阅读说明：本技术 具有带有改进配合表面的触点的电气组件 (Electrical assembly having contacts with improved mating surfaces ) 是由 A.Y.李 R.L.思拉什 于 2020-03-13 设计创作，主要内容包括：一种适于向具有电源的电路切换电力的电气组。所述电气组件(10)包括：所述电气组件(10)包括壳体(20),壳体带有设置在壳体中的载流触点(20,22)。载流触点(20,22)具有带有非线性表面(34)的接合端部(32)。壳体(20)中设置有联接构件(44)。联接构件(44)具有用于接合载流触点(20,22)的非线性表面(34)的配合部分(48)。配合部分(48)具有从配合部分(48)的顶表面(72)向配合部分(48)的底表面(74)延伸的凹槽(70)。随着所述电气组件(10)移动到闭合位置,联接构件(44)的配合部分(48)的凹槽(70)移动成与触点(20,22)的非线性表面(34)接合,导致在载流触点(20,22)中的每个相应触点(20,22)的非线性表面(34)与配合部分(48)的凹槽(70)中的每个相应凹槽(70)的边缘(78)之间提供多个接触点。(An electrical pack adapted to switch power to a circuit having a power source. The electrical assembly (10) comprises: the electrical assembly (10) includes a housing (20) with current carrying contacts (20, 22) disposed therein. The current carrying contacts (20, 22) have an engagement end (32) with a non-linear surface (34). A coupling member (44) is provided in the housing (20). The coupling member (44) has a mating portion (48) for engaging the non-linear surface (34) of the current carrying contacts (20, 22). The mating portion (48) has a groove (70) extending from a top surface (72) of the mating portion (48) to a bottom surface (74) of the mating portion (48). As the electrical assembly (10) is moved to the closed position, the grooves (70) of the mating portion (48) of the coupling member (44) are moved into engagement with the non-linear surfaces (34) of the contacts (20, 22), resulting in a plurality of contact points being provided between the non-linear surface (34) of each respective one (20, 22) of the current carrying contacts (20, 22) and the edge (78) of each respective one (70) of the grooves (70) of the mating portion (48).)

1. An electrical assembly (10) adapted to switch power to a circuit having a power source, the electrical assembly (10) comprising:

a housing (20);

a current carrying contact (20, 22) disposed in the housing (20), the current carrying contact (20, 22) having an engagement end (32) with a non-linear surface (34);

a coupling member (44), the coupling member (44) having a mating portion (48) for engaging the non-linear surface (34) of the current carrying contact (20, 22), the mating portion (48) having a groove (70) disposed thereon, the groove (70) extending from a top surface (72) of the mating portion (48) toward a bottom surface (74) of the mating portion (48);

wherein as the electrical assembly (10) is moved to a closed position, the grooves (70) of the mating portion (48) of the coupling member (44) move into engagement with the non-linear surfaces (34) of the contacts (20, 22) resulting in a plurality of contact points being provided between the non-linear surface (34) of each respective one of the current carrying contacts (20, 22) and an edge (78) of each respective one of the grooves of the mating portion (48).

2. The electrical assembly (10) of claim 1, wherein the non-linear surface (34) has a rounded configuration.

3. The electrical assembly (10) of claim 1, wherein the groove (70) extends in a direction parallel to a longitudinal axis of the coupling member (44).

4. The electrical assembly (10) of claim 1, wherein the recess (70) has a sidewall (76) extending to a top surface (72) of the mating portion (48), an intersection of the sidewall (76) and the top surface (72) forming a contact edge (78) that pierces, breaks, or penetrates any contaminants that may be present at the contact point.

5. The electrical assembly (10) of claim 4, wherein the sidewall (76) extends at a 90 degree angle from the top surface (72) to form the contact edge (78).

6. The electrical assembly (10) of claim 4, wherein the contact edge (78) is a rounded edge (78) extending between the side wall (76) and the top surface (72).

