KR20110111533A - Electromagnetic relay assembly - Google Patents

Abstract

The electromagnetic relay enables current to pass through the switch distal end and includes a coil assembly, a rotor or bridge assembly and a switch assembly. The coil assembly includes a coil and a C-shaped core. The coil is wound around a coil axis extending through the core. The core includes a core end portion parallel to the coil axis. The bridge assembly includes a bridge and an actuator. The bridge includes intermediate, lateral and transverse field paths. The actuator extends laterally from the lateral field path. The core end is coplanar with the axis of rotation and is received in the middle of the intermediate and lateral field paths. The actuator is cooperative with the switch assembly. The coil creates a guiding magnetic field through the bridge assembly via the core end to impart bridge rotation about the axis of rotation. Bridge rotation displaces the actuator to open and close the switch assembly.

Description

Electromagnetic Relay Assembly {ELECTROMAGNETIC RELAY ASSEMBLY}

The disclosed invention generally relates to an electromagnetic relay assembly having a uniquely constructed armature assembly. More specifically, the disclosed invention relates to an electromagnetic relay assembly having a magnetically operable rotor assembly for linearly displacing the switch actuator.

In general, the function of an electromagnetic relay is to use a small amount of power in the electromagnet to move the armature which is capable of switching a much larger amount of power. As an example, a relay designer may want the electromagnet to excite using 5 volts and 50 milliamps (250 milliwatts), and the amateur may support 120 volts (240 watts) at 2 amps. Relays are very common in home appliances where there are electronic controls that turn on (or turn off) some application devices, such as motors or lights. The teachings of the present invention are primarily intended for use as a monopole 120-amp pass electromagnetic relay assembly. However, it is contemplated that the nature of the present invention may be applicable to multipole relay assemblies having inherent configurations and functionality as would be enabled by the teachings of the monopole embodiments described herein. Many other electromagnetic relay assemblies, reflected in the art and disclosed in the US patent, are briefly described below.

U. S. Patent No. 6,046, 660 (the '660 patent) to Gruner discloses a latching magnetic relay assembly having a linear motor. The '660 patent teaches a latching magnetic relay capable of delivering currents in excess of 100 amps for use in regulating the transfer of electricity or for other applications requiring switching of currents in excess of 100 amps. The relay motor assembly has an elongated coil bobbin having an axially extending cavity therein. The excitation coil is wound around the bobbin. An approximately U-shaped ferromagnetic frame has a core section disposed within and extending through the axially extending cavity in the elongated coil bobbin. Two contact sections extend generally perpendicular to the core section and rise above the motor assembly. The actuator assembly is magnetically coupled to the relay motor assembly. The actuator assembly consists of an actuator frame operatively coupled to the first and second substantially U-shaped ferromagnetic pole pieces and a permanent magnet. A contact bridge made of a sheet of conductive material copper is operatively coupled to the actuator assembly.

U.S. Patent No. 6,246,306 to the Gruner ('306 patent) discloses an electromagnetic relay with a pressure spring. The '306 patent teaches an electromagnetic relay having a motor assembly having a bobbin fixed to the housing. The core is connected adjacent below the bobbin except for the core end extending from the bobbin. The armature end magnetically couples the core end when the coil is excited. An actuator couples the armature and the plurality of central contact spring assemblies. The center contact spring assembly consists of a center contact spring that is ultrasonically welded onto the center contact terminal without pre-bending. Normally open springs are positioned relatively parallel to the center contact spring. The normally open spring is ultrasonically welded onto the normally open terminal to form the normally open external contact spring assembly. The normally closed outer contact spring is positioned perpendicular to the center contact spring such that the normally closed outer contact spring assembly is in contact with the center contact spring assembly when the center contact spring is not acted upon by the actuator. The normally closed spring is ultrasonically welded onto the normally closed terminal to form the normally closed assembly. The pressure spring urges the center contact spring on the actuator when the actuator is not in use.

U. S. Patent No. 6,252, 478 (the '478 patent) to Gruner discloses an electromagnetic relay. The '478 patent teaches an electromagnetic relay having a motor assembly with a bobbin fixed to the frame. The core is disposed in the bobbin except for the core end extending from the bobbin. The armature end is magnetically coupled to the core end when the coil is excited. An actuator couples the armature with the plurality of movable blade assemblies. The movable blade assembly consists of a movable blade ultrasonically welded onto the center contact terminal. Normally the open blade is positioned relatively parallel to the movable blade. The normally open blade is ultrasonically welded onto the normally open terminal to form the normally open contact assembly. The normally closed contact assembly consists of a third contact rivet and a normally closed terminal. The normally closed contact assembly is positioned perpendicular to the movable blade such that the normally closed contact assembly is in contact with the movable blade assembly when the movable blade is not acted upon by the actuator.

