CN102388427B - Electromagnetic relay assembly - Google Patents

Abstract

An electromagnetic relay enables current to pass through switch termini and comprises a coil assembly, a rotor or bridge assembly, and a switch assembly. The coil assembly comprises a coil and a C-shaped core. The coil is wound round a coil axis extending through the core. The core comprises core termini parallel to the coil axis. The bridge assembly comprises a bridge and an actuator. The bridge comprises medial, lateral, and transverse field pathways. The actuator extends laterally from the lateral field pathway. The core termini are coplanar with the axis of rotation and received intermediate the medial and lateral field pathways. The actuator is cooperable with the switch assembly. The coil creates a magnetic field directable through the bridge assembly via the core termini for imparting bridge rotation about the axis of rotation. The bridge rotation displaces the actuator for opening and closing the switch assembly.

Description

Electromagnetic relay device

Technical field

Disclosure invention relates generally to a kind of electromagnetic relay device of the built-in armature component through unique fit.More specifically, disclosure invention relates to a kind of electromagnetic relay device, and this device has the rotor assembly of field drives, for the position of moving switch magnetizing exciter assembly magnetizing exciter linearly.

Background technology

Usually, the function of electromagnetic relay moves armature by the small-power of electromagnet, and this armature can the much bigger power of switch.Exemplarily, relay design person can require that electromagnet connects 5 volts of voltages and 50 milliamperes of electric currents (250 milliwatt), and armature can support the voltage (240 watts) of 120 volts when 2 peace electric current.Relay is very common in household electrical appliance, has electronic control circuit for connecting the application apparatus of (or disconnection) such as rotor or lamp and so in these electrical equipment.Present inventive concept mainly as one pole, overcurrent is the electromagnetic relay device of 120 peaces.But, also contemplate a main idea of the present invention and be applied to multipole relay device, unique 26S Proteasome Structure and Function can be made it have by the aim of the one pole embodiment proposed in publication of the present invention.Below concise and to the point reflection the present art is described and disclosed in United States Patent (USP) other electromagnetic relay devices several.

The patent No. being presented to Gruner is 6,046, United States Patent (USP) (' 660 patent of 660) a kind of magnetic latching relay device with line rotor is disclosed.The magnetic latching relay that ' 660 patent is explained can transmit the electric current being greater than 100 peaces, can be used for regulating the transmission of electric current or requiring that switching current is greater than the application of 100 peaces for other.Relay rotor assembly has elongated coil-winding cylinder, has an axially extended cavity in it.Excitation coil is wound around around reel.Be placed with core section in the ferromagnetic framework being generally U-shaped, extend in the axially extended cavity in elongate coil reel.Cross section, two contacts is generally perpendicular to core section and extends, and appears at the top of rotor assembly.Magnetizing exciter assembly magnetizing exciter assembly and relay rotor assembly carry out magnetic coupling.Magnetizing exciter assembly is made up of the magnetizing exciter framework and permanent magnet being coupled to the first and second A ferromagnetic pole piece being generally U-shaped in the running.The contact carriage become by one piece of electric conducting material copper is coupled with magnetizing exciter assembly in the running.

The patent No. being presented to Gruner is 6,246, United States Patent (USP) (' 306 patent of 306) a kind of electromagnetic relay with stage clip is disclosed.The electromagnetic relay that ' 306 patent is explained has rotor assembly, and this assembly is with the reel be fixed on bracket.Magnetic core is close to below reel, and magnetic core end stretches out from reel.When the coil is energized, armature end closes because of magnetic force and magnetic core joining distal ends.Magnetizing exciter assembly combines with armature and multiple central contact spring assembly.Central contact spring assembly is made up of central contact spring, and this spring is not bending in advance, and is welded to central contact terminals by with supersonic speed.The spring of usually opening a way is placed on the position parallel with central contact spring.This spring of usually opening a way is welded to the terminals of open circuit usually with supersonic speed, form the external contact spring assembly of usually opening a way.Usually closed circuit external contact spring is placed in the position perpendicular to central contact spring, makes when center contact spring is not subject to the effect of magnetizing exciter, and this usually closed circuit external contact spring contacts with central contact spring assembly.This usually closed circuit spring is welded to usually closed circuit terminals by with supersonic speed, to form usually closed circuit assembly.When not using magnetizing exciter, stage clip can be exerted pressure to the central contact spring above magnetizing exciter.

The patent No. being presented to Gruner is 6,252, United States Patent (USP) (' 478 patent of 478) a kind of electromagnetic relay is disclosed.The electromagnetic relay that ' 478 patent is explained has rotor assembly, and this assembly is with the reel being fixed on support.Magnetic core is placed on reel inside, only has magnetic core end to stretch out from reel.When the coil is energized, armature end closes with magnetic core joining distal ends because of magnetic force.Magnetizing exciter engages with armature and multiple movable gate knife assembly.Movable gate knife assembly is made up of movable plug-in strip, and this movable plug-in strip is welded to central contact terminals by with supersonic speed.The plug-in strip of usual open circuit is placed in the position parallel with movable plug-in strip.This plug-in strip of usually opening a way is welded to the terminals of open circuit usually with supersonic speed, to form the contact assembly of open circuit usually.The contact assembly of usual open circuit is made up of another contact rivet and usually closed circuit terminals.Usually closed circuit contact assembly is placed in the position perpendicular to movable plug-in strip, and make when movable plug-in strip is not subject to the effect of magnetizing exciter, this usually closed circuit contact assembly contacts with this movable gate knife assembly.

