESCRIPTION

Magnetothermic protection device, thermal protection component and magnetic protection component

Background of the invention

1. Field of the invention

The invention is related to the field of low voltage electrical appliances, and more particularly it is related to a circuit breaker protection apparatus for switching appliances.

2. Related art

A circuit breaker protection device can provide protection against overload current and protection against short circuit current. Protection of a switching apparatus, such as a circuit breaker, is usually controlled by a circuit breaker protection apparatus. The circuit breaker protection apparatus is widely applied to small capacity circuit breakers. For large capacity circuit breakers with rated current greater than 1000A, electronic protection apparatus is usually adopted. According to the electronic protection apparatus, a mutual inductor induces a current in the loop and is monitored by a controller. A magnetic release is used to perform a trigger operation. Magnetothermic protection apparatus is rarely adopted for high capacity circuit breakers with a rated current greater than 1000 A.

However, considering from a perspective of market needs and cost of use, a high cost-performance ratio will be obtained if the magnetothermic protection device can be adopted for high capacity circuit breakers with a rated current greater than 1000 A, and a good application market will be achieved. According to a traditional magnetothermic protection apparatus, a thermal protection component heats a double metal sheet by Foucault heating and thermal deformation is generated. An operating mechanism of the circuit breaker is activated by a force generated by thermal deformation. A magnetic protection component adopts an electromagnet to adjust a counter force of a spring and an air gap, so that the multiple instantaneous action is adjustable. A series of action rods are used to promote firing of the operating mechanism. The traditional thermal protection component of the magneto-thermal protection device adopts eddy heating technology, which is difficult to control. There are a large number of items and the cost advantage is poor. Furthermore, the force generated by the deformation of the double metal sheet is usually small. For a large-capacity circuit breaker operating mechanism, as a large tripping force is required, it is very difficult for the double sheet metal to directly activate the operating mechanism to trip. The traditional magnetic shield component has to adjust a counter force of a spring and an air gap at the same time. In this mode there are two changeable parameters, it is difficult in design calculation and verification. Furthermore, the counter force of the spring is relatively large so that it is inconvenient for a user to adjust the counter force of the spring. Additionally, the number of elements of the magnetic protection tripping component is large, and fast action of the circuit breaker cannot be obtained.

European patent EP 1077460 A2 describes a magneto-thermal protection apparatus, wherein the magneto-thermal protection apparatus is applicable to a multi-pole circuit breaker, the magneto-thermal protection apparatus comprises: a housing (124) comprising an upper casing (106) and a base (104); a multi-pole protection unit installed inside the housing, the multi-pole protection unit comprises a plurality of magnetothermic protection devices, each magnetothermic protection device corresponds to one pole of the multi-pole circuit breaker, each magnetothermic protection device is assembled by means of a component of thermal protection (152) and a magnetic protection component (126, 180A), the multi-pin protection unit comprises a rod (134); wherein the thermal protection component comprises a double metal sheet (152), the magnetic protection component (126, 180A) comprises a movable iron core (126), a static iron core (180A), wherein between the core of static iron (18A) and the movable iron core (3126) an air gap is provided; an energy storage component (150, 75, 162, 74) installed within the housing, wherein the energy storage component (150, 75, 162, 74) couples with the thermal protection component (152), and , when an overload current occurs, the energy storage component (150, 75, 162, 74) is activated by the thermal protection component (152) and hits an operating mechanism of the multi-pole circuit breaker, wherein the component Energy storage device comprises an energy storage rod (75), a double metal adjusting rod (150), energy storage springs (162, 282), the double metal adjusting rod (150) comprises a locking rod (top surfaces 232, 234, 236) and contact rods (294), where each contact rod (294) engages a work surface (154) at an upper end of the double sheet metal (152), at normal operation, each rod of c contact (294) is spaced from work surface (154), when overload occurs, double sheet metal (152) deforms so that work surface (154) is in contact with each contact rod (294) ; an adjustment component (114, 116) mounted on the housing, wherein the adjustment component comprises a first adjustment rod (114) and a second adjustment rod (116), wherein the second adjustment rod (116) is provides a second adjusting gear (240) in the middle.

Compendium

The present invention provides a circuit breaker protection apparatus applicable to a large capacity circuit breaker.