U.S. Patent No. 6,320,485 to the Gruner ('485 patent) discloses an electromagnetic relay assembly with a linear motor. The '485 patent teaches an electromagnetic relay capable of delivering currents in excess of 100 amps for use in regulating the transmission of electricity or in other applications requiring switching of currents in excess of 100 amps. The relay motor assembly has an elongated coil bobbin having an axially extending cavity therein. The excitation coil is wound around the bobbin. An approximately U-shaped ferromagnetic frame has a core section disposed within and extending through the axially extending cavity in the elongated coil bobbin. Two contact sections extend generally perpendicular to the core section and rise above the motor assembly. The actuator assembly is magnetically coupled to the relay motor assembly. The actuator assembly consists of an actuator frame operatively coupled to the first and second substantially U-shaped ferromagnetic pole pieces, and a permanent magnet. A contact bridge made of a sheet of conductive material copper is operatively coupled to the actuator assembly.

U.S. Patent No. 6,563,409 to the Gruner ('409 Patent) discloses a latching magnetic relay assembly. The '409 patent is a relay motor having a first coil bobbin having a first excitation coil wound around it and a second coil bobbin having a second excitation coil wound around it, wherein the first excitation coil and the second All of the excitation coils are the same, the first excitation coil being a relay motor electrically insulated from the second excitation coil, an actuator assembly magnetically coupled to the relay motor and having first and second ends, respectively, It teaches a latching magnetic relay assembly comprising a group of one or two contact bridge assemblies comprising this contact bridge and a spring.

It is an object of the present invention to provide an electromagnetic relay assembly having specific means for damping contact vibrations in the middle of the contacts of the switching assembly. Another object of the present invention is to provide an armature assembly having a rotational axis and rotating under the influence of a magnetic field generated or imparted from an electromagnetic coil assembly. The armature assembly linearly displaces the switch actuator for opening and closing of the switch assembly of the relay. To accomplish these and other readily apparent purposes, the electromagnetic relay assembly of the present invention includes an electromagnetic coil assembly, an armature bridge assembly and a switch assembly as described in more detail below.

The coil assembly essentially comprises a coil, a C-shaped yoke assembly and a coil shaft. The coil is wound around the coil axis and the yoke assembly includes first and second yoke arms. Each yoke arm includes an axial yoke portion that is coaxially aligned with the coil axis and that together forms the rear portion of the C-shaped yoke assembly. Each yoke arm further comprises a yoke end, which is coplanar and substantially parallel to the coil axis.

The armature bridge assembly is rotatable about an axis spaced orthogonally from the coil axis and coplanar with the yoke end. Thus, the armature bridge assembly includes a bridge axis of rotation, a bridge and an actuator arm. The bridge is a middle field path that is relatively closer to the coil axis, a lateral field path that is relatively further near the coil axis, and longitudinal or axially spaced mid-lateral or extending to the middle of the middle and lateral paths. Lateral-medium field paths (or transverse field paths). The actuator arm is cooperative with the lateral field path via its first end and extends laterally away from the lateral field path.

The switch assembly essentially comprises a spring assembly between the switch terminals and the switch terminals. The spring assembly is attached to the second end of the actuator arm. The yoke end is received in the middle of the intermediate and lateral paths. As standard and well established in the art, the coils receive current and create or impart a magnetic field, which provides the bridge rotation around the bridge axis of rotation and the yoke end to linearly displace the actuator arm. Can be guided through the bridge assembly. The displaceable actuator arm functions to actuate the spring assembly in the middle of the open and closed contact positions, the closed contact position allowing current to pass through the switch assembly via the switch distal end.

Certain ambient features of the essential electromagnetic relay assembly include specific means for enhancing spring overtravel, which function to increase the contact pressure in the middle of the switch terminals when the spring assembly is in the closed position. Means for improving spring overtravel further provide means for contact wiping or contact cleaning via improved contact or increased contact pressure. In other words, the improved conduction path through the contact interface may preferably function to burn off residues and / or debris that may otherwise be stopped at the contact surface. The means for improving spring overtravel can also make the function of providing a specific means for damping the vibration of the contact bounce or vibration in the middle of the first and second contacts when switching from the open position to the closed position.

Other objects, as well as specific features, elements and advantages of the present invention, will become apparent or will become apparent from the following detailed description and the accompanying drawings.

Other features of the present invention will become more apparent from consideration of the following brief description of the drawings.