The patent No. being presented to Gruner is 6,320, United States Patent (USP) (' 485 patent of 485) a kind of electromagnetic relay with line rotor is disclosed.The electromagnetic relay that ' 485 patent is explained can transmit the electric current being greater than 100 peaces, can be used for regulating the transmission of electric current or requiring that switching current is greater than the application of 100 peaces for other.Relay rotor assembly has elongated coil-winding cylinder, has an axially extended cavity in it.Excitation coil is wound around around reel.Be placed with core section in the ferromagnetic framework being generally U-shaped, extend in the axially extended cavity in elongated coil-winding cylinder.Cross section, two contacts is generally perpendicular to core section and extends, and appears at the top of rotor assembly.Magnetizing exciter assembly and relay rotor assembly carry out magnetic coupling.Magnetizing exciter assembly is made up of the magnetizing exciter framework and permanent magnet being coupled to the first and second A ferromagnetic pole piece being generally U-shaped in the running.The contact carriage become by one piece of electric conducting material copper is coupled with magnetizing exciter assembly in the running.

The patent No. being presented to Gruner is 6,563, United States Patent (USP) (' 409 patent of 409) a kind of magnetic latching relay device is disclosed.The magnetic latching relay device that ' 409 patent is explained comprises relay rotor, the first excitation coil is wrapped around its first coil reel, the second excitation coil is wrapped around its second coil-winding cylinder, the first described excitation coil is identical with the second described excitation coil, and the first described excitation coil and the second described excitation coil are electric insulations; Magnetizing exciter assembly, it and described relay rotor and the described magnetizing exciter assembly with the first end and the second end both have magnetic coupling relation; And one group or two groups of contact carriage assemblies, described contact carriage assembly is often organized and is all included contact carriage and spring.

Summary of the invention

A target of the present invention is to provide a kind of electromagnetic relay device, and this device has certain to suppress the component of contact vibration between switch module contact.Further object of the present invention is to provide a kind of armature component, and this assembly has rotating shaft and rotates under the magnetic field induction that electromagnetic coil assembly produced or conducted.The position of this armature component moving switch magnetizing exciter linearly, to switch on and off the switch module of relay.In order to reach these and other apparent targets, electromagnetic relay device disclosed by the invention is made up of electromagnetic coil assembly, armature axle assemble and switch module, is described in detail below.

Coil block mainly comprises coil, C shape yoke assembly and coil axes.Coil winding is on coil axes, and yoke assembly comprises the first yoke arm and the second yoke arm.Each yoke arm comprises the axial curvature with coil axes co-axially align, and they form the rear portion of C shape yoke assembly jointly.Again and then comprise yoke end, these yoke ends are coplanar to each yoke arm, and substantially parallel with coil axes.

Armature axle assemble can around to separate with coil axes and orthogonal and coplanar with yoke end axle rotates.Such armature axle assemble comprises bridge rotating shaft, bridge and magnetizing exciter arm.Bridge comprise relatively close to coil axes intermediate field path, relatively away from the lateral field path of coil axes and the longitudinal direction extended between intermediate field path and lateral field path or axially spaced centre to side or side to middle path, field (or transverse field path).Magnetizing exciter arm matches with lateral field path by its first end, and extends laterally away from lateral field path.

Switch module mainly comprises switch terminal, and the spring assembly between switch terminal.Spring assembly is connected to the second end of magnetizing exciter arm.Yoke end is housed inside between intermediate field path and lateral field path.As standard and the very ripe technology of this area, coil received current, and produce or conduct magnetic field, axle assemble directly can be passed by yoke end in this magnetic field, makes bridge carry out rotating around bridge rotating shaft and move the position of magnetizing exciter arm linearly.The function of the magnetizing exciter arm of this moveable position drives the spring assembly be between break contacts position and circuit closing contact position, and wherein circuit closing contact position allows electric current to pass through switch module via tail end of switch.

Some miscellaneous function of this basic electromagnetic relay device comprises the component that certain strengthens the spring excess of stroke, and the effect of this component increases pressing between switch terminal when spring assembly is in closed circuit position.This component for strengthening the spring excess of stroke provide further by strengthen contact or increase press the component carrying out contact wiping or contact clean.In other words, conductive path interface, contact strengthened can burn remnants and/or the chip that otherwise may stay contact surface well.The component strengthening the spring excess of stroke also may provide certain component, for suppressing the contact between the first contact and the second contact to be upspring or contact chatter when being switched to closed circuit position from open-circuit position.

Tell about below in conjunction with accompanying drawing, by make other targets of the present invention and concrete function wherein, element and advantage better clear, obvious.

Accompanying drawing explanation

Other functions of the present invention can be clearer after carrying out brief description to patent accompanying drawing below:

Fig. 1 is the plane graph of electromagnetic relay device of the present invention, and its switch module is in open-circuit position.

Fig. 2 is the plane graph of electromagnetic relay device of the present invention, and its switch module is in closed circuit position.

Figure 3 shows that the top perspective exploded views of electromagnetic relay device of the present invention, an optional cabinet cover is shown.

Fig. 4 is the decomposition diagram of the first Wiring terminal assembly of the switch module of electromagnetic relay device.

Fig. 5 is the decomposition diagram of the second Wiring terminal assembly of the switch module of electromagnetic relay device.

Fig. 6 is the decomposition diagram of the coil block of electromagnetic relay device of the present invention.

Fig. 7 is the partial, exploded perspective view of the rotor assembly of the armature component of electromagnetic relay device.

Fig. 8 is three spring assemblies of the switch module of electromagnetic relay device and the decomposition diagram of contact button.

Figure 9 shows that the partial side view of three spring assemblies, contact button and the armature arm in the present invention, shown contact button is in closed circuit position, and three spring assemblies are substantially in coplanar relation.

Figure 10 shows that the partial side view of three spring assemblies, contact button and armature arm in the present invention, shown contact button is in closed circuit position, and three spring assemblies are in travel position for strengthening pressing between contact button.

Figure 11 shows that the Partial enlarged side view of three spring assemblies and contact button junction, top, separately have Figure 10 to show three spring assemblies herein and be in travel position for the situation about pressing strengthened between contact button.