According to an embodiment of the present invention, a magnetothermic protection apparatus defined in claim 1 is described.

In one embodiment, the adjustment bracket is provided with a plurality of spring fixing points, one end of the torsion spring is fixed at different spring fixing points to obtain different fixed interior counter forces.

In one embodiment, in normal operation, the double metal adjustment rod is not in contact with the double metal sheet, the double metal adjustment rod and the energy storage rod lock together, the energy storage spring stores energy . When an overload current occurs, the double metal sheet deforms and pushes the double metal adjusting rod and the energy storage rod to unlock, the energy storage spring releases energy and drives the double metal adjusting rod to hit the operating mechanism of the circuit breaker.

An example of a thermal protection component that is applicable to a circuit breaker protection apparatus described above comprises a double sheet metal, the double sheet metal is installed directly on a bus bar, and a work surface of the double sheet metal is an inclined surface. .

The double sheet metal can be bent to be "L" shape, a cross part of the double sheet metal "L" shape is installed directly "L" on the bus bar, an upper end of a longitudinal part of the Double "L" shaped metal sheet is the work surface.

The thermal protection component can be coupled with an energy storage component, and when an overload current occurs, the thermal protection component activates the energy storage component, and the energy storage component hits a circuit breaker operating mechanism. circuit.

In normal operation, the energy storage component may be jammed and there is a gap between the energy storage component and the double sheet metal work surface; When an overload current occurs, the double metal sheet deforms and is in contact with the energy storage component, so that the energy storage component unlocks and acts.

The energy storage component may comprise an energy storage rod, a double metal adjustment rod, and an energy storage spring. The double metal adjusting rod may be provided with a contact rod, and when an overload current occurs, the working surface of the double metal sheet is in contact with the contact rod to push the double metal adjusting rod. The contact rod can be aligned at different positions on the double sheet metal working surface, so that the clearance between the contact rod and the working surface is different to obtain different nominal overload currents.

An example of a magnetic shielding component that is applicable to a magnetothermal shielding apparatus described above may comprise a movable iron core, a static iron core and a torsion spring, between the static iron core and the movable iron core are provides air clearance, air clearance is adjustable, torsion spring provides fixed internal counter force.

The magnetic shield component may comprise: a static iron core bracket, a movable iron core bracket, an adjusting bracket, and the torsion spring. The static iron core bracket is used to install the static iron core on it. The movable iron core bracket is used to install the movable iron core on it, the movable iron core bracket is rotatably mounted on the static iron core bracket by a rotating rod. The adjustment bracket is arranged on the rotation stem, the adjustment bracket is in contact with the movable iron core square. The torsion spring snaps onto the rotation stem, one end of the torsion spring is fixed onto the adjusting bracket, the torsion spring applies the fixed internal counter force to the movable iron core bracket through the adjusting bracket , the torsion spring also maintains the air gap between the movable iron core and the static iron core.

The adjustment bracket can be provided with a plurality of spring fixing points, one end of the torsion spring is fixed at different spring fixing points to obtain different fixed internal counter forces.

Two adjusting brackets can be provided and the two adjusting brackets are arranged near the inner sides of the two side walls of the static iron core bracket respectively. Two torsion springs are provided and fixed by adjusting bracket respectively, one end of the torsion spring is fixed at one of the adjusting bracket spring fixing points, the other end of the torsion spring is an end free. A stop block is provided on the adjusting bracket, the stop block is in contact with a contact surface on the movable iron core bracket.

The magnetic shield component can be coupled with a rod, and the rod is in contact with the adjustment bracket, the air gap is adjusted through the adjustment bracket.

The adjusting bracket can be provided with an extension pin, and the rod is provided with an inclined surface, the extension pin is in contact with different positions of the inclined surface, so that the adjusting bracket rotates around the stem of rotation, and drives the movable iron core bracket to rotate to adjust the air clearance, a reset spring snaps over the rotation stem, the reset spring makes the extension pin press on the inclined surface. When the rod moves, the extension pin is in contact with different positions of the inclined surfaces, the air gap is adjusted to obtain different nominal transient currents.