1 is a plan view of an electromagnetic relay assembly of the present invention with the switch assembly in an open position.
2 is a top view of the electromagnetic relay assembly of the present invention with the switch assembly in the closed position.
3 is a top exploded perspective view of the electromagnetic relay assembly of the present invention showing an optional housing cover.
4 is an exploded perspective view of the first terminal assembly of the switch assembly of the electromagnetic relay assembly.
5 is an exploded perspective view of a second terminal assembly of the switch assembly of the electromagnetic relay assembly.
6 is an exploded perspective view of a coil assembly of the electromagnetic relay assembly of the present invention.
7 is a partially exploded perspective view of the rotor assembly of the armature assembly of the electromagnetic relay assembly.
8 is an exploded perspective view of a contact button and a triumvirate spring assembly of a switch assembly of an electromagnetic relay assembly.
FIG. 9 is a partial side view of the triode spring assembly, contact button and armature arm of the present invention showing the contact button in a closed position with the triode spring assembly in a substantially coplanar position. FIG.
FIG. 10 is a partial side view of the trillion spring assembly, contact button and armature arm of the present invention in which the trillion spring assembly shows the contact button in a closed position in an overmoving position to enhance the contact pressure in the middle of the contact button;
FIG. 11 is an enlarged fragmentary side view of the junction of the three-spring spring assembly and upper contact button shown in FIG. 10 showing the three-spring spring assembly in an overmoved position to improve the contact pressure in the middle of the contact button;
12 is a schematic diagram of flux flow through a rotor assembly and a C-shaped core assembly of an electromagnetic relay assembly showing a split and diverted field through the rotor assembly;
FIG. 13 is a switch terminal operatively connected to a triangular spring assembly and contact button showing first and second springs having a centrally located C-shaped fold and a third spring having bends located at an end; Side view of assembly and trillion spring assembly.
FIG. 14 is a partially enlarged cross-sectional view as taken from FIG. 13 showing the bent portion located at the end of the third spring in more detail. FIG.
15 is a schematic diagram of a threshold voltage path guided through a relay distal end disposed adjacent to a rotatable armature assembly showing a distal end magnetic field larger in magnitude than the armature source magnetic field for rotating the armature assembly towards the circuit open position.

Referring now to the drawings, a preferred embodiment of the present invention relates to an electromagnetic relay assembly 10 as shown and referred to in FIGS. The electromagnetic relay assembly 10 of the present invention essentially functions to allow current to pass through the switch distal end 11, as shown and mentioned in Figures 1-5. In order to achieve these and other readily apparent functions, the electromagnetic relay assembly 10 of the present invention is preferably an electromagnetic coil assembly 12, as shown and referred to generally in FIGS. 1-3 and 6, FIG. A rotatable armature assembly 13 as generally shown and mentioned in FIGS. 1-3 and a switch assembly 14 as generally shown and mentioned in FIGS.

The coil assembly 12 of the present invention is preferably an energizing coil 15 as shown and mentioned in FIGS. 1 to 3 and 6, and a C- as shown and mentioned in FIGS. 3, 6 and 12. A core or yoke assembly 16 and a coil shaft 100 generally shown and referred to in FIGS. 1, 2, 6 and 12. Investigation of the mentioned figures in which the energizing coil 15 is wound around the coil shaft 100 and includes first and second electromagnet drive distal ends 17 as shown and mentioned in FIGS. 1-3 and 6. It can be known or understood from. The yoke assembly or C-shaped core assembly 16 of the present invention is axially housed within the coil 15 and preferably comprises a first and a second yoke arm 18, one of which is shown in FIGS. It is shown and mentioned in FIG. 3, all of which are shown and mentioned in FIG. 6. It can be seen from the irradiation of FIG. 6 that the yoke arm 18 comprises an axial yoke portion 19 and a substantially planar yoke end portion 20, which yoke end portion 20 is preferably also shown in FIG. 12. As shown and mentioned, it is parallel to the coil axis 100.

The rotatable armature assembly 13 of the present invention is preferably in the rotor assembly 21 as shown and mentioned generally in FIGS. 1-3 and 7, FIGS. 1-3, 9 and 10. Actuator or actuator arm 22 as generally shown and mentioned and the armature rotation axis 101 as shown and referred to as lines in FIGS. 3 and 7, with points in FIGS. 1, 2, 12 and 15. It is contemplated that this may be described as including. The rotor assembly 21 is preferably a first and second uniformly oriented or polarized rotor magnet 23 as shown and mentioned in FIGS. 7 and 12, FIGS. 1 to 3, 7 and In the rotor plate 25 as shown and mentioned in FIG. 12, in the rotor bracket 26 as shown and mentioned in FIGS. 1 to 3, 7 and 12, in FIGS. 1 to 3 and 7. Rotor housing 27 as shown and mentioned, return spring 28 as shown and mentioned in FIGS. 3 and 7, rotor pin 29 as shown and mentioned in FIGS. 1 and 3, and A rotor mount 30 as shown and mentioned in FIGS.