Figure 12 is schematic diagram, shows by the C shape core assembly of electromagnetic relay device and the magnetic flux flow of rotor assembly and is turned to by rotor assembly and the field flow separated.

Figure 13 shows that the end view of the switch terminal assembly being connected to three spring assemblies and contact button in the running, three spring assemblies show has C shape fold in the middle of the first and second springs, and the 3rd spring end band elbow.

Figure 14 is the partial cross section's enlarged drawing intercepted from Figure 13, is shown specifically the elbow of the 3rd spring end.

Figure 15 is schematic diagram, show through being placed on the threshold current path with the relay wiring end of rotatable armature component adjoiner, and the magnetic field intensity showing terminals is greater than the magnetic field of armature, thus armature component can be rotated to the position of open circuit.

Embodiment

Referring now to accompanying drawing, the preferred embodiments of the present invention relate to electromagnetic relay device 10, see Fig. 1 to Fig. 3.Electromagnetic relay device 10 of the present invention mainly plays and allows electric current by tail end of switch 11 selectively, see Fig. 1 to 5.In order to reach these and other apparent functions, electromagnetic relay device 10 of the present invention preferably includes electromagnetic coil assembly 12, substantially see Fig. 1 to Fig. 3 and Fig. 6; Rotatable armature component 13, substantially see Fig. 1 to Fig. 3; Switch module 14, substantially see Fig. 1 to 5.

Coil block 12 of the present invention preferably includes conductive coil 15, see Fig. 1 to Fig. 3 and Fig. 6; C shape magnetic core or yoke assembly 16, see Fig. 3, Fig. 6 and Figure 12; Coil axes 100, substantially see Fig. 1, Fig. 2, Fig. 6 and Figure 12.Can see or recognize by observing these mentioned figure, conductive coil 15 to be wrapped on coil axes 100 and to comprise the first and second Electromagnetic Drive ends 17, see Fig. 1 to Fig. 3 and Fig. 6.Yoke assembly of the present invention or C shape core assembly 16 being axially housed inside in coil 15, and preferably include the first and second yoke arms 18, and one of them can see Fig. 1 to Fig. 3, can see Fig. 6 both it.Can find out by observing Fig. 6, each yoke arm 18 comprises axial curvature 19 and the basic yoke end 20 in plane, and this yoke end 20 is preferably parallel with coil axes 100, and this can with further reference to Figure 12.

Through considering, rotatable armature component 13 of the present invention can be described as preferably including rotor assembly 21, substantially see Fig. 1 to Fig. 3 and Fig. 7; Magnetizing exciter or magnetizing exciter arm 22, substantially see Fig. 1 to Fig. 3, Fig. 9 and Figure 10; And armature rotating shaft 101, see the point represented in Fig. 1, Fig. 2, Figure 12 and Figure 15, and the line represented in Fig. 3 and Fig. 7.Rotor assembly 21 preferably includes the first and second rotor magnets 23 unanimously pointing to or polarize, see Fig. 7 and Figure 12; Rotor sheet 25, see Fig. 1 to Fig. 3, Fig. 7 and Figure 12; Rotor spider 26, see Fig. 1 to Fig. 3, Fig. 7 and Figure 12; Rotor casing 27, see Fig. 1 to Fig. 3 and Fig. 7; Return spring 28, see Fig. 3 and Fig. 7; Rotor clamp 29, see Fig. 1 and Fig. 3; Rotor mounting 30, see Fig. 1 to Fig. 3.

Can find out by observing these mentioned figure, rotor spider 26 is attached to or otherwise contacts the first end at magnetizing exciter arm 22, and rotor sheet 25 and rotor spider 26 (or part wherein) preferably reach via the orientation of rotor casing 27 and be parallel to each other.In this point, can find out further, first and second rotor magnet 23 sizes are equal, force and extend between rotor sheet 25 and rotor spider 26, thus with rotor sheet 25 with rotor spider 26 is equidistant is separated by, and and then provide guide rail or path, make so-called Lorentz lorentz's electric current or magnetic flux effectively cross rotor or axle assemble 21, as signal Figure 12 shown in.

Last point, through considering, armature component 13 can be considered to armature axle assemble, the bridge that this axle assemble comprises bridge rotating shaft (similar with armature rotating shaft 101) and is associated with armature arm 22.In this case, bridge can be understood or be described as preferably including intermediate path (being similar to rotor sheet 25), lateral approach (being similar to rotor spider 26) and several longitudinal or axially spaced centre to side or transverse path (being similar to the first and second rotor magnets 23).Armature arm 22 can be described as like this extending away from lateral approach or rotor spider 26, to combine with switch module 14.

The major function of rotor casing 27 is accommodations, settles and location the first and second rotor magnets 23, rotor sheet 25 and rotor spider 26, to form the class bridge construction of armature component 13.The sensing of rotor magnet 23 is consistent, to make homopolarity in the face of identical rotor structure.Such as, through considering, the arctic possibility of rotor magnet 23 is in the face of rotor spider 26 (therefore south face is to rotor sheet 25), or the South Pole of rotor magnet 23 may in the face of rotor spider 26 (therefore north pole face is to rotor sheet 25).

Rotor casing 27 may further include the aperture or boring that hold clamp, and to hold rotor clamp 29, this can see substantially by observing Fig. 3 and Fig. 7.Rotor casing 27 for hold clamp aperture or boring bridge or armature component 13 can be made to rotate around armature rotating shaft 101, rotor clamp 29 extends through the boring holding clamp, lower end can be axially fixed in via relay casing 48, see Fig. 1 to Fig. 3, the size and dimension of relay casing 48 can hold, settle and set winding assembly 12, armature component 13 and switch module 14, and this can be readily appreciated that by observing Fig. 3.Observe Fig. 3 can be easier to understand, relay casing 48 can but be not must comprise relay cover 49 or cooperate with it.