The thermal protection component of the circuit breaker protection apparatus of the present invention uses a double metal sheet to activate an energy storage component to perform a tripping operation. It has a unique structure and high speed of action. The energy storage component can maintain a constant firing force. The magnetic protection component of the magneto-thermal protection apparatus uses a spring to provide a fixed internal counter force, so that an air gap is the only parameter to be adjusted, the design difficulty is reduced.

Brief description of the drawings

The above and other features, natures, and advantages of the invention will be apparent from the following description of the embodiments incorporating the drawings, wherein,

Figure 1 illustrates a structural diagram of a magnetothermic protection apparatus according to an embodiment of the present invention.

Fig. 2 illustrates a structural diagram of a thermal protection component of the magnetothermic protection apparatus according to an embodiment of the present invention.

Fig. 3A illustrates a structural diagram of a magnetic shielding component of the magnetothermic shielding apparatus according to an embodiment of the present invention.

Fig. 3B illustrates the spring attachment points of the magnetic shielding component of a magnetothermic shielding apparatus according to one embodiment.

Fig. 3C illustrates the spring attachment points of the magnetic shield component of a magnetothermal shield apparatus according to another embodiment.

Figure 4 illustrates a structural diagram of the thermal protection component and the magnetic component of the magneto-thermal protection apparatus after being assembled.

Fig. 5 illustrates an assembly structure of a plurality of circuit breaker protection devices and a base of the circuit breaker protection apparatus according to an embodiment of the present invention.

Figure 6 illustrates a structural diagram of an upper case and a base of the magnetothermic protection apparatus according to an embodiment of the present invention.

Fig. 7 illustrates a schematic diagram for adjusting an air gap between a static iron core and a movable iron core of the magneto-thermal protection apparatus according to an embodiment of the present invention. Fig. 8A, Fig. 8B, and Fig. 8C illustrate structural diagrams of an energy storage component of the magneto-thermal protection apparatus according to an embodiment of the present invention.

Fig. 9A and Fig. 9B illustrate structural diagrams of an adjusting component of the magnetothermic protection apparatus according to an embodiment of the present invention.

FIG. 10A and FIG. 10B illustrate structural diagrams of an adjusting component of a circuit breaker protection apparatus according to an embodiment not part of the present invention.

Fig. 11A and Fig. 11B illustrate an assembly structure of an adjusting component of the magneto-thermal protection apparatus according to an embodiment of the present invention.

Detailed description of realizations

The present invention describes a magnetothermic protection apparatus applicable to a multi-pole circuit breaker, which can allow the multi-pole circuit breaker to trip. Figure 1 illustrates a structural diagram of a magnetothermic protection apparatus according to an embodiment of the present invention. as the picture shows 1, the magneto-thermal protection apparatus comprises: an upper housing 101, a base 112, a multi-pin protection unit 105 comprising a plurality of magneto-thermal protection devices 104, an energy storage component 106 and an adjustment component 107. The upper case 101 and base 112 are assembled to form a housing of the circuit breaker protection apparatus. The multi-pole protection unit 105, the energy storage component 106 and the adjustment component 107 are installed in the housing formed by the upper case 101 and the base 112. Each magnetothermic protection device 104 is installed on one pole of the circuit breaker. circuit and corresponds to a circuit phase. Each circuit breaker protection device 104 is assembled by a thermal protection component 102 and a magnetic protection component 103. The plurality of circuit breaker protection devices 104 are arranged on the base 112 to form the multi-pin protection unit 105. The protection unit Multi-pin 105 comprises a rod 501 for adjusting an air gap between a static iron core and a movable iron core of the magnetic shield component 103. The energy storage component is mounted on the upper housing 101. The energy storage component Energy comprises an energy storage rod 602, a double metal adjustment rod 601, an energy storage spring and an adjustment screw 604. The energy storage component 106 mates with the thermal protection component 102. The component adjusting rod 107 comprises a first adjusting rod 171 and a second adjusting rod Set 172. The first setting rod 171 is coupled with the energy storage component 106 and the thermal protection component 102 to set a rated overload current. Second adjusting rod 172 engages rod 501 to adjust a nominal transient current by adjusting the air gap.