The rotor bracket 26 is attached or otherwise cooperatively associated with the first end of the actuator arm 22, the rotor plate 25 and the rotor bracket 26 (or portions thereof) preferably It can be seen from the examination of the figures mentioned that they are oriented parallel to each other via the rotor housing 27. In this regard, the first and second rotor magnets 23 are equally dimensioned to equally space the rotor plate 25 and the rotor bracket 26 simultaneously and as shown schematically in FIG. 12. The middle of the rotor plate 25 and the rotor bracket 26 to also provide a guide or path for the so-called Lorentz current or magnetic flux so that it is effectively oriented transversely across the rotor or bridge assembly 21 as well. It can also be seen that

In this regard, the armature assembly 13 can be considered as an armature bridge assembly, which includes a bridge axis of rotation (similar to the armature axis 101) and a bridge cooperatively associated with the armature arm 22. Is considered. In this regard, the bridge is preferably in the intermediate path (similar to the rotor plate 25), the lateral path (similar to the rotor bracket 26) and in the longitudinal or axially spaced mid-lateral direction. Or as a transversal path (similar to the first and second rotor magnets 23). Thus, armature arm 22 may be described as laterally spaced from lateral path or rotor bracket 26 to engage switch assembly 14.

The rotor housing 27 essentially houses, houses and positions the first and second rotor magnets 23, the rotor plate 25 and the rotor brackets 26 to structure the armature assembly 13. It functions to form a bridge similar to. The rotor magnets 23 are evenly directed so that similar poles face the same rotor structure. For example, the north pole of the rotor magnet 23 can face the rotor bracket 26 (the south pole thereby directs the rotor plate 25), or turn It is contemplated that the S pole of the electromagnetic magnet 23 may face the rotor bracket 26 (the N pole thereby facing the rotor bracket).

The rotor housing 27 may preferably further comprise a pin receiving opening or bore for receiving the rotor pin 29 as will generally be seen from the irradiation of FIGS. 3 and 7. The pin receiving opening or bore of the rotor housing 27 enables the rotation of the bridge or armature assembly 13 around the armature axis of rotation 101. The rotor pin 29 extending through the pin receiving bore may be axially fixed to its lower end via the relay housing 48 as shown and mentioned in FIGS. 1-3, and the relay housing 48. Is dimensioned and shaped to receive, receive, and position the coil assembly 12, the armature assembly 13, and the switch assembly 14 as can be readily understood from the survey of FIG. 3. It can also be immediately understood from the survey of FIG. 3 that the relay housing 48 is not essential but can include or cooperate with the relay cover 49.

In this regard, the armature assembly 13 of the invention can be fixed or mounted via the rotor mount 30. The rotor mount 30 can be cooperatively associated with the relay housing 48 (ie fixed to the relay housing 48) to secure the rotor pin 29 axially, and the fixed rotor mount 30 houses and secures the upper end of the rotor pin 29 to enable the user of the relay to effectively operate the electromagnetic relay assembly 10 of the present invention without the relay cover 49. Thus, the means for mounting the rotor mount 30 or rotor assembly or bridge assembly may be described as providing specific means for enabling open directional operation of the electromagnetic relay assembly 10. For example, in certain scenarios it is contemplated that the coverless relay assembly provides certain gains. For example, the relay assembly of the present invention can be observed more immediately during the test procedure. In either case, the rotor mount 30 of the present invention is contemplated to enable uncovered operation of the electromagnetic relay assembly 10 by alternatively securing the armature assembly 13 to the relay housing 48.

The switch assembly 14 of the relay assembly 10 of the present invention is preferably a first switch terminal assembly 31 as shown and referred to generally in FIGS. 1 to 4, FIGS. 1 to 3, 5, A second switch terminal assembly 32 as shown and mentioned in FIGS. 13 and 14 and a set of three as shown and mentioned in FIGS. 1-3, 5, 8-11, 13 and 14 A spring assembly 33. From the examination of the mentioned figures, the first switch terminal assembly 31 preferably comprises a first contact button 34 and a first switch end as in reference numeral 11. In addition, the second switch terminal assembly 32 preferably comprises a second switch end as in reference numeral 11.