7. The electrical assembly (10) of claim 1, wherein a contact bridge (46) extends from a first mating portion of the mating portion (48) of the coupling member (44) to a second mating portion of the mating portion (48) of the coupling member (44).

8. The electrical assembly (10) of claim 1, wherein an actuator assembly (40) moves the coupling member (44) between a closed position and an open position in which the mating portion (48) of the coupling member (44) is separated from the current carrying contacts (20, 22).

9. A switch assembly (10) adapted to switch power to a circuit having a power source, the switch assembly comprising:

a stationary contact (20, 22) having an engagement end (32) with a non-linear surface (34);

a movable coupling member (44), the movable coupling member (44) having a mating portion (48) for engaging the non-linear surface (34) of the fixed contact, the mating portion (48) having a groove (70) disposed thereon, the groove (70) having a contact edge (78), the movable coupling member (44) being movable between an open position in which the mating portion (48) of the movable coupling member (44) is separated from the fixed contact and a closed position in which the mating portion (48) of the movable coupling member (44) is engaged with the fixed contact,

wherein as the switch assembly (10) is moved to the closed position, the contact edge (78) of the mating portion (48) of the movable coupling member (44) moves into engagement with the non-linear surface (34) of the fixed contacts (20, 22) resulting in a plurality of contact points being provided between the non-linear surface (34) of each respective one of the fixed contacts (20, 22) and the contact edge (78) of each respective one of the recesses (70) of the mating portion (48).

10. The switch assembly (10) of claim 9, wherein the non-linear surfaces (34) of the stationary contacts (20, 22) have a rounded configuration.

11. The switch assembly (10) of claim 10 wherein said recess (70) has a sidewall (76) extending to a top surface (72) of said mating portion (48), an intersection of said sidewall (76) and top surface (72) forming said contact edge (78).

12. The switch assembly (10) of claim 11 wherein said side wall (76) extends from said top surface (72) at a 90 degree angle to form said contact edge (78).

13. The switch assembly (10) of claim 11 wherein said contact edge (78) is a rounded edge (78) extending between said side wall (76) and said top surface (72).

Technical Field

The present invention relates to an electrical assembly adapted to switch electrical power to an electrical circuit having a power source. More particularly, the present invention relates to an electrical assembly having contacts with improved mating surfaces to minimize or eliminate the effects of contaminants on the mating surfaces.

Background

Relays and contactors are known devices for switching desired circuits/loads and the like. A relay is an electrically operated switch. Many known relays use electromagnets to mechanically operate the switching mechanism, but other operating principles are also used. Relays are used in situations where air flow through a low power signal control circuit is required, or where several circuits must be controlled by one signal. A contactor is an electrically controlled switch used to switch power circuits, similar to a relay, but rated for higher currents.

Generally, a simple electromagnetic relay includes a coil assembly, a movable armature, and one or more sets of contacts, i.e., a single throw system, a double throw system, etc. The contact set includes a movable contact and a fixed contact. The armature is mechanically connected to one or more sets of moving contacts and is held in place by a spring.

When the movable and fixed contacts are moved to a mated or closed position, the mating surfaces of the contacts engage to provide an electrical connection therebetween. However, if contaminants (e.g., particles as small as 40 microns) are present on the mating surfaces of the movable or fixed contacts, the contaminants may: preventing an electrical connection; resulting in unreliable electrical connections; or cause the contacts to have a high resistance when the movable contact and the fixed contact are in a mated or closed position.

The problem to be solved is to provide a contact having an improved mating surface to minimize or eliminate the effects of contaminants, thereby ensuring that a positive electrical connection is made when the movable contact and the fixed contact are mated, regardless of whether contaminants are present.