As shown in Figure 2, Figure 2 illustrates a structural diagram of a thermal protection component of the magnetothermic protection apparatus. The thermal protection component 102 comprises a double sheet metal 121. The double sheet metal 121 is bent to be in an "L" shape. A lower part of the double sheet metal 121, that is, a cross part of the double sheet metal in the shape of an "L" is installed directly on a bus bar 123 through a screw 124. An upper part of the double sheet metal 121, that is, an upper end of a longitudinal portion of the "L" -shaped double sheet metal forms an end contact. A contact surface 122 of the end contact is an inclined surface. The inclined surface 122 acts as a working surface for the double sheet metal 121, so that an overload protection factor is adjustable.

As shown in Fig. 3A, Fig. 3A illustrates a structural diagram of a magnetic shielding component of the magneto-thermal shielding apparatus. Magnetic shielding component 103 comprises: a static iron core 302, a movable iron core 302, a static iron core bracket 305, a movable iron core bracket 301, a rotation stem 304, adjustment brackets 306 , 307, torsion springs 308, 310, and a reset spring 309. Static iron core 303 is formed by lamination of multiple layers of magnetic conductive sheets, and installed on static iron core bracket 305. Static iron core Static Iron 303 and Static Iron Core Bracket 305 are both in frame form with a through hole formed in the middle. The through hole is used for bus bar 123 to pass through. Movable iron core 302 is installed on movable iron core bracket 301. Movable iron core bracket 301 is rotatably mounted on static iron core bracket 305 by rotating rod 304. movable iron 301 and movable iron core 302 can rotate around rotation stem 304 with respect to static iron core bracket 305 and static iron core 303. Adjusting brackets 306, 307 are arranged near the sides interiors of the two side walls of the static iron core bracket 305 respectively. Adjustment brackets 306, 307 are also installed on rotation stem 304 and also rotate around rotation stem 304. Adjustment brackets 306, 307 are provided with a respective vertically extending extension pin 306H, 307H. The adjusting brackets 306, 307 are provided with a group of spring attachment points 306B, 307B. The groups of spring attachment points 306B, 307B comprise a plurality of spring attachment points respectively. The groups of spring attachment points 306B, 307B are formed in a bending position of the adjustment brackets 306, 307 respectively and correspond to each other. The torsion spring 308 is fitted over the rotation stem 304, and is fixed by the adjustment bracket 306. One end of the torsion spring 308 is fixed at one of the spring fixing points 306B of the adjustment bracket 306, the another end of the torsion spring 308 is a free end. Similarly, torsion spring 310 snaps onto rotation stem 304, and is fixed by adjusting bracket 307. One end of torsion spring 310 is fixed at one of spring fixing points 307B on the bracket. fit 307, the other end of torsion spring 310 is a free end. Stop blocks 306G, 307G are provided on adjusting brackets 306, 307 (refer to Figure 7). The stop blocks 306G, 307G are in contact with a contact surface 301G on the movable iron core bracket 301 respectively, so that the adjusting brackets 306, 307 apply a force to the movable iron core bracket 301. The movable iron core bracket 301 obtains a fixed internal counter force through the symmetrically arranged adjusting brackets 306, 307 and the symmetrically arranged torsion springs 308, 310. By setting different spring attachment points on the adjustment brackets 306, 307 to which one end of the torsion spring 308, 310 is attached, different fixed interior counter forces can be obtained. Figure 3B and Figure 3C illustrate different embodiments of the spring attachment points. According to the embodiment of the spring attachment points shown in Figure 3B, in bending positions of the adjusting brackets 306, 307 two steps are formed in an up and down arrangement respectively, and on each step a fixing point is arranged spring, which in the drawings are numbered 306B1, 306B2, 307B1 and 307B2 respectively. According to the embodiment of the spring attachment points shown in Figure 3C, in bending positions of the adjusting brackets 306, 307 are formed respectively three steps in an inclined arrangement, and on each step a spring attachment point is provided, which in the drawings are respectively numbered 306B1, 306B2, 306B3, 307B1, 307B2 and 307B3. A reset spring 309 fits over the rotation stem 304, the reset spring 309 is a torsion spring with long rack type pins. The reset spring 309 is arranged between the adjustment brackets 306, 307. One long frame-type pin of the reset spring 309 is in contact with the movable iron core bracket 301, and the other long frame-type pin is fixed on the Thermal shield component 102. Between the static iron core 303 and the movable iron core 302 in the assembled magnetic shield component 103 there is a rotating air gap 311.