The triangular spring assembly 33 preferably comprises a second contact button 37 as shown and referred to in FIGS. 1, 2, 9-11, 13 and 14, and FIGS. A first spring 38, a second spring 39 and a third spring 40 as also shown and mentioned in FIGS. 10 and 13 are included. The first spring 38 preferably has a first contact receiving opening such as 41 in FIG. 8 and a first C-shaped opening as in 42, as well as 70 in FIGS. 13 and 14. It can also be seen that it includes the same end positioned offset or bend. In particular, the first C-shaped opening 42 is preferably concentric with the first contact receiving opening 41. The second spring 39 preferably comprises a second contact receiving opening as in 43 of FIG. 8 and a first C-shaped fold as in 44. It can be seen from the irradiation of FIG. 8 that the first C-shaped fold 44 has a particular first radius of curvature. The third spring 40 preferably comprises a third contact receiving opening as in 45, a second C-shaped opening as in 46 and a second C-shaped fold as in 47. do.

The second C-shaped opening 46 is preferably concentric with the third contact receiving opening 45, and the second C-shaped folded portion 47 has a second radius of curvature, the second radius of curvature being It can also be seen that the size is larger than the first radius of curvature (of the first C-shaped fold 44). The second spring 39 is interposed between the first and third springs 38, 40 via the second contact button 37, as received or extended through the contact receiving openings 41, 43, 45. The first C-shaped fold 44 is concentric (with respect to the folding axis) in the second C-shaped fold 47. The first and second contact buttons 34, 37 or contacts are oriented or juxtaposed apart from one another, as generally shown in FIGS. 1, 2, 9 and 10. In a preferred embodiment, the triangular spring assembly 33 is biased at the open contact position in the middle of the first and second switch distal ends 11 and the armature arm 22 as shown most clearly in FIGS. 9 and 10. Is attached to (lateral end of).

The first and second C-shaped openings 42 and 46 and the end-positioned offset or bend 70 allow for improved overtravel to increase the intermediate contact pressure of the first and second contact buttons 34 and 37. It is contemplated that the function of providing a specific means for this can be improved. In this regard, the reader is further guided to FIGS. 9 and 10. From the relative comparison of the mentioned figures, it can be seen that the terminal side end 53 of the spring assembly 33 can be operated past the planar portion of the spring assembly directly adjacent to the stem 51 of the contact button 37. Thus, the planar portion of the spring assembly immediately adjacent (and radially) to the stem 51 of the contact button 37 forms a button stackable spring portion, as indicated by reference numeral 52 in FIGS. 8 and 11. From the irradiation of Figs. 8 and 11, the button stackable spring portion 52 is stacked on the contact button 37, and the terminal side end 53 is elastic as shown at 50 to enable the overtravel. Is deformed.

In other words, the material (preferably copper) of the spring element with the C-shaped opening is more readily elastically deformable at the distal end of the C-shaped opening as in reference numeral 50 in FIG. 8. In particular, the elastic deformation of the material adjacent to the distal end 50 does not result in significant brittleness of the underlying material lattice (ie does not impart significant undesirable lattice dislocations), and thus the C-shaped opening structure of the trillion spring assembly. Or the feature provides robust means for improved overtravel to also provide certain added pressure in the middle of the contact buttons 34, 37 to enhance the conductive contact (es) therebetween. The end-positioned offset or bend 70 also provides improved overtravel means for increasing the contact pressure of the contacts 34, 37 and reducing the contact bounce.

Thus, conduction through the contact buttons 34, 37 is improved via C-type opening enablement and / or improved overtravel, as is generally shown in FIG. Improved contact and consequent conduction provide specific means for improved contact wiping, and it is contemplated that the contact wiping or contact cleaning means are thus further improved via improved overtravel. In this regard, the relay assembly 10 of the present invention is considered to have a self-cleaning feature as essentially enabled by the C-shaped openings 42, 46. In addition, the C-shaped openings 42, 46 (offset or bend 70) are closed from the open contact state or open switch position (as generally shown in FIG. 1) or closed switch position (as shown in FIG. 2). It is contemplated that a particular means for reducing contact bounce in the middle of the contact buttons 34, 37 or otherwise cushioning contact vibrations when switched to a switch (as generally shown) may be well provided.

From the irradiation of FIG. 12, the core or yoke end 20 is loosely received between the rotor plate 25 and the rotor bracket 26, the armature rotational axis 10 is coplanar with the yoke end 20, It can be immediately understood that this axis of rotation 101 extends through the rotor pin 29 (not specifically shown in FIG. 20). As can be readily appreciated, the energizing coil 15 functions to receive a current thereby generating a magnetic field as further shown and mentioned as a vector 102 in FIG. 12. As can be seen from the investigation of the mentioned figures, the magnetic field 102 is subjected to a rotor assembly (essentially the rotor bracket 26) to impart armature or bridge rotation around the armature rotational axis 101 via magnetically induced torque. Formed by the rotor magnet 23 and the rotor plate 25].

