Patent Grant
10141145
This application is based on and incorporates herein by reference Japanese Patent First Application No. 2015-72042 filed on Mar. 31, 2015.
Field of Application
The present invention relates to a relay apparatus having a plurality of relays having respective contact switches, and to a relay system which incorporates such a relay apparatus.
Description of Related Art
Types of solenoid-operated relay apparatus have been proposed, having a plurality of solenoids with respective plungers for actuating respective contact switches, designed to be manufactured at lower cost than has hitherto been possible. The term “contact switch” is used herein to signify an on/off switch having fixed and movable contacts, which is actuated (switched between a non-conducting and a conducting state) by displacing the movable contact, as opposed to a semiconductor switching element such as a transistor. Examples of a solenoid-operated relay apparatus are described in Japanese patent publication No. 2013-211514, referred to in the following as reference 1. The relay apparatus of a first embodiment of reference 1 consists of a pair of solenoid-operated relays having respective contact switches, with only the solenoid of a first one of the relays having a corresponding electromagnetic coil, and with a magnetic flux generated by that electromagnetic coil being used to also activate the solenoid of the second relay. With the relay apparatus of reference 1, activation of the relays is performed in a specific sequence. Firstly, both of the relays are inactivated. The first relay is then activated by passing a sufficient level of current through the corresponding electromagnetic coil, pulling the corresponding plunger into a central aperture of the coil by magnetic attraction. Part of the magnetic flux produced by the electromagnetic coil of the first relay acts on the plunger of the second relay, but is insufficient to activate the second relay until the plunger of the first relay has become fully drawn into the central aperture of the electromagnetic coil. Both the relays are then left activated (both of the corresponding contact switches held in a conducting state).
Normally, leaving a pair of solenoids in an activated condition for a long period of time will result in a high level of electric power consumption. The apparatus of reference 1 is claimed to enable a reduction of 50% of the electric power required for maintaining both of the relays activated, by comparison with a conventional type of relay apparatus in which both of the relays are provided with respective electromagnetic coils.
However with the invention of reference 1, it is not possible to decrease the power consumption by more than 50% relative to a conventional type of relay apparatus. Furthermore all of the magnetic flux is concentrated in a magnet circuit passing through the single electromagnetic coil, so that it is necessary for the cross-sectional area of the central aperture of that electromagnetic coil (i.e., an aperture into which the corresponding plunger is drawn) to be large. Hence, the external dimensions of the electromagnetic coil must correspondingly be large, thereby increasing the overall size of the relay apparatus. In addition, the manufacturing cost will be high, due to the large amount of copper which must be used to form the single electromagnetic coil.
Furthermore, there will be differences between the forces applied by the respective plungers of the two solenoids when activated), on the corresponding contact switches, so that the characteristics of the two relays will be unbalanced.
Hence it is desired to overcome the above problems, by providing a relay apparatus whereby the power consumption and external dimensions of the apparatus can be reduced by comparison with the prior art, and to provide a relay system incorporating the relay apparatus.
The invention provides a relay apparatus which includes at least a first and a second relay having respective first and second electromagnetic coils (referred to in the following simply as coils), respective first and second movable magnetic members (where movable magnetic member here signifies an armature in the case of an electromagnet type of relay, or a plunger in the case of a solenoid type of relay) and respective contact switches. Each contact switch is actuated to an on (conducting) state or to an off (non-conducting) state when a current is passed through the corresponding coil, producing magnetic excitation which causes displacement of the corresponding movable magnetic member. The invention is specifically advantageous when applied to a relay apparatus having a plurality of relays which are controlled to change sequentially from the inactivated to the activated state, thereby successively operating respective contact switches of the relays.
The relay apparatus of the invention is characterized in that a single yoke is common to each of the relays, and is configured to partially surround each of respective coils of the relays. In the case of a relay apparatus having two relays, with a first relay being activated prior to a second relay, the yoke is formed such that:
(a) when magnetic excitation of the first coil (of the first relay) is produced, a first magnetic flux flows via a first magnetic circuit around the first coil, extending through the first movable magnetic member and the yoke;
(b) when magnetic excitation of the second coil is produced, a second magnetic flux flows via a second magnetic circuit around the second coil, extending through the second movable magnetic member and the yoke; and
(c) when respective currents are passed concurrently through the first and second coils, for activating the second relay, a third magnetic flux flows via a third magnetic circuit, extending successively through the first movable magnetic member, the yoke, the second movable member, and back through the yoke. The third magnetic flux consists of respective parts of the magnetic flux produced by the first and second coils. By ensuring identical directions of magnetic flux flow from the first and second coils through the third magnetic circuit, these magnetic flux flows become mutually reinforced, thereby reducing the level of electric power required to activate the second relay, and also reducing the level of electric power required to maintain the first and second relays in the activated state, by comparison with the prior art.