An in the end point, remembers that armature component 13 of the present invention can fix via rotor mounting 30 or lay.Rotor mounting 30 can be related to relay casing 48 (being namely fixed on relay casing 48) and carry out axial restraint rotor clamp 29, and the rotor mounting 30 be fixed holds, the upper end of fixed rotor clamp 29 to be to make relay user valid function when not having relay cover 49 electromagnetic relay device 10 of the present invention.Thus rotor mounting 30 or bridge chair frame or component for installing rotor assembly or axle assemble can be described as providing certain can the component of open type operation electromagnetic relay device 10.Can consider, such as in some cases, the relay-set of uncovered has certain benefit.Such as, passive relay device more easily may be observed in test process.In any case can consider, by different modes, armature component 13 is fixed on relay casing 48, rotor mounting 30 of the present invention like this makes electromagnetic relay device 10 realize uncovered operation.

The switch module 14 of this relay-set 10 preferably includes the first switch terminal assembly 31, substantially see Fig. 1 to Fig. 4; Second switch Wiring terminal assembly 32, see Fig. 1 to Fig. 3, Fig. 5, Figure 13 and Figure 14; Three spring assemblies 33, see Fig. 1 to Fig. 3, Fig. 5, Fig. 8 to Figure 11, Figure 13 and Figure 14.Can see by observing these mentioned figure, the first switch terminal assembly 31 preferably includes the first contact button 34 and the first tail end of switch as 11.And second switch Wiring terminal assembly 32 preferably includes the second switch end as 11.

Three spring assemblies 33 preferably include the second contact button 37, see Fig. 1, Fig. 2, Fig. 9 to Figure 11, Figure 13 and Figure 14; First spring 38, second spring 39 and the 3rd spring 40, can with further reference to Fig. 5, Fig. 8 to Figure 10 and Figure 13.Can see further, the first spring 38 preferably includes the first accommodation aperture, contact as 41 and as the C shape aperture in Fig. 8 in the of 42, adds as the end fixed offshoot in Figure 13 and Figure 14 in the of 70 or elbow.Notably, a C shape aperture 42 is preferably concentricity with the first accommodation aperture 41, contact.Second spring 39 preferably includes the second accommodation aperture, contact as 43 and as the C shape fold in Fig. 8 in the of 44.Can see by observing Fig. 8, a C shape fold 44 has first curvature radius.3rd spring 40 preferably includes the 3rd accommodation aperture, contact as 45, the 2nd C shape aperture as 46 and the 2nd C shape fold as 47.

Can see further, 2nd C shape aperture 46 is preferably concentricity with the 3rd contact support aperture 45,2nd C shape fold 47 has second radius of curvature, and this second radius of curvature is larger than (a C shape fold 44) radius of curvature on size is liked.Second spring 39 is clipped in the middle of the first spring 38 and the 3rd spring 40 via accommodation or through second contact button 37 in accommodation aperture, contact 41,43 and 45.One C shape fold 44 is in the 2nd C shape fold 47, and concentricity with its (about fold axis).In first contact button 34 and the second contact button 37 or contact space in the same way or side by side, be closely adjacent to each other, large volume description is shown in Fig. 1, Fig. 2, Fig. 9 and Figure 10.In the preferred embodiment, three spring assemblies 33 are offset to the break contacts position between the first and second tail end of switchs 11, and are connected on armature arm 22 (side), and this point is perhaps clear shown in Fig. 9 and Figure 10.

Expect that a C shape aperture 46, C shape aperture the 42, the 2nd and end fixed offshoot or elbow 70 can provide certain component to strengthen the excess of stroke well, thus increase pressing in the middle of the first contact button 34 and the second contact button 37.In this respect, reader can go to see Fig. 9 and Figure 10 further.Contrast considers that these figure mentioned can see, the terminals side 53 of spring assembly 33 may be crossed the flat of spring assembly by driving, the handle 51 of this part next-door neighbour contact button 37.Like this, the spring assembly flat being close to (and radially adjoining) with the handle 51 of contact button 37 forms the folding spring section of button, as in Fig. 8 and Figure 11 52.Observe Fig. 8 and Figure 11 can find out, button foldable portion 52 is stacked in contact button 37, and the terminals side 53 of spring assembly 33 is flexibly out of shape as 50, thus the excess of stroke described in realizing.

In other words, the material (preferably copper) with the spring element in C shape aperture more easily, more can flexiblely be out of shape at such as the end in the C shape aperture in Fig. 8 in the of 50.Notably, the strain of adjacent end 50 does not cause basic material lattice to produce significantly brittle (namely can not transmit undesirable lattice dislocation significantly), thus the C shape aperture structure of three spring assemblies and feature provide a kind of component of the enhancing excess of stroke of stalwartness, and then can increase certain pressure to improve conductive contact therebetween in the middle of contact button 34 and 37.End fixed offshoot or elbow 70 provide a kind of component strengthening the excess of stroke further, can increase and press, and alleviate the contact bounce of contact 34 and 37.

Therefore, by C shape pore size control and/or the enhancing excess of stroke, the conductivity of contact button 34 to 37 is improved, substantially as shown in Figure 10.The contact that expection strengthens and the conductivity that obtains provide certain component for the wiping improving contact, and thus the wiping of this contact or cleaning element become possibility further because of the excess of stroke strengthened.In this respect, expect that relay-set 10 of the present invention has inherent self-cleaning function, this is that C shape aperture 42 and 46 completes.In addition, expection C shape aperture 42 and 46 (with offshoot or elbow 70) can provide certain component to alleviate contact bounce, or suppress the contact vibration in the middle of contact button 34 and 37, when this vibration occurs in and is switched to closed circuit state or closed switch position (substantially as shown in Figure 2) from open-circuit condition or open switch position (substantially as shown in Figure 1).