As shown in Fig. 4, Fig. 4 illustrates a structural diagram of the thermal protection component and the magnetic component of the magneto-thermal protection apparatus after being assembled. The thermal protection component 102 and the magnetic protection component 103 are assembled, the busbar 123 passes through the through holes in the middle of the static iron core 303 and the static iron core bracket 305, the double metal sheet 121 passes between the rotation stem 304 and the movable iron core bracket 301. A long frame-type pin of the reset spring 309 is fixed over the thermal protection component 102. As shown in the drawings, the long frame-type pin It is embedded in a gap formed by the busbar 123 and the transverse part of the double metal sheet 121. The thermal protection component 102 and the magnetic protection component 103 are assembled to form the magnetothermic protection device 104, which is used to certain pole of multiphase circuit breaker and corresponds to a certain circuit phase.

As shown in Fig. 5, Fig. 5 illustrates an assembly structure of a plurality of magneto-thermal protection devices and a base of the magneto-thermal protection apparatus. Figure 5 is a view shown from a rear side of Figure 1. On the base 112 a plurality of magnetothermic protection devices 104 are installed through screws to form the multi-pin protection unit 105. The multi-pole protection unit 105 is couples with a multi-pole circuit breaker. Each circuit breaker protection device 104 corresponds to one pole of the multi-pole circuit breaker and is used for one circuit phase. The multi-pin protection unit 105 comprises a rod 501. The rod 501 is mounted in a guide groove formed after the assembly of the upper housing 101 and the base 112. As shown in Figure 6, the upper housing 101 and the base 112 are assembled to form the housing. Guide grooves 101A and 101B are formed in the housing. Rod 501 slides in guide grooves 101a and 101B. On the rod 501 sloping structures are formed in positions corresponding to the respective magneto-thermal protection devices 104. Each sloping structure comprises two inclined surfaces 502 and 503, which correspond to the adjusting brackets 306 and 307 of each magneto-thermal protection device 104 respectively. The inclined surface 502 corresponds to the adjustment bracket 306, and the extension pin 306H of the adjustment bracket 306 is in contact with the inclined surface 502. The inclined surface 503 corresponds to the adjustment bracket 307, and the extension pin 307H of the bracket The adjustment spring 307 is in contact with the inclined surface 503. The reset spring 309 generates torque and urges the adjustment brackets 306, 307 to rotate towards the rod 501. Under the action of the reset spring 309, the extension pins 306H , 307H of the adjusting brackets 306, 307 always press on the inclined surfaces 502, 503 and maintain a certain pressure. Figure 7 illustrates a schematic diagram

air 311 between the static iron core and the movable iron core. As shown in Figure 7, the reset spring 309 causes the extension pins 306H, 307H to always press on the inclined surfaces 502, 503. When the rod 501 moves, the contact positions of the extension pins are changed. 306H, 307H and inclined surfaces 502, 503. This type of change in positions causes extension pins 306H, 307H to drive adjusting brackets 306, 307 to rotate around rotation stem 304. As one of the pins of torsion springs 308 and 310 is fixed on adjusting brackets 306, 307, rotation of adjusting brackets 306, 307 will drive torsion springs 308, 310 to rotate. Torsion springs 308, 310 drive movable iron core bracket 301 to rotate around rotation stem 304 so that the air clearance 311 between movable iron core 302 and static iron core 303 is changed. Therefore, the adjustment of the air clearance 311 can be performed by moving the rod 501 along the guide grooves 101a and 101b. Continuing with FIG. 5, a gear member 504 is provided on rod 501. Rod 501 can be driven to move along guide grooves 101a and 101b through gear member 504.