To ensure that the second relay can only become activated after the first relay (i.e., prevent accidental activation of the second relay when only the first relay is to be activated), a part of the yoke is preferably formed with a magnetic flux restriction section, having a reduced cross-sectional area, formed and positioned such as to restrict the flow of magnetic flux produced from the first coil around the second coil.
Alternatively or in addition to employing a magnetic flux restriction section, while only the first relay is to be activated, a current is passed through the second coil in a direction predetermined for producing a flow of magnetic flux in a direction opposing (and thereby suppressing) the flow of magnetic flux produced from the first coil around the second coil, to reliably ensure that the second relay can only become activated after the first relay.
Similar advantages can be obtained for a relay apparatus having three or more relays.
The invention further provides a relay system incorporating a relay apparatus as described above, in which a relay control circuit controls the supplying of currents to the coils of the relays by selectively connecting/disconnecting the coils to/from an electric power source. The control is performed to operate the contact switches of the relays in a required sequence of conditions, e.g.,
((1) a first connection condition, in which only the first coil is connected in parallel with the control circuit power source (only the contact switch of the first relay is actuated),
(2) a second connection condition, in which both of the first and second coils are connected in parallel with the power source (respective contact switches of both relays are actuated), and
(3) a third connection condition, in which the first and second coils are connected in series across the power source (respective contact switches of both relays remain actuated).
In the third connection condition, due to the reduced level of current which flows through the series-connected coils, the power consumption can be reduced by 75%, by comparison with the parallel-connected condition. Such a reduction of power consumption is significant, when the relay apparatus must be left for long periods with both of the contact switches held activated.
The relay system may be applied for example to control the supplying of power to an electrical load via a pair of supply leads, from an electric power source, with the supply leads respectively connected in series with the first and second contact switches of the relays.
In the following, “switch contacts” are referred to simply as “contacts”. The directions “up”, “down”, “right”, “left” are to be understood to refer to directions as viewed in the drawings. In the drawing designations, a distinction is made between upper-case and lower-case letters. For example a control section 12A is to be distinguished from a controller 12a. The term “on” or “activated” applied to a switching device signifies a conducting condition, while “off” or “inactivated” signifies a non-conducting condition. A relay is “activated” when the armature of the relay is fully drawn into contact with the yoke by magnetic attraction, in the case of an electromagnet type of relay. In the case of a solenoid type of relay, the relay is “activated” when the plunger of the relay becomes fully retracted into a central aperture of the relay coil by magnetic attraction.
A first embodiment of a relay apparatus will be described referring to
The coil springs 110 and 117 support the movable member 111 for reciprocating motion. It would be equally possible to use other types of elastic members for the functions of the coil springs 110 and 117, such as leaf springs, members formed of rubber or gel, etc. The movable member 111 is partially or entirely formed of a magnetic material which is also electrically conductive, and the armature 116 is partially or entirely formed of a magnetic material.
The movable member 111 and the armature 116 are fixedly attached to one another by the insulator 113. The armature 116 becomes attracted onto the No. 1 core 119 when a current flows through the No. 1 coil L1, producing magnetic excitation, thereby actuating the contact switch CS1 to a conducting state by bringing the movable contact 112 and fixed contact 114 together. When no current flows through the No. 1 coil L1, the armature 116 is held pulled apart from the No. 1 core 119 by the actions of the springs 110 and 117.
The No. 1 coil L1 is wound on a coil bobbin 118 formed of an electrically insulating material. A central cavity in the No. 1 coil L1 contains the No. 1 core 119, which is formed of a magnetic material. The No. 1 coil L1, the coil bobbin 118 and the No. 1 core 119 are fixedly retained by the yoke Yk.
The plan view of
The relay RL2 has the same configuration as the relay RL1, with component parts having the same positional relationships as those of the relay RL1. The No. 1 coil L1 is configured to produce a smaller value of magnetizing force (MF1) than a magnetizing force (MF2) produced by the No. 2 coil L2, when the coils L1 and L2 are connected in parallel to the same power supply voltage, e.g., with the No. 1 coil L1 being formed with a higher resistance value than the No. 2 coil L2, to thereby pass a lower value of current than the coil L2.