Disclosure of Invention

This problem is solved by an electrical assembly adapted to switch electrical power to an electrical circuit having a power source. The electrical assembly includes a housing with current carrying contacts disposed therein. The current carrying contact has an engagement end with a non-linear surface. A coupling member is disposed in the housing. The coupling member has a mating portion for engaging the non-linear surface of the current carrying contact. The mating portion has a groove disposed thereon that extends from a top surface of the mating portion toward a bottom surface of the mating portion. As the electrical assembly is moved to the closed position, the grooves of the mating portion of the coupling member are moved into engagement with the non-linear surfaces of the contacts, resulting in a plurality of contact points being provided between the non-linear surface of each respective one of the current carrying contacts and an edge of each respective one of the grooves of the mating portion.

Drawings

The invention will now be described, by way of example, with reference to the accompanying drawings:

fig. 1 is a perspective view of an illustrative contactor assembly.

Fig. 2 is a cross-sectional view of the exemplary contactor assembly taken along line 2-2 of fig. 1, showing the contactor assembly in an open position.

Fig. 3 is a cross-sectional view of the exemplary contactor assembly similar to fig. 2, showing the contactor assembly in a closed position.

Fig. 4 is an enlarged perspective view of an exemplary stationary contact of the contactor assembly.

Figure 5 is an enlarged perspective view of an exemplary movable contact of the contactor assembly.

Fig. 6 is an enlarged side view of the fixed and movable contacts in an open or unmated position.

Fig. 7 is an enlarged side view of the fixed and movable contacts in the closed or mated position.

Fig. 8 is an enlarged side view of an alternative embodiment of the fixed and movable contacts in an open or unmated position.

Detailed Description

The contactor assembly 10 is a relay or switch that controls the delivery of power through an electrical circuit (not shown). The contactor assembly 10 alternates between an open state (as shown in figure 2) and a closed state (as shown in figure 3). In the closed state, the contactor assembly 10 provides a conductive bridge to close the circuit and allow current to be supplied from the power source to the electrical load. In the open state, the contactor assembly 10 removes the conductive bridge so that the circuit is open and current cannot be supplied from the power source to the electrical load via the contactor assembly 10.

The exemplary contact assembly 10 shown in fig. 1-3 includes an outer housing 12 extending between opposite ends 14, 16 of the contact assembly 10. Although outer housing 12 is shown as approximately the shape of a cylindrical can, outer housing 12 may have a different shape. Outer housing 12 may include or be formed from a dielectric material, such as one or more polymers. In another embodiment, outer housing 12 may include or be formed from an electrically conductive material, such as one or more metal alloys.

The end 14 of the housing 12 includes several openings 18 through which current carrying contacts 20, 22 extend. Contacts 20, 22 extend through opening 18 to mate with conductors, such as bus bars, connected to the circuit.

As best shown in fig. 2 and 3, the contactor assembly 10 includes an inner housing 24 disposed within an outer housing 12. The contacts 20, 22 project through an end 26 of the inner housing 24. The inner housing 24 may include or be formed from a dielectric material, such as one or more polymers. The inner housing 24 includes an inner chamber or compartment 28.

Portions of the contacts 20, 22 are disposed in an interior chamber or compartment 28. The inner chamber or compartment 28 may be sealed and loaded with an inert and/or insulating gas such as, but not limited to, sulfur hexafluoride, nitrogen, and the like. The interior chamber or compartment 28 is sealed such that any arc extending from the contacts 20, 22 is contained within the interior chamber or compartment 28 and does not extend out of the interior chamber or compartment 28 to damage the contactor assembly 10 or other components of the electrical circuit.

The contactor assembly 10 shown and described herein is provided for illustrative purposes. The configuration of the contactor assembly 10 and its components may vary without departing from the scope of the present invention.