Fig. 8A, Fig. 8B and Fig. 8C illustrate structural diagrams of an energy storage component of the magneto-thermal protection apparatus. Figure 8B is a cross-sectional view of part A in Figure 8A. Figure 8C is a cross-sectional view of the B in Figure 8A. Figure 8A is a view shown from a rear side of Figure 1. The energy storage component is mounted on the upper housing 101. The energy storage component comprises an energy storage rod 602, a metallic adjustment rod double 601, an energy storage spring and an adjustment screw 604. The energy storage springs are multiple, comprising an energy storage spring 603 and an energy storage spring 610. The double metal adjustment rod 601 encompasses the entire upper housing 101 and engages the plurality of poles of the multi-pole circuit breaker. On the double metal setting rod 601, contact rods 601B are provided at positions corresponding to the respective poles of the multi-pole circuit breaker. Each contact rod 601B corresponds to a magnetothermic protection device 104, the contact rod 601B is coupled with the double metal sheet 121 of the component of thermal protection in the magnetothermic protection device 104. Contact rod 601B engages inclined surface 122 at the upper end of double sheet metal 121. In normal operation, contact rod 601B is spaced from inclined surface 122. When overload occurs, the double sheet metal deforms so that the inclined surface 122 is in contact with the contact rod 601B. The double metal adjustment rod 601 further comprises a locking rod 601A. Locking rod 601A allows the dual metal adjustment rod 601 and energy storage rod 602 to be hooked together. As shown in Figure 8C, locking rod 601A and a locking surface 602A of the locking rod. energy storage 602 form the hitch. An adjustment screw 604 is used to adjust an engagement amount of the locking rod 601A and the locking surface 602A. When the adjusting screw 604 is rotated, a contact surface between the locking rod 601A and the 602A locking surface, that is, the amount of engagement. The energy storage spring 603 connects to the double metal adjusting rod 601. When the double metal sheet 121 is heated and deformed, it will push the contact rod 601B and drive the double metal adjusting rod 601 to rotate around its center of rotation 601C. After the double metal adjustment rod 601 is rotated, the locking rod 601A unlocks from the locking surface 602A. After unlocking, the energy storage spring 603 drives the double metal setting rod 601, and with the engagement of the energy storage spring 610, the operating mechanism of the circuit breaker is struck by the double metal setting rod 601, so that the operating mechanism is tripped and overload protection is achieved. According to the energy storage component of the present invention, the double metal sheet 121 functions as a trigger, and the striking action is driven by the energy storage springs 603 and 610, then the operating force to strike the operating mechanism is stable.

Fig. 9A and Fig. 9B illustrate structural diagrams of an adjustment component of the circuit breaker protection apparatus. Fig. 11A and Fig. 11B illustrate an overall structure of the adjusting component. As shown in the drawings, the adjustment component 107 is installed on the basis of the circuit breaker. The adjustment component comprises a mounting bracket 173, a first adjustment rod 171, and a second adjustment rod 172. The first adjustment rod 171 and the second adjustment rod 172 are rotatably mounted on the mounting bracket 173. In a joint of the first adjustment rod 171 and the mounting bracket 173 and a joint of the second adjustment rod 172 and the mounting bracket 173 are provided with gaskets 705. The first adjustment rod 171 is provided with a first adjustment gear 704 in the middle, a first bulge 708 in the center of the bottom, and a conical bulge 701 at the bottom. A locating rod is provided at the conical end of the conical boss 701. As shown in FIG. 8A, a bracket 161 is mounted on the upper housing 101, and the bracket 161 is provided with a mounting hole 605 in a bent portion. The first protrusion 708 of the first adjustment rod 171 is mounted in the mounting hole 605 to form a rotational pair. The locating rod in the conical boss 701 of the first adjustment rod 171 is inserted into an adjustment groove 601F of the double metal adjustment rod 601. The second adjustment rod 172 is provided with a second adjustment gear 703 in the middle, a third adjusting gear 702 at the bottom, and a second boss 707 at the center of the bottom. As shown in FIG. 8A, a mounting hole 606 is provided in the upper housing 101. The second boss 707 of the second adjusting rod 171 is mounted in the mounting hole 606 to form a rotating pair. The third setting gear 702 of the second setting rod meshes with the gear member 504 on the rod 501. For the purpose of more precise rotation of the first setting rod 171 and the second setting rod 172, on the mounting bracket 173 a stepped bracket is provided. Both ends of the stepped bracket are tooth-shaped ends. The tooth-shaped end 706 is in contact with and meshing with the first adjustment gear 704, and the tooth-shaped end 705 is in contact and meshing with the second adjustment gear 705. When the first adjustment rod 171 or the second adjusting rod 172 rotates, the tooth-shaped ends and adjusting gears allow the adjusting rod to rotate in a staggered fashion one tooth at a time.