The respective directions of winding of the No. 1 coil L1 on the coil bobbin 118 and No. 2 coil L2 on the coil bobbin 128 can be arbitrarily determined, so long as the respective directions of flow of current through the coils establish specific relationships between directions of flow of magnetic flux, described hereinafter.
With a second condition of the relay apparatus 11A shown in
No. 2 core 129→yoke Yk→armature 126→No. 2 core 129
The flow path of the No. 2 magnetic flux ϕ2 is designated as the No. 2 magnetic circuit MC 2. (If the direction of current flow through the No. 2 coil L2 were to be reversed, the flow direction of the No. 2 magnetic flux ϕ2 would be correspondingly reversed).
Part of the magnetic flux produced in the No. 2 core 129, designated as ϕb, flows through a lower bridging portion of the yoke Yk (i.e., which bridges the lower ends of the No. 1 coil L1 and the No. 2 coil L2) via a third magnetic circuit MC 3 which includes the magnetic flux restriction section Yka of the yoke Yk. The main part (ϕ2) of the magnetic flux generated in the No. 2 core 129 flows around the No. 2 coil L2, and a resultant magnetizing force acting on the armature 126 causes displacement of the armature 126, and hence actuation of the contact switch CS2. The flow of remaining flux (ϕb) of the No. 2 core 129 is restricted, since it must flow along a path having high magnetic resistance which is increased by the magnetic flux restriction section Yka. Hence a magnetizing force acting on the armature 116 at this time (resulting from the flow of magnetic flux ϕb) is made insufficient to displace the armature 116, so that the relay RL1 remains inactivated (contact switch CS1 remains off).
Thus in the second condition shown in
However in addition to forming the magnetic flux restriction section Yka (or as an alternative), the condition of the relay apparatus shown in
No. 1 core 119→yoke Yk→armature 116→No. 1 core 119
This flow path is designated as the No. 1 magnetic circuit MC 1.
In addition, a part of the magnetic flux produced by the coil L1 and a part of the magnetic flux produced by the coil L2 flow in the same direction through the third magnetic circuit MC3, and hence become mutually reinforced. That is, a flow of No. 3 magnetic flux ϕ3 occurs around a path:
No. 2 core 129→(lower bridging portion of yoke Yk)→No. 1 core 119→armature 116→(upper bridging portion of yoke Yk)→armature 126→No. 2 core 129
The first, second and third magnetic circuits MC 1, MC 2 and MC 3 constitute respectively separate circuits.
The magnetizing force MF1 required to be produced by the No. 1 coil L1 for activating the relay RL1 (to change from the condition shown in
Hence, the level of electric power required for activating the relay RL1, and also the level of power required for then maintaining the relays RL1, RL2 in the activated state, can be reduced by comparison with prior art types of relay apparatus.
A second embodiment will be described referring to
Components of the second embodiment corresponding to those of the first embodiment are indicated by the same reference designations as for the first embodiment. In the following description it is assumed that accidental activation of the relay RL1 at the time of activating the relay RL2 is prevented (i.e., ensuring that the relay RL2 can be activated prior to activating the relay RL1) only by utilizing a magnetic flux restriction section in the yoke Yk, as shown in
As shown in
The electrical load 30 of this embodiment consists of an inverter 31 (operable for DC/AC and AC/DC electric power conversion)), a rotary machine 32, a converter (power voltage converter) 33, and electrical equipment 34. It would be possible for either or both of the inverter 31 and the converter 33 to be controlled by signals supplied from the external apparatus 20.
Designating the side of the relay apparatus 11A opposite to the battery E1 as the output side, the inverter 31 and the converter 33 are each connected in parallel with that output side (i.e., in parallel with the supply leads Ln1 and Ln2). The input side of the relay apparatus 11A is connected in parallel with the battery E1.
The rotary machine 32 of this embodiment is a motor-generator apparatus of the host vehicle, which produces motive power when supplied with electric power from the battery E1, or is driven to generate electric power. The inverter 31 converts the (DC) power from the battery E1 to AC power which is supplied to the rotary machine 32, and performs the inverse operation for supplying power from the rotary machine 32 to charge the battery E1. The converter 33 converts the electric power from the battery E1, to suitable form for being supplied to the electrical equipment 34 of the vehicle. The electrical equipment 34 can consist for example of a vehicle navigation system, lamps such as headlamps, interior lamps, etc., vehicle air conditioner apparatus, heater apparatus, etc., motors for operating windshield wipers, etc.