Thus, the rotary bracket 26 functions to linearly displace the actuator arm 22, which is displaced from the preferred spring biased open position (as generally shown in FIG. 1). It functions to operate the trillion spring assembly 33 in the closed position (as shown generally in FIG. 2). The material configuration of the relay assembly 10 (considered to be within the skill of those skilled in the art) and the closed position are essentially 120-ampere currents with the first and second contact buttons 34 and 37 and the switch distal end 11 And through the switch assembly 14. When the coil assembly 12 is currently at rest and the magnetic field is effectively removed, the return spring 28 preferably returns the trillion spring assembly 33 to the preferred spring biased open position as generally shown in FIG. Can function to improve. If a fault current condition occurs, the electromagnetic relay 10 may preferably further comprise specific closed contact default means, wherein the closed contact default means are first and second during said default current or short circuit condition (s). It is for forcibly closing the contact buttons 34 and 37. In this regard, it is contemplated that the path follows the Lorentz current or magnetic field path as generally shown in FIG. 12 by the vector arrow 102.

It is also contemplated that the electromagnetic relay according to the present invention may include specific means for defaulting to an open contact position during threshold terminal based current conditions. In this regard, it is noted from traditional electromagnetic theory that streaming charge carriers develop a magnetic field radially adjacent to the direction of the carrier stream. Thus, the reader is guided to FIG. 15, which is a schematic diagram of a threshold current path as 71 which is guided through relay terminals 31, 32 via contact buttons 34, 37. The magnetic force vector, 103, is shown as terminal originated via the charge carrier current flowing through path 71. After reaching a certain threshold amount of current, the magnetic field generated through the terminals 31, 32 can interact with the permanent magnet or rotor magnet 23 of the rotatable armature assembly 13. The magnet 23 has an outwardly directed intrinsic magnetic field as referred to as the vector arrow 104, whose force is smaller than the force at the vector arrow 103. As indicated, the difference in force between 104 and 103 allows the rotatable armature assembly 13 to rotate towards the open contact position as schematically shown in FIG. 15. This feature can be corrected by the distance between the armature and the stop contact and the size and strength of the magnet 23.

While the description includes many details, these details should not be construed as limitations on the scope of the invention, but rather as illustrations of the invention. For example, the present invention may be referred to as teaching or initiating an electromagnetic relay assembly that essentially allows current to pass through the switch distal end, which may be referred to as a coil assembly, a bridge assembly, and a switch assembly. Include. The coil assembly includes a coil, a coil shaft and a C-shaped core. The coil is wound around the coil shaft 100, and the coil shaft 100 extends through the core shown at 60 in FIG. 12. The core 60 includes a core end 20, and the core end 20 is substantially parallel to the coil axis 100.

The bridge assembly comprises a bridge as the axis of rotation and a reference numeral 61 in FIGS. 12 and 15; And a switch actuator as 22. Bridge 61 includes intermediate field path 63 (ie, relatively closer to core 60), lateral field path 64 (ie, relatively closer to core 60) and intermediate and In the middle of the lateral field paths 63, 64 is an axially spaced transverse path 65 for guiding the field as 102. The actuator arm 22 is cooperable with and extends away from the lateral path 64 (not specifically shown in FIG. 12). The core end 20 is preferably coplanar with the axis of rotation 101 and is received in the middle of the intermediate and lateral paths 63, 64.

The transverse path 65 provides specific field-switching means for transversing the magnetic field 102 relative to the coil axis 100 and for magnetically inducing torque, the magnetically induced torque being the switch actuator 22. It is contemplated to have a function that works. The field shifting means can also be described as including a specific field shifting means (two axis opposite paths as 66 in FIG. 12) for generating a magnetic couple for the magnetically induced torque.

A switch assembly, such as reference numeral 14, is also cooperable with actuator arm 22, which is essentially a coupling between bridge assembly 61 and switch assembly 14. The coil functions to generate or impart a magnetic field as shown by the vector at 102. The magnetic field 102 is directable through the bridge assembly 61 via the core end 20 to impart bridge rotation about the axis of rotation 101 via magnetically induced torque. Bridge rotation functions to displace actuator arm 22, which displaced actuator arm 22 physically opens and closes switch assembly 14. As will be immediately understood in the art, the closed switch assembly 14 allows current to pass through it.

The switch assembly 14 includes specific spring means for enhancing spring overtravel, which means for improving the closed switch position by increasing the contact pressure in the middle of the contact buttons 34, 37. The spring means for improving spring overtravel further provide contact wiping means and vibration dampening means. The contact wiping means is contemplated to effectively self-clean the switch assembly 14, and the vibration damping means function to dampen the contact vibrations when switching from the open switch position to the closed switch position. The spring means for improving spring overtravel is thus said to improve the closed switch position by increasing the contact pressure in the middle of the contacts, maintaining the contact interface free of residue, and dampening the contact vibrations when closing the contacts. Can lose.