FIG. 10A and FIG. 10B illustrate structural diagrams of an adjustment component according to another embodiment. According to this embodiment, the first adjusting rod 171 and the second adjusting rod 172 adopt a damped rotation mode. Compared with the embodiment shown in Fig. 9A and Fig. 9B, the difference from the embodiment shown in Fig. 10A and Fig. 10B is that no stepped support is provided. An attachment point manner is applied so that interference fit is generated between a cylindrical surface of the rod body of the adjusting rod and a through hole of the mounting bracket. As shown in the drawings, mounting holes 174 are provided in mounting bracket 173, and first adjusting rod 171 and second adjusting rod 172 pass through the mounting holes. A plurality of attachment points 710 are provided in the mounting holes 174. The inside diameters of the mounting holes 714 are slightly larger than the outside diameters of the rod bodies 720 of the first adjusting rod 171 and the second adjusting rod. fit 172, while the inside diameters formed by the plurality of clamping points 710 are slightly smaller than the outer diameters of the rod bodies 720. Therefore, between the clamping point 710 and the rod body 720 fit is formed by interference, and a clamping rotation effect is achieved. It should be noted that the diameters of the first adjusting rod 171 and the second adjusting rod 172 do not need to be the same, only the diameters of the first adjusting rod 171 and the second adjusting rod 172 are required to match the size of a corresponding mounting hole 174.

As shown in Fig. 11A and Fig. 11B, the adjusting component 107 is respectively coupled with the gear member 504 and the double metal adjusting rod 601, to realize the adjustment of a rated overload current and a rated transient current. . The locating rod in the conical boss 701 of the first adjustment rod 171 is inserted into the adjustment groove 601F of the double metal adjustment rod 601. When the first adjustment rod 171 is rotated, the locating rod of the conical boss 701 is urged to move, and the locating rod urges double metal adjusting rod 601 to move transversely through adjusting groove 601F. Since the working surface of the double metal sheet 121 is the inclined surface 122, after the double metal adjustment rod 601 is moved transversely, a distance F is changed between the contact rod 601B and the inclined surface 122. The scale of the The rated overload current can be adjusted when the distance F is changed. A third adjusting gear 702 of the second adjusting rod 172 engages with the gear member 504 on the rod 501. When the second adjusting rod 172 is rotated , drives the rod 501 to move transversely through the gear engagement. The size of the air gap between the movable iron core and the static iron core is adjusted when the rod 501 moves transversely, and a change in the size of the air gap can adjust the scale of the nominal transient current.

The thermal protection component of the circuit breaker protection apparatus of the present invention uses a double metal sheet to activate an energy storage component to perform a tripping operation. It has a unique structure and high speed of action. The energy storage component can maintain a constant firing force. The magnetic protection component of the magneto-thermal protection apparatus uses a spring to provide a fixed internal counter force, so that an air gap is the only parameter to be adjusted, the design difficulty is reduced.

The above embodiments are provided to those skilled in the art to make or use the invention and can be modified and changed in various ways, therefore the scope of protection of the invention is not limited by the above embodiments, instead, it is it must conform to the maximum scope of the innovative features mentioned in the claims.

Claims (3)