Can be readily appreciated that by observing Figure 12, magnetic core or yoke end 20 are accommodate by rotor sheet 25 and rotor spider 26 loosely, and armature rotating shaft 101 is coplanar with yoke end 20, and rotating shaft 101 runs through rotor clamp 29 (not specifically illustrating in fig. 20).Should easy understand, conductive coil 15 received current, thus produces magnetic field, can with further reference to vector in Figure 12 102.Can find out by observing this figure, yoke end 20 is run through via rotor assembly (defined primarily of rotor spider 26, rotor magnet 23 and rotor sheet 25) in magnetic field 102, thus the torque of magnetic field induction makes armature or bridge rotate around armature rotating shaft 101.

Therefore, rotor spider 26 moves the position of magnetizing exciter arm 22 point-blank, and this magnetizing exciter arm 22 being moved position orders about three spring assemblies 33 and moves to spring driven closed circuit position (substantially as shown in Figure 2) from the open-circuit position (substantially as shown in Figure 1) that the spring of first-selection is biased.The material structure (believing in the scope understood of those skilled in the art) of relay assembly 10 and closed circuit position can allow the electric current of 120 peaces via the first contact button 34, second contact button 37 and tail end of switch 11 substantially by switch module 14.When coil block 12 temporarily effectively eliminated by no current and magnetic field, return spring 28 can strengthen three spring assemblies 33 are biased recurrence from open-circuit position to the spring of first-selection, substantially as shown in figure 11.The situation of electric current because may break down, so the component comprising certain acquiescence circuit closing contact more preferably considered by electromagnetic relay 10, the circuit closing contact component of this acquiescence forces the first contact button 34 and the second contact button 37 to close during the fault current described in occurring or short circuit current situation.In this respect, expect that path that Lorentz electric current or magnetic field follows is generally as shown in the vector arrows 102 in Figure 12.

Can further contemplate that electromagnetic relay of the present invention can comprise certain component and make its acquiescence in based on the threshold current state of terminals be break contacts positions.In this respect, traditional electromagnetic theory shows, the electric charge carrier of flowing produces the magnetic field adjacent with the flow direction radial direction of charge carrier.Such reader can see Figure 15, Figure 15 shows that the diagram of the threshold current path as 71, and wherein electric current passes relay wiring end 31 and 32 via contact button 34 and 37.Because charge carriers electron current flows according to path 71, so the magnetic force vector represented as 103 comes from terminals.After reaching certain threshold amperage, the magnetic field of the interface connection end 31 and 32 produced interacts with the rotor magnet 23 in permanent magnet or rotatable armature component 13.Magnet 23 has interior magnetic field, and shown in vector arrows 104, outside this magnetic fields point, its intensity size is less than the intensity at vector arrows 103 place.The intensity difference of indicated 104 and 103 causes rotatable armature component 13 to rotate to break contacts position, as shown in the diagram of Figure 15.This function can be measured by the distance of the size of magnet 23 and intensity and armature and fixed contact.

Although above-mentioned explanation comprises very large certainty, this certainty should not be construed as range limits of the present invention, and should be interpreted as illustration of the present invention.Such as, the present invention can be understood as main explanation or discloses a kind of electric current that can make by the electromagnetic relay device of tail end of switch, and this electromagnetic relay device comprises coil block, axle assemble and switch module.Coil block comprises coil, coil axes and C shape magnetic core.Coil winding is on coil axes 100, and coil axes 100 runs through magnetic core, as in Figure 12 in the of 60.Magnetic core 60 comprises magnetic core end 20, and in fact magnetic core end 20 is parallel to coil axes 100.

Axle assemble comprises axle assemble and comprises rotating shaft as 101, as the bridge in Figure 12 and Figure 15 in the of 61 and the switch type excitation device assembly as 22.Bridge 61 comprises intermediate field path 63 (namely relatively close to the path of magnetic core 60), lateral field path 64 (i.e. the relative path away from magnetic core 60) and axially spaced transverse path 65, and transverse path 65 guides the field as 102 in the middle of intermediate field path 63 and lateral field path 64.Magnetizing exciter arm 22 coordinates with lateral approach 64, and extends (not having shown in Figure 12) away from it.Magnetic core end 20 is best and rotating shaft 101 is coplanar, and obtains the support of intermediate path 63 and lateral approach 64 mid portion.

Expection transverse path 65 provides certain steering component, magnetic field 102 opposed coil axle 101 can be made laterally to turn to and produce magnetic induction torque, this magnetic induction torque actuated switch type excitation device assembly 22.Described field steering component can be regarded as further and comprise certain dividing member (having the path that two as contrary in the axle in Figure 12 in the of 66), can produce the magnetic couple relevant with magnetic induction torque.

Switch module as 14 coordinates the switch module as 14 to coordinate magnetizing exciter arm 22 especially especially, and magnetizing exciter arm 22 is the connector of bridge 61 and switch module 14 centre in essence.The function of coil is the magnetic field producing or conduct vector representation as 102.Axle assemble 61 is passed via magnetic core end 20 in magnetic field 102, thus produces the rotation of bridge around rotating shaft 101 by magnetic induction torque.The position of the magnetizing exciter arm 22 in rotary moving of bridge, the magnetizing exciter arm 22 physically on-off switch assembly 14 of displacement.This area is the most easily understood, and closed switch module 14 allows electric current to pass through wherein.

Switch module 14 comprises the spring member that certain strengthens the spring excess of stroke, and described component strengthens the closed position of the switch by increasing pressing in the middle of contact button 34 and 37.The spring member of this enhancing spring excess of stroke provides component and the vibration damping component of contact wiping.The expection of contact Wiping member can effective automatically cleaning switch module 14, and vibration damping component suppresses from opening a way to contact vibration during closed circuit diverter switch position.Thus, the spring member of this enhancing spring excess of stroke by increasing pressing in the middle of contact, by maintaining without remaining contact interface, by suppressing the contact chatter during closing of contact, can strengthen the closed position of the switch.