Only the condition in which power is supplied (discharged) from the battery E1 to the equipment constituting the electrical load 30 is considered in the following description.
As shown in
With this embodiment, the battery E2 is a secondary type of storage battery such as a lead-acid battery, whose voltage and power output capabilities are lower than those of the battery E1.
The first switch SW1 and the diode D1 are connected in series, constituting a first series-connected section. The No. 2 coil L2, the third switch SW3 and the No. 2 coil L2 are connected in series to constitute a second series-connected section. The second switch SW2 and the diode D2 are connected in series, constituting a third series-connected section, and the fourth switch SW5 and the diode D5 are connected in series, constituting a fourth series-connected section. The first, second, third and fourth series-connected sections are connected in parallel with one another, and in parallel with the battery E2. The diodes D1, D2, D5 are connected respectively across the coils L1, L2, LP, with a forward conduction direction that is opposite to the direction of current flow through the corresponding one of the coils L1, L2, LP (when such flows are enabled, as described in the following).
The junction of the first switch SW1 and the diode D1 is connected to the junction of the third switch SW3 and the No. 1 coil L1. The junction of the No. 2 coil L2 and the third switch SW3 is connected to the junction of the diode D2 and the second switch SW2.
The contents of step S11 are illustrated in the flow diagram of
If no current is detected in the first judgement step, only the switching device SW1 is then set in the on state (step S11c). Only the relay RL1 should now be activated, so that only the supply lead Ln1 should be in a conducting state. As a second judgement step (step S11d), if a current (I1>0) is now detected in the supply lead Ln2, this indicates failure of the contact switch CS2.
If no current is detected in the second judgement step, only the switching device SW2 is then set in the on state (step S11e), so that only the relay RL2 should be now activated. In that condition, only the supply lead Ln2 should be in a conducting state. As a third judgement step (step S110, if a current (I1>0) is now detected in the supply lead Ln2, this indicates failure of the contact switch CS1. If no current is detected (NO decision in step S11f) then (step S11g) the switching device SW2 is set to the off state (so that all of the switching devices SW1, SW2, SW3 and SW5 are now initialized to the off state), and a NO decision is reached for step S12 of
If a current (I1>0) is detected in any of the first, second or third judgement steps above, indicating failure of one or both of the relays RL1 and RL2, a YES decision is reached in step S12 of
If both of the relays RL1 and RL2 are judged to be normal (NO in step S12), the switching device SW5 is set in the on state (step S13), to pass current through the precharging coil LP and so set the contact switch CSP in the on state.
After the switching device SW5 has been set to the on state (or concurrent with this) the switching device SW2 is set to the on state (step S14) thereby producing magnetic excitation in the No. 2 coil L2 by a current Ic. A condition is thereby established for the relay apparatus 11A whereby a magnetizing force MF2 (acting on the armature 126) is greater than a magnetizing force MF1 (acting on the armature 116), such that the relay RL2 now becomes activated while the relay RL1 remains inactivated.
Since both of the contact switches CS2 and CSP are now in the on state, a charging current flows from the battery E1 through the current limiting resistor R1 into the smoothing capacitor C1, thereby commencing precharging of the capacitor C1.
This is continued until a predetermined charge storage condition has become satisfied (YES decision in step S15). The charge storage condition can be for example that the relay RLP has remained activated for a predetermined time interval, or that the smoothing capacitor C1 has become charged to a predetermined voltage, or that the current I1 flowing through the supply lead Ln2 has fallen to a predetermined value. When the charge storage condition has become satisfied, the switching device SW1 is set to the on state (step S16), producing magnetic excitation in the No. 1 coil L1 of the relay RL1.
The condition shown in
After the switching device SW1 has been set on, the switching device SW5 is set to the off state (step S17), thereby halting the flow of current Ip through the coil LP, and so deactivating the relay RLP and thus ending the charging of the smoothing capacitor C1.
The switching devices SW1 and SW2 are then concurrently set to the off state (step S18), to halt the condition of parallel connection between the coils L1 and L2. Currents (Is) then flow momentarily via the diodes D1 and D2 as indicated by the broken-line circuits, and become dissipated. The switching devices SW1 and SW2 can be switched off simultaneously, without timing restrictions, so that system design is facilitated.
After the switching devices SW1 and SW2 have been switched off, the third switching device SW3 is set in the on state (step S19) so that a current flows Ib through the coils L1 and L2, which have become connected in series as shown in
A decision is then made (step S20) as to whether a predetermined condition for halting the supplying of power to the electrical load 30 is satisfied. The requisite condition can be for example that the host vehicle has become halted (including a temporary halt) so that the operation of the rotary machine 32 has become halted, or that the operation of the electrical equipment 34 has ended due to the vehicle having become halted, etc.