Although the present invention has been described with reference to a number of embodiments, the novel devices or relays are not intended to be limited thereby, and their modifications are intended to be included as falling within the broad scope and spirit of the disclosure and the accompanying drawings. Is considered. For example, the specification supports an electromagnetic relay assembly primarily intended for use as a monopole 120-amp pass relay assembly. However, it is contemplated that the nature of the present invention may be applied to a multipole relay assembly having its own configuration and functionality but enabled by the teachings of the monopole embodiments described herein.

10: electromagnetic relay assembly 12: electromagnetic coil assembly
13: amateur assembly 15: energized coil
16: yoke assembly 17: drive distal end
18: York arm 19: York part
20: yoke end 21: rotor assembly
25: rotor plate 26: rotor bracket
27: rotor housing 30: rotor mounting
33: 3-piece spring assembly 34, 37: contact button
48: relay housing 49: cover

Claims (29)

An electromagnetic relay assembly for selectively enabling current to pass through a switch end, the electromagnetic relay assembly comprising:
An electromagnetic coil assembly comprising an energizing coil, a yoke assembly, and a coil shaft, the coil wound around the coil shaft and including first and second electromagnet driving ends, the yoke assembly including first and second yoke arms. And the yoke arms comprise an axial yoke portion and a yoke end portion, respectively;
An armature assembly comprising a rotor assembly and a rotor axis of rotation, the rotor assembly comprising first and second rotor magnets, a rotor plate and a rotor bracket, the rotor bracket including an actuator, and The rotor magnets having a similar orientation and extending in the middle of the rotor bracket opposite the rotor plate and the rotor axis of rotation; And
A switch assembly comprising first and second switch terminals and a triumvirate spring assembly, the first switch terminal comprising a first contact and a first switch end, and the second switch terminal being a second switch end Wherein the spring assembly comprises a second contact and three spring elements, the first spring element comprises a first C-type opening, and the first C-type opening is in the first contact receiving opening. Concentric to the second spring, the second spring comprising a second contact receiving opening, the third spring including a third contact receiving opening and a second C-shaped opening, and the second C-shaped opening being the second Concentric to the contact receiving opening, the second spring is interposed between the first and third spring via the second contact, the first and second contacts are juxtaposed adjacent to each other, and the spring assembly The liquid Attached to the heater, the yoke end is received between the rotor plate and the rotor bracket, the rotor axis of rotation is coplanar with the yoke end, the coil is for generating a magnetic field, and the magnetic field is Guiding through the yoke end via the rotor assembly to impart armature rotation around the rotor axis of rotation, the rotor bracket for displacing the actuator, the actuator being intermediate between the open and closed positions And to operate the spring assembly, wherein the closed position is to allow current to pass through the switch assembly via the first and second contacts and the switch distal end. Relay assembly. The method of claim 1, wherein the C-shaped openings provide improved spring overtravel means, wherein the improved spring overtravel increases the contact pressure in the middle of the first and second contacts when the spring assembly is in the closed position. Electromagnetic relay assembly for increasing. 3. The electromagnetic relay assembly of claim 2 wherein the improved spring overshifting means provides contact wiping means, wherein the contact wiping means is for cleaning the first and second contacts. The electromagnetic relay assembly of claim 1, wherein the C-shaped openings provide a means for damping contact vibrations intermediate between the first and second contacts when switching from the open position to the closed position. 2. The electromagnetic relay assembly of claim 1, wherein the rotor assembly comprises a return spring, the return spring to enhance the return of the spring assembly to the open position when the coil is currently at rest. 2. The electromagnetic relay assembly of claim 1 comprising rotor mounting means, wherein the rotor mounting means is for enabling open direct operation of the electromagnetic relay. 2. The electromagnetic relay assembly of claim 1, comprising closed contact default means, wherein the closed contact default means is forcing the first and second contacts to the closed position during a fault current condition. 2. The electromagnetic relay assembly of claim 1 including means for defaulting to an open contact position during a threshold terminal based current condition. An electromagnetic relay for allowing current to pass through a switch terminal,
An electromagnetic coil assembly comprising a coil, a C-shaped yoke assembly and a coil shaft, wherein the coil is wound around the coil shaft, the yoke assembly includes first and second yoke arms, and the yoke arms are axial yokes An electromagnetic coil assembly comprising a portion and a yoke end portion, respectively;
An armature bridge assembly comprising a bridge axis of rotation, a bridge and an actuator arm, the bridge comprising a middle field path, a lateral field path and longitudinally spaced transverse field paths, the actuator arm from the lateral field path. Extending laterally, the armature bridge assembly; And