Although come by reference to several embodiment, invention has been described, and novel device or relay are not limited thereto, as long as when meeting scope and the purport of foregoing publication and accompanying drawing, can revise it and change.Such as, aforesaid specification mainly support one pole, the relay-set that by electric current is 120 peaces.Elite of the present invention but also can be considered to be applied to multipole relay device, to make its claim complying with oneself have unique 26S Proteasome Structure and Function, as long as meet the concept thereof of the one pole embodiment by stating in the disclosure.

Claims (33)

1. an electromagnetic relay device, this electromagnetic relay device is used for optionally allowing electric current by tail end of switch, and this electromagnetic relay device comprises:

Electromagnetic coil assembly, this coil block comprises conductive coil, yoke assembly and coil axes, this coil winding is on this coil axes and comprise the first and second Electromagnetic Drive ends, and this yoke assembly comprises the first and second yoke arms, and each yoke arm comprises axial curvature and yoke end;

Armature component, this armature component comprises the armature spindle of rotor assembly and rotation, this rotor assembly comprises the first and second rotor magnets, rotor sheet and magnetizing exciter assembly, this magnetizing exciter assembly comprises rotor spider and magnetizing exciter, this rotor spider comprises terminal ends, this terminal ends is substantially parallel to this rotor sheet from rotor assembly horizontal expansion, and described rotor magnet has identical direction, and extends at rotor sheet and the middle of rotor spider relative to the armature spindle with this rotation; And

Switch module, this switch module comprises the first and second switch terminal and three spring assemblies, this first switch terminal comprises the first contact and the first tail end of switch, these second switch terminals comprise second switch end, this spring assembly comprises the second contact and three spring elements, first spring element comprises a C shape aperture, one C shape aperture defines the first semicircle aperture confining spectrum, one C shape aperture and the first accommodation aperture, contact concentricity, second spring comprises the second accommodation aperture, contact and terminates in the second semicircle aperture confining spectrum, 3rd spring comprises the 3rd accommodation aperture, contact and the 2nd C shape aperture, 2nd C shape aperture defines the 3rd semicircle aperture confining spectrum, 2nd C shape aperture and this accommodation aperture, the second contact concentricity, this second spring is clipped in first and the 3rd between spring by the second contact, thus first, second and the 3rd semicircle aperture confining spectrum unified in heaps, this first contact and the second contact arranged side by side and adjacent one another are, this spring assembly is connected on this magnetizing exciter, this yoke end is contained between this rotor sheet and rotor spider, the armature spindle of this rotation and this yoke end coplanar, this rotor spider extends relative to this armature spindle non-radioactive shape rotated with terminal ends, this coil is for generation of magnetic field, yoke end is directly passed by rotor assembly in this magnetic field, armature is rotated around the armature spindle of this rotation, this rotor spider and terminal ends are used for the position of this magnetizing exciter mobile, and magnetizing exciter is for encouraging the spring assembly between open-circuit position and closed circuit position, this closed circuit position allows electric current via the first contact, second contact and this tail end of switch are by this switch module.

2. electromagnetic relay device as claimed in claim 1, wherein this C shape aperture is provided for the component strengthening the spring excess of stroke, and the spring excess of stroke of this enhancing is for increasing pressing when this spring assembly is in closed circuit position between the first contact and the second contact.

3. electromagnetic relay device as claimed in claim 2, wherein the component of this enhancing spring excess of stroke is provided for the component of contact wiping, and this component being used for contact wiping is for this first and second contact clean.

4. electromagnetic relay device as claimed in claim 1, wherein this C shape aperture provides component, for suppressing the contact vibration occurred in when open-circuit position is switched to closed circuit position between first and second contact.

5. electromagnetic relay device as claimed in claim 1, wherein this rotor assembly comprises return spring, and this return spring is for strengthening when the interim no current of coil this spring assembly to the recurrence of open-circuit position.

6. electromagnetic relay device as claimed in claim 1, comprise rotor installation component, this rotor installation component is used for enabling electromagnetic relay carry out open type operation.

7. electromagnetic relay device as claimed in claim 1, comprises circuit closing contact acquiescence component, and this circuit closing contact acquiescence component was used between the fault current situation emergence period, forced the first and second contacts to be in closed circuit position.

8. electromagnetic relay device as claimed in claim 1, comprises the component for giving tacit consent to break contacts position between the threshold current situation emergence period based on terminals.

9. an electromagnetic relay, this electromagnetic relay passes through tail end of switch for allowing electric current, and this electromagnetic relay comprises:

Electromagnetic coil assembly, this coil block comprises coil, C shape yoke assembly and coil axes, and this coil winding is on this coil axes, and this yoke assembly comprises the first yoke arm and the second yoke arm, and each yoke arm comprises axial curvature and yoke end;

Armature axle assemble, this armature axle assemble comprises bridge rotating shaft, bridge and magnetizing exciter assembly, the transverse field path that this bridge comprises intermediate field path, lateral field path and longitudinally separates, this magnetizing exciter assembly comprises rotor spider, this rotor spider comprises terminal ends, this terminal ends, relative to this centre and lateral field path, extends from the horizontal on-right angle of this axle assemble zig zag; And