As best shown in fig. 2-4 and 6, the contacts 20, 22 are elongated bodies extending between a circuit mating end 30 and an engagement end 32. The circuit mating end 30 is coupled to an electrical circuit to electrically couple the contactor assembly 10 to the electrical circuit. In the illustrated embodiment, the engagement end 32 has a non-linear surface 34, such as a curved or arcuate surface 34. The non-linear surface 34 may be, but is not limited to, rounded, arcuate, curvilinear, triangular, spherical, conical, or pyramidal. The nonlinear surface 34 is formed of an electrically conductive material such as, but not limited to, one or more metals or metal alloys. For example, the nonlinear surface 34 may be formed of a silver (Ag) alloy. The use of silver alloy may prevent the non-linear surface 34 from soldering to the mating contact. Alternatively, the non-linear surface 34 may be made of a softer material, such as, but not limited to, copper or a copper alloy.

In the illustrative embodiment shown in fig. 2 and 3, the actuator subassembly 40 moves along or in a direction parallel to a longitudinal axis 42 of the contactor assembly 10 to electrically couple the contacts 20, 22 to each other. The actuator subassembly 40 includes a coupling member 44.

As best shown in fig. 5, the coupling member 44 has contact bridges 46 with mating portions or contact pads 48 disposed at either end thereof. The coupling member 44 is formed of an electrically conductive material such as, but not limited to, one or more metals or metal alloys. The mating segment 48 is formed of an electrically conductive material such as, but not limited to, one or more metals or metal alloys. For example, the fitting portion 48 may be formed of silver (Ag) alloy. The use of silver alloy may prevent the mating portion 48 from being soldered to the non-linear surface 34. Alternatively, the mating portion 48 may be made of a softer material than the coupling member 44, such as, but not limited to, copper or a copper alloy.

The mating segment 48 has a groove or slot 70 extending from a top surface 72 of the mating segment 48 to a bottom surface 74 of the mating segment 48. The groove 70 may extend in a direction parallel to the longitudinal axis of the coupling member 44, in a direction perpendicular to the longitudinal axis 75 of the coupling member 44, or at any other angle relative to the longitudinal axis of the coupling member 44. The recess 70 has a side wall 76 that extends to the top surface 72 of the mating portion 48. The intersection of the side walls 76 and the top surface 72 forms a contact edge 78. In the illustrative embodiment, the contact edge 78 is a curved or rounded edge extending between the sidewall 76 and the top surface 72, as shown in fig. 6 and 7. In other embodiments, as shown in FIG. 8, the sidewalls 76 may extend from the top surface 72 at a 90 degree angle to form the contact edges 78. Other configurations of the edge 78 may also be used, such as, but not limited to, trapezoidal. The opening 79 is provided in the center of the coupling member 44.

The actuator subassembly 40 moves in opposite directions along the longitudinal axis 42 to move the coupling member 44 toward the contacts 20, 22 (closed position, fig. 3) and away from the contacts 20, 22 (open position, fig. 2).

The mating of the mating portion 48 of the coupling member 44 with the non-linear surfaces 34 of the contacts 20, 22 causes an electrical current to flow through the coupling member 44 of the actuator subassembly 40, thereby closing the electrical circuit. In the illustrated embodiment, the mating portion 48 and the coupling member 44 electrically connect the contacts 20, 22 to one another such that electrical current may flow through the non-linear surfaces 34 of the contacts 20, 22, through the mating portion 48 and across the contact bridge 46. The current can flow in either direction.

Figure 2 is a cross-sectional view of the contactor subassembly 10 in an open state according to one embodiment of the present disclosure. The actuator subassembly 40 includes an elongate shaft or armature 50 oriented along the longitudinal axis 42. The armature 50 extends through an opening 79 of the coupling member 44. The coupling member 44 is connected at one end to a shaft or armature 50 using a clip or other known method. The contactor assembly 10 is in the open state because the actuator subassembly 40 is separated from the contacts 20, 22. The actuator subassembly 40 is decoupled from the contacts 20, 22 such that the coupling member 44 does not interconnect or electrically connect the contacts 20, 22 to one another. As a result, current cannot pass through the contacts 20, 22.