1. A magnetothermic protection device applicable to a multi-pole circuit breaker, wherein the magnetothermic protection device comprises: a housing comprising an upper housing (101) and a base (112); a multi-pin protection unit (105) installed inside the housing, where: The multi-pole protection unit (105) comprises a plurality of magnetothermic protection devices (104), each magnetothermic protection device (104) corresponds to one pole of the multi-pole circuit breaker, each magnetothermic protection device (104) is assembled by means of a thermal protection component (102) and a magnetic protection component (103), the multi-pin protection unit (105) comprises a rod (501), The thermal protection component (102) comprises a double metal sheet (121), the double metal sheet (121) is bent to an L-shape, a cross part of the L-shaped double metal sheet (121) is installed directly On a bus bar (123), an upper end of a longitudinal part of the double L-shaped sheet metal (121) is a work surface (122), the work surface (122) of the double sheet metal (121 ) is an inclined surface, and The magnetic shield component (103) comprises a movable iron core (302), a static iron core (302), a movable iron core bracket (301) to install the movable iron core (302) thereon , a static iron core bracket (305) to install the static iron core (302) thereon, an adjustment bracket (306) disposed on a rotation stem (304), and a torsion spring (308) , wherein between the static iron core (302) and the movable iron core (302) an air clearance is provided, the air clearance is adjustable, the movable iron core bracket (301) is rotatably mounted on the Static iron core bracket (305) through the rotation rod (304), the adjustment bracket (306) is in contact with the movable iron core bracket (301), the torsion spring (308) fits over the rotation stem (304), one end of torsion spring (308) is fixed on the bracket (306), the torsion spring (308) applies a fixed internal counter force to the movable iron core bracket (301) through the adjustment bracket (306), the torsion spring (308) also maintains the air gap between the movable iron core (302) and the static iron core (302), the magnetic shield component (103) engages with the rod (501), the rod (501) is provided with a surface inclined (502), the adjustment bracket (306) is in contact with different positions of the inclined surface (502); an energy storage component (106) installed within the housing, where: The energy storage component (106) is coupled with the thermal protection component (102), and when an overload current occurs, the energy storage component (106) is activated by the thermal protection component (102) and strikes a multi-pole circuit breaker operating mechanism, the energy storage component (106) comprises an energy storage rod (602), a double metal adjusting rod (601), energy storage springs (603, 610) and an adjusting screw (604), the double metal adjusting rod (601) comprises a locking rod (601A) and contact rods (601B), in normal operation, the locking rod (601A) and the energy storage rod (602) forms a latch, adjusting screw (604) adjusts a latch amount, each contact rod (601B) engages the work surface (122) at an upper end of the sheet metal double (121), In normal operation, each contact rod (601B) is spaced from the work surface (121), when overload occurs, the double sheet metal (122) is deformed so that the work surface (122) is in contact with each contact rod (601B); an adjustment component (107) mounted on the housing, wherein the adjustment component (107) comprises a mounting bracket (173), a first adjustment rod (171) and a second adjustment rod (172), the first Adjusting rod (171) and second adjusting rod (172) are rotatably mounted on mounting bracket (173), the first adjusting rod (171) is provided with a first adjusting gear (704) in the middle and a conical protrusion (701) at the bottom, at the conical end of the conical protrusion (701) a positioning rod is provided, the positioning rod is inserted into an adjustment groove (601F) of the double metal adjustment rod (601), the second adjusting rod (172) is provided with a second adjusting gear (703) in the middle and a third adjusting gear (702) at the bottom, the third adjusting gear (702) meshes with a gear member (504) on the rod (501), on the square of m On mounting (173) a stepped bracket is provided, both ends of the stepped bracket are tooth-shaped ends, one tooth-shaped end is in contact and meshed with the first adjusting gear (704), the other tooth-shaped end is in contact and meshed with the second adjusting gear (703), when the first adjusting rod (171) or the second adjusting rod (172) rotates, the tooth-shaped ends and adjusting gears allow the first adjusting rod (171) or second adjusting rod (172) rotate in a stepwise fashion one tooth at a time; When the first adjusting rod (171) is rotated, the locating rod of the conical boss (701) is driven to move, and the locating rod urges the double metal adjusting rod (601) to move transversely through the adjustment groove (601E), so that a distance is changed between each contact rod (601B) and the work surface (122) to adjust a scale of the overload current, when the second is rotated adjusting rod (172), the rod (501) is driven to move transversely through the engagement of the third adjusting gear (702) and the gear member (504), changes a contact position between the inclined surface (502) of the rod (501) and the adjustment bracket (306), and through the adjustment bracket (306) a size of the air gap is adjusted between the movable iron core (302) and the static iron core (302 ). The magneto-thermal protection apparatus according to claim 1, wherein the adjusting bracket (306) is provided with a plurality of spring fixing points (306B), one end of the torsion spring (308) is fixed on different points spring clamp (306B) to obtain different fixed internal counter forces. The magnetothermic protection apparatus according to claim 1, wherein in normal operation, the double metal adjusting rod (601) is not in contact with the double metal sheet (121), the double metal adjusting rod (601) and the energy storage rod (602) lock together, the energy storage springs (603, 610) store energy; When an overload current occurs, the double metal sheet (121) deforms and pushes the double metal adjustment rod (601) and the energy storage rod (602) to unlock, the energy storage spring (603) releases energy and drives the striking action.