Switch module, this switch module comprises switch terminal and three spring assemblies, this spring assembly comprises three spring elements, first spring element comprises a C shape aperture, one C shape aperture defines the first semicircle aperture confining spectrum, one C shape aperture and the first accommodation aperture, contact concentricity, second spring comprises the second accommodation aperture, contact and terminates in the second semicircle aperture confining spectrum, 3rd spring comprises the 3rd accommodation aperture, contact and the 2nd C shape aperture, 2nd C shape aperture defines the 3rd semicircle aperture confining spectrum, 2nd C shape aperture and this accommodation aperture, the second contact concentricity, this second spring is clipped in first and the 3rd between spring by the second contact, thus first, second and the 3rd semicircle aperture confining spectrum unified in heaps, this spring assembly to be connected on magnetizing exciter assembly and to extend between switch terminal, this yoke end is contained between centre and lateral field path, this bridge rotating shaft and yoke end coplanar, this coil is used for received current and produces magnetic field, axle assemble is directly passed by yoke end in this magnetic field, bridge is rotated around bridge rotating shaft, and the position of magnetizing exciter assembly is moved via terminal ends, the magnetizing exciter assembly of this moveable position is for driving the spring assembly be between break contacts position and circuit closing contact position, this circuit closing contact position allows electric current to pass through switch module via tail end of switch.

10. electromagnetic relay as claimed in claim 9, comprise the aperture component based on spring, for strengthening the spring excess of stroke, described component is for strengthening pressing when spring assembly is in circuit closing contact position between switch terminal.

11. electromagnetic relays as claimed in claim 10, wherein this aperture component based on spring being used for strengthening the spring excess of stroke is provided for the component of contact wiping, and described component is used for clean switch terminal.

12. electromagnetic relays as claimed in claim 9, comprise for the aperture component based on spring, for suppressing the contact vibration occurred between first and second contact when being switched to closed circuit position from open-circuit position.

13. electromagnetic relays as claimed in claim 9, comprise bridge installation component, and this bridge installation component is used for enabling electromagnetic relay carry out open type operation.

14. electromagnetic relays as claimed in claim 9, comprise the component for giving tacit consent between the fault current situation emergence period in circuit closing contact position.

15. as the electromagnetic relay in claim 9, comprises the component for giving tacit consent to break contacts position between the threshold current situation emergence period based on terminals.

16. 1 kinds of electromagnetic relays, this electromagnetic relay passes through tail end of switch for allowing electric current, and this electromagnetic relay comprises:

Coil block, this coil block comprises coil, coil axes and C shape magnetic core, and this coil winding is on this coil axes, and this coil axes runs through this magnetic core, and this magnetic core comprises magnetic core end, and this magnetic core end is parallel to this coil axes;

Axle assemble, this axle assemble comprises rotating shaft, bridge and magnetizing exciter assembly, the transverse field path that this bridge comprises intermediate field path, lateral field path and separates, this magnetizing exciter assembly comprises rotor spider, this rotor spider comprises terminal ends, this terminal ends, relative to this lateral field path, extends from this axle assemble zig zag, magnetic core end and rotating shaft coplanar and be contained between centre and lateral field path; And

Switch module, this switch module comprises three spring assemblies, this spring assembly comprises three spring elements, first spring element comprises a C shape aperture, one C shape aperture defines the first semicircle aperture confining spectrum, one C shape aperture and the first accommodation aperture, contact concentricity, second spring comprises the second accommodation aperture, contact and terminates in the second semicircle aperture confining spectrum, 3rd spring comprises the 3rd accommodation aperture, contact and the 2nd C shape aperture, 2nd C shape aperture defines the 3rd semicircle aperture confining spectrum, 2nd C shape aperture and this accommodation aperture, the second contact concentricity, this second spring is clipped in first and the 3rd between spring by the second contact, thus first, second and the 3rd semicircle aperture confining spectrum unified in heaps, this magnetizing exciter assembly cooperates with switch module, this coil is for generation of magnetic field, axle assemble is directly passed by magnetic core end in this magnetic field, bridge is rotated around rotating shaft by magnetic induction torque, the rotation of bridge makes magnetizing exciter assembly shift position, the magnetizing exciter assembly of this moveable position is used for switching on and off switch module, closed switch module allows electric current to pass through wherein.

17. electromagnetic relays as claimed in claim 16, wherein this switch module comprises the footpath component based on spring eye, and for strengthening the spring member of the spring excess of stroke, described component is for strengthening the closed position of the switch.

18. electromagnetic relays as claimed in claim 17, wherein this aperture component based on spring being used for strengthening the spring excess of stroke provides contact Wiping member, and described component is used for clean switch module.

19. electromagnetic relays as claimed in claim 16, comprise the aperture component based on spring for suppressing switch vibration when being switched to closed switch position from open switch position.

20. electromagnetic relays as claimed in claim 16, comprise bridge installation component, and this bridge installation component is used for enabling electromagnetic relay carry out open type operation.

21. electromagnetic relays as claimed in claim 16, comprise the component for giving tacit consent to circuit closing contact position between the fault current situation emergence period.

22. electromagnetic relays as claimed in claim 16, comprise the component for giving tacit consent to break contacts position between the threshold current situation emergence period based on terminals.

23. electromagnetic relays as claimed in claim 17, wherein this switch module comprises spring assembly, this spring assembly comprises three spring elements, first spring element comprises a C shape aperture, one C shape aperture defines the first semicircle aperture confining spectrum, one C shape aperture and the first accommodation aperture, contact concentricity, second spring comprises the second accommodation aperture, contact and terminates in the second semicircle aperture confining spectrum, 3rd spring comprises the 3rd accommodation aperture, contact and the 2nd C shape aperture, 2nd C shape aperture defines the 3rd semicircle aperture confining spectrum, 2nd C shape aperture and this accommodation aperture, the second contact concentricity, this second spring is clipped in first and the 3rd between spring by the second contact, thus first, second and the 3rd semicircle aperture confining spectrum unified in heaps, these three spring elements are configured, to be provided for the aperture component based on spring strengthening the spring excess of stroke.