In the illustrative embodiment shown, the actuator subassembly 40 includes a magnetized body 52 coupled to a shaft or armature 50. The body 52 may include a permanent magnet that generates a magnetic field or flux oriented along the longitudinal axis 42. The contact assembly 10 includes a coil body 54 surrounding a body 52. The coil body 54 may act as an electromagnet to drive the magnetic body 52 of the shaft 50 along the longitudinal axis 42. For example, the coil body 54 may include wires or other components that surround the magnetic body 52. An electrical current may be applied to the coil body 54 to generate a magnetic field oriented along the longitudinal axis 42. Depending on the direction of the current flowing through the coil body 54, the magnetic field induced by the coil body 54 may have a magnetic north oriented toward the end 14 or toward the end 16 of the outer housing 12.

To drive the actuator subassembly 40 toward the contacts 20, 22, the coil body 54 is energized to generate a magnetic field along the longitudinal axis 42. The magnetic field may move the magnetic body 52 of the actuator assembly 40 along the longitudinal axis 42 toward the contacts 20, 22. In the illustrated embodiment, the armature spring 56 applies a force to the armature 50 in a downward direction toward the end 16 of the outer housing 12. The force exerted by the armature spring 56 prevents the actuator subassembly 40 from moving toward the contacts 20, 22 and engaging the contacts 20, 22 without the coil body 54 generating a magnetic field. The magnetic field generated by the coil body 54 is large enough or strong enough to overcome the force exerted on the armature 50 by the armature spring 56 and drive the armature 50 and the actuator subassembly 40 and the coupling member 44 toward the contacts 20, 22.

Figure 3 is a cross-sectional view of the contactor assembly 10 in a closed state according to one embodiment of the present disclosure. In the closed state, the actuator subassembly 40 has moved far enough within the coupling member 44 along the longitudinal axis 42 such that the mating portion 48 of the coupling member 44 mates with the non-linear surface 34 of the contacts 20, 22. As a result, the actuator subassembly 40 has electrically coupled contacts 20, 22 to close the circuit.

In the closed position, current flows through the non-linear surface 34 of the contact 20, through the first mating segment 48, across the contact bridge 46, through the second contact mating segment 48, and through the non-linear surface 34 of the contact 22.

As the contactor assembly 10 moves to the closed position, the mating portion 48 of the linking member 44 moves into engagement with the non-linear surfaces 34 of the contacts 20, 22. The shape of the non-linear surface 34 and the positioning of the recess 70 in the mating portion 48 results in a plurality (two or more) of contact points 80 (as best shown in fig. 7) being provided between the non-linear surface 34 of the contacts 20, 22 and the edge 78 of the recess 70 of the mating portion 48.

As a result, portions of the nonlinear surface 34 and the mating portion 48 do not contact or engage each other. Thus, any contaminants or particles adhering to the non-linear surface 34 and the mating segment 48 do not interfere with or prevent the contact points 80 from moving into engagement to ensure a proper electrical connection therebetween.

In contrast, the contacts and the mating portion of the known connection member have linear surfaces that are substantially parallel to each other. Thus, any contaminants (e.g., particles as small as 40 microns) located along the surfaces of the mating portions of the contacts or the coupling member will prevent the mating portions of the contacts and the coupling member from moving to the fully mated or closed position, thereby preventing an electrical connection, resulting in an unreliable electrical connection or a contact having a high electrical resistance when the movable and fixed contacts are closed.

As shown in fig. 7, the configuration of the non-linear surfaces 34 of the contacts 20, 22 and the edges 78 of the grooves or slots 70 of the mating portion 48 allows the edges 78 to pierce, break, or penetrate any contaminants that may be present in the contact points 80. In addition, the redundancy of the plurality of contacts 80 provided on each contact 20, 22 also ensures that a proper electrical connection is achieved.

Although the non-linear surface 34 and the groove 70 are shown with respect to the illustrative contacts 20, 22 and the mating portion 48 of the coupling member 44, the non-linear surface 34 and the groove 70 may be used for fixed and movable contacts of other devices having other configurations, such as, but not limited to, switches and relays.