If the halt condition is satisfied (YES decision in S20), all of the switching devices of the control section 12 are set to the off state (step S21), and this execution connection changeover processing is terminated. If the halt condition is not satisfied (NO decision in step S20), the connection changeover processing is terminated without any other action being performed.
With the relay system described above, the yoke of the relay apparatus 11A is formed with a magnetic flux restriction section such as that shown in
(a) when relay RL2 is to be activated, connect the coil L1 across the battery E2 with a first connection polarity (to pass a current in a first direction through the coil L1 of the relay RL1, i.e., a direction whereby the magnetic flux ϕa of the coil L1 opposes the magnetic flux ϕb produced by the coil L2),
(b) when relay RL1 is thereafter to be activated, connect the coil L1 across the battery E2 with a second connection polarity (to pass a current in a second direction, opposite to the first direction, through the coil L1 of the relay RL1, i.e., a direction whereby magnetic flux of the coil L1 reinforces magnetic flux of the coil L2 in the magnetic circuit MC3 as shown in
(c) thereafter connect the coils L1, L2 in series across the battery E2, with the direction of current flow through the coils left unchanged.
It will be apparent that the circuit of the controller 12a shown in
A third embodiment will be described referring to
The control section 12B shown in
The transistor Q5 (and processing steps S30 and S35 in
The transistors Q1, Q2 and Q5 of this embodiment are respective MOS FETs, incorporating parasitic diodes which perform the functions of the diodes D1, D2, D3, and D5. However if other types of switching device are utilized as SW1, SW2 and SW5, which do not incorporate parasitic diodes, separate diode devices may be used as the diodes D1, D2, D3 and D5.
The No. 2 coil L2, the diode D3, the No. 1 coil L1 and the switching device SW4 are connected in series, with the combination being referred to in the following as the fifth series-connected section. The transistor Q1 is connected between the positive terminal of the battery E2 and the junction of the diode D3 and the No. 1 coil L1. The transistor Q2 is connected between the junction of the No. 2 coil L2 and the diode D3 and the junction of the No. 1 coil L1 and the switching device SW4.
The transistor Q5 and the coil LP are connected in series (constituting a sixth series-connected section), with the diode D5 and the coil LP connected in parallel. The fifth and the sixth series-connected sections are connected in parallel with the battery E2.
The failure diagnostic processing of step S11 in
If it is judged that the relays RL1 and RL2 are functioning normally (NO decision in step S12), then the transistor Q5 is set in the on state (step S30) so that the current Ip flows, producing magnetic excitation of coil LP. The transistor Q2 is then set in the on state (step S31). With both of the transistors Q1 and Q2 in the on state, precharging of the capacitor C1 commences. The precharging is continued so long as the predetermined charging condition is not satisfied (NO decision in step S15).
Following step S31, the switching device SW4 is set to the on state (step S32). At that time, as shown in
When the predetermined charging condition is satisfied (YES decision in step S15), the transistor Q1 is set in the on state (step S33). At that time, the voltage applied across the terminals of the diode D3 is lower than the forward voltage of that diode, so that the currents Ie and If flow in parallel. As a result, the No. 1 coil L1 and the No. 2 coil L2 become connected in parallel. The condition of the relay apparatus 11A shown in
After the transistor Q1 has been set in the on state (step S33) the transistor Q5 is set in the off state (step S34) to set the precharging relay RLP in the off state and end the precharging of the smoothing capacitor C1.
The transistors Q1 and Q2 are then both set to the off state concurrently (step S35) to change the No. 1 coil L1 and the No. 2 coil L2 from a parallel to a series connection condition. At this time, a current Ie flows through the fifth series-connected section (the No. 2 coil L2, the diode D3, the No. 1 coil L1 and the switching device SW4). The transistors Q1 and Q2 can be switched off simultaneously, without timing restrictions, so that system design is facilitated.
When the transistors Q1 and Q2 are switched off, currents Is then flow momentarily via the diodes D1, D2 and D5 as indicated by the broken-line circuits in
Following step S35, a decision is made as to whether an operation halt condition is satisfied (step S20) If the condition is satisfied (YES decision), the switching device SW4 and all of the transistors Q1, Q2, Q3 are set to the off state (step S21). This execution of the connection changeover control processing is then ended. If the halt condition is not satisfied (NO decision in step S20), execution of the connection changeover processing is terminated without further action.