24. electromagnetic relays as claimed in claim 19, wherein this switch module comprises spring assembly, this spring assembly comprises three spring elements, first spring element comprises a C shape aperture, one C shape aperture defines the first semicircle aperture confining spectrum, one C shape aperture and the first accommodation aperture, contact concentricity, second spring comprises the second accommodation aperture, contact and terminates in the second semicircle aperture confining spectrum, 3rd spring comprises the 3rd accommodation aperture, contact and the 2nd C shape aperture, 2nd C shape aperture defines the 3rd semicircle aperture confining spectrum, 2nd C shape aperture and this accommodation aperture, the second contact concentricity, this second spring is clipped in first and the 3rd between spring by the second contact, thus first, second and the 3rd semicircle aperture confining spectrum unified in heaps, these three spring elements are configured, to be provided for the aperture component based on spring suppressing contact chatter.

25. electromagnetic relays as claimed in claim 10, wherein this switch module comprises spring assembly, this spring assembly comprises three spring elements, first spring element comprises a C shape aperture, one C shape aperture defines the first semicircle aperture confining spectrum, one C shape aperture and the first accommodation aperture, contact concentricity, second spring comprises the second accommodation aperture, contact and terminates in the second semicircle aperture confining spectrum, 3rd spring comprises the 3rd accommodation aperture, contact and the 2nd C shape aperture, 2nd C shape aperture defines the 3rd semicircle aperture confining spectrum, 2nd C shape aperture and this accommodation aperture, the second contact concentricity, this second spring is clipped in first and the 3rd between spring by the second contact, thus first, second and the 3rd semicircle aperture confining spectrum unified in heaps, these three spring elements are configured, to be provided for the aperture component based on spring strengthening the spring excess of stroke.

26. electromagnetic relays as claimed in claim 12, wherein this switch module comprises spring assembly, this spring assembly comprises three spring elements, first spring element comprises a C shape aperture, one C shape aperture defines the first semicircle aperture confining spectrum, one C shape aperture and the first accommodation aperture, contact concentricity, second spring comprises the second accommodation aperture, contact and terminates in the second semicircle aperture confining spectrum, 3rd spring comprises the 3rd accommodation aperture, contact and the 2nd C shape aperture, 2nd C shape aperture defines the 3rd semicircle aperture confining spectrum, 2nd C shape aperture and this accommodation aperture, the second contact concentricity, this second spring is clipped in first and the 3rd between spring by the second contact, thus first, second and the 3rd semicircle aperture confining spectrum unified in heaps, these three spring elements are configured, to be provided for the aperture component based on spring suppressing contact chatter.

27. 1 kinds of electromagnetic relay devices, this electromagnetic relay device passes through tail end of switch for allowing electric current, and this electromagnetic relay device comprises:

Electromagnetic coil assembly, this coil block comprises conductive coil, yoke assembly and coil axes, this coil winding is on this coil axes and comprise the first and second Electromagnetic Drive ends, and this yoke assembly comprises the first and second yoke arms, and each yoke arm comprises axial curvature and yoke end;

Armature component, this armature component comprises the armature spindle of rotor assembly and rotation, this rotor assembly comprises the first and second rotor magnets, rotor sheet, rotor spider and return spring, this rotor spider comprises magnetizing exciter, rotor magnet has identical direction, and extends at rotor sheet and the middle of rotor spider relative to the armature spindle with this rotation; And

Switch module, this switch module comprises the first and second switch terminal and three spring assemblies, this first switch terminal comprises the first contact and the first tail end of switch, these second switch terminals comprise second switch end, this spring assembly comprises the second contact and three spring elements, first spring element comprises a C shape aperture, one C shape aperture and the first accommodation aperture, contact concentricity, second spring comprises the second accommodation aperture, contact, 3rd spring comprises the 3rd accommodation aperture, contact and the 2nd C shape aperture, 2nd C shape aperture and this accommodation aperture, the second contact concentricity, this second spring is clipped in first and the 3rd between spring by the second contact, this first contact and the second contact arranged side by side and adjacent one another are, this spring assembly is connected on this magnetizing exciter, this yoke end is contained between this rotor sheet and rotor spider, the armature spindle of this rotation and this yoke end coplanar, this coil is for generation of magnetic field, yoke end is directly passed by rotor assembly in this magnetic field, armature is rotated around the armature spindle of this rotation, this rotor spider is used for the position of this magnetizing exciter mobile, and magnetizing exciter is for encouraging the spring assembly between open-circuit position and closed circuit position, this closed circuit position allows electric current via the first contact, second contact and this tail end of switch are by this switch module, this return spring is used for promoting this spring assembly when this coil suspends and turns back to open-circuit position.

28. electromagnetic relay devices as claimed in claim 27, wherein this C shape aperture is provided for the component strengthening the spring excess of stroke, and the spring excess of stroke of this enhancing is for increasing pressing when this spring assembly is in closed circuit position between the first contact and the second contact.

29. electromagnetic relay devices as claimed in claim 28, wherein the component of this enhancing spring excess of stroke is provided for the component of contact wiping, and this component being used for contact wiping is for this first and second contact clean.

30. electromagnetic relay devices as claimed in claim 27, wherein this C shape aperture provides component, for suppressing the contact vibration occurred in when open-circuit position is switched to closed circuit position between first and second contact.

31. electromagnetic relay devices as claimed in claim 27, comprise rotor installation component, and this rotor installation component is used for enabling electromagnetic relay carry out open type operation.

32. electromagnetic relay devices as claimed in claim 27, comprise circuit closing contact acquiescence component, and this circuit closing contact acquiescence component was used between the fault current situation emergence period, forced the first and second contacts to be in closed circuit position.

33. electromagnetic relay devices as claimed in claim 27, comprise the component for giving tacit consent to break contacts position between the threshold current situation emergence period based on terminals.