A switch assembly comprising switch terminals and a spring assembly, the spring assembly attached to the actuator arm and extending in the middle of the switch terminals, the yoke end being received in the middle of the intermediate and lateral field paths; The bridge axis of rotation is coplanar with the yoke end, the coil is for receiving current and generating a magnetic field, and the magnetic field is adapted to impart bridge rotation around the bridge axis of rotation and to displace the actuator arm. Guiding through the bridge assembly via the displaceable actuator arm for operating the spring assembly between an open contact position and a closed contact position, the closed contact position via the switch assembly via the switch assembly And said switch assembly for allowing electrical current to pass therethrough. 10. The electromagnetic relay of claim 9 including means for enhancing spring overtravel, wherein the means is for increasing contact pressure in the middle of the switch terminals when the spring assembly is in the closed contact position. 11. The electromagnetic relay of claim 10 wherein the means for improving spring overtravel provides contact wiping means, and the contact wiping means for cleaning the switch terminals. 10. The electromagnetic relay of claim 9 including means for damping contact vibrations intermediate between the first and second contacts when switching from the open contact position to the closed contact position. 10. The electromagnetic relay of claim 9 comprising bridge mounting means, wherein the bridge mounting means are for enabling open directional operation of the electromagnetic relay. 10. The electromagnetic relay of claim 9 including means for defaulting to a closed contact position during a fault current condition. 10. The electromagnetic relay of claim 9 including means for defaulting to an open contact position during threshold terminal based current conditions. An electromagnetic relay for allowing current to pass through a switch terminal,
A coil assembly comprising a coil, a coil shaft, and a C-shaped core, the coil wound around the coil shaft, the coil shaft extending through the core, the core comprising a core end portion, the core end portion The coil assembly parallel to the coil axis;
A bridge assembly comprising an axis of rotation, a bridge and an actuator, wherein the bridge includes an intermediate field path, a lateral field path and a spaced transverse field path, the actuator extending from the lateral field path, the core end being The bridge assembly coplanar with the axis of rotation and received in the middle of the intermediate and lateral field paths; And
A switch assembly, wherein the actuator is cooperable with the switch assembly, the coil is for generating a magnetic field, and the magnetic field is passed through the core end portion to impart bridge rotation around the axis of rotation via magnetic induced torque. Guided through a bridge assembly, the bridge rotation is for displacing the actuator, the displaceable actuator for opening and closing the switch assembly, the closed switch assembly allowing current to pass through it To provide the switch assembly. 17. The electromagnetic relay of claim 16 wherein the switch assembly comprises spring means for enhancing spring overtravel, wherein the means is for enhancing the closed switch position. 18. The electromagnetic relay of claim 17 wherein the spring means for enhancing spring overtravel provides contact wiping means, and the contact wiping means for cleaning the switch assembly. 17. The electromagnetic relay of claim 16 including means for damping switch vibrations when switching from the open switch position to the closed switch position. 17. The electromagnetic relay of claim 16, comprising bridge mounting means, wherein the bridge mounting means are for enabling open direct operation of the electromagnetic relay. 17. The electromagnetic relay of claim 16 including means for defaulting to a closed contact position during a fault current condition. 17. The electromagnetic relay of claim 16 including means for defaulting to an open contact position during a threshold terminal based current condition. 18. The apparatus of claim 17, wherein the switch assembly comprises a spring assembly, the spring assembly comprising a contact portion and a C-type opening, the contact portion and the C-type opening are concentric, and the C-type opening is Electromagnetic relays that provide spring means for improving spring overtravel. 20. The apparatus of claim 19, wherein the switch assembly comprises a spring assembly, the spring assembly comprising a contact portion and a C-type opening, the contact portion and the C-type opening are concentric, and the C-type opening is An electromagnetic relay providing a means for damping switch vibrations. An electromagnetic relay for allowing current to pass through a switch terminal,
A coil assembly comprising an energizing coil and a coil shaft, the coil for generating a magnetic field;
An armature assembly comprising a switch actuator and a field shifting means, said field shifting means for transversing said magnetic field relative to said coil axis and magnetically inducing torque, said magnetically induced torque being said switch actuator. For operating the armature assembly; And
An electromagnetic relay comprising a switch assembly cooperable with the switch assembly to allow current to pass therethrough. 26. The electromagnetic relay of claim 25, wherein said field switching means comprises field dividing means, said field dividing means for creating a magnetic couple around said magnetically induced torque. 27. The electromagnetic relay of claim 25 wherein the switch assembly includes means for damping switch vibrations when switching from an open switch position to a closed switch position. 27. The electromagnetic relay of claim 25 including means for defaulting to an open contact position during threshold terminal based current conditions. 26. The electromagnetic relay of claim 25 comprising means for enabling open directional operation of the electromagnetic relay.

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