A fourth embodiment will be described referring to
No. 1 core 119→armature 116→yoke Yk (i.e., a part of the yoke Yk which surrounds the No. 1 coil L1)→No. 1 core 119
Magnetic circuit MC5 and MC6 are constituted by the paths through which the No. 1 magnetic flux ϕ5 and No. 2 magnetic flux ϕ6 respectively flow. The No. 1 magnetic flux ϕ5 and the No. 2 magnetic flux differ from one another in flowing through respectively different parts of the yoke Yk (i.e., a left-side portion and a right-side portion of the yoke Yk respectively, as viewed in
Magnetic excitation of the No. 2 core 129 is produced by current which flows in the No. 2 coil L2 in the direction indicated by the circled symbols in
No. 2 core 129 armature 126→yoke Yk (i.e., a part of the yoke Yk which surrounds the No. 2 coil L2)→No. 2 core 129
Magnetic circuits MC7 and MC8 are thereby constituted, as the respective flow paths of the No. 2 magnetic fluxes ϕ7 and ϕ8. The No. 2 magnetic fluxes ϕ7 and ϕ8 differ from one another in that they flow through respectively parts of the yoke Yk (i.e., a left-side portion and a right-side portion, as viewed in
If current is passed through the No. 2 coil L2 in the opposite direction to that shown in
As shown in
With this embodiment as shown in
With this embodiment, control of the relays RL1 and RL2 (and of the precharging relay RLP, if used) is performed as described for the second or third embodiment (see
A fifth embodiment will be described referring to
The precharging relay RLP includes a coil spring 130, a movable member 131, an insulator 133, a fixed member 135, an armature 136, a coil spring 137, a coil bobbin 138 a No. 3 core 139, and a precharging coil LP. A contact switch CSP indicated by the chain-line outline (also indicated in
The functions of the relay system 10B are identical to those of the relay system 10A described above, with respect to supplying electric power to the electrical load 30. However the relay system 10B differs from the relay system 10A by utilizing the relay apparatus 11C shown in
With the relay system 10B, control of the relays RL1 and RL2 and of the precharging relay RLP is as described for the third and fourth embodiments (see
The present invention is not limited to the embodiments described above. Various alternative embodiments, or modifications of the described embodiments, may be envisaged, as with the following examples.
With the first to fifth embodiments, the magnetic flux restriction section Yka is formed by cut-out portions Ykd having a rectangular shape with rounded corners, as shown in
With the first to fifth embodiments above, a system configuration is described whereby electric power from the battery E1 can be supplied to the electrical load 30, i.e., by discharging the battery E1. However alternatively (or in addition), the system configuration may be as shown in
With the control section 12B of the third embodiment, MOS FET transistors which incorporate parasitic diodes are used as the transistors Q1 and Q2, performing a similar function to the switching devices SW1 and SW2 respectively of the control section 12A. However it would be equally possible to use MOS FETs which do not have parasitic diodes, or to use transistors other than MOS FETs, such as bipolar transistors (including power transistors), IGBTs, etc. Other than requiring the addition of separate diodes to function as the diodes D1 and D2, the same effects can be expected as those described above. This is also true for the transistor Q5.
Furthermore it would be equally possible to use a transistor as one of the switching devices SW1 and SW2 and to use a contact switch or a semiconductor relay, etc., as the other. Irrespective of the type of switching devices, the same effects can be expected as those described above for the third embodiment.
Furthermore with each of the first to fifth embodiments described above, each of the contact switches CS1 and CS2 is held in the off state when the corresponding one of the relays RL1, RL2 is not activated, and is set in the on state when the corresponding relay is activated. However it would be equally possible to configure the relay apparatus such that each of the contact switches CS1 and CS2 is held in the on state when the corresponding one of the relays RL1, RL2 is not activated, and is set in the off state when the corresponding relay is activated.
Furthermore with each of the first to fifth embodiments described above, the coils L1 and L2 are set in the series-connected condition after having been set in the parallel-connected condition (steps S15 to S18 in
The first to fourth embodiments have been described for the case of the relay apparatus 11A having two relays, RL1 and RL2 (see
The above embodiments have been described for the case of using an electromagnet type of relay, in which magnetic flux produced by the coil of a relay causes attraction of the corresponding armature, to actuate the corresponding contact switch. (see
In the appended claims, “movable magnetic member” is used as a general term to signify an armature of a relay in the case of an electromagnet type of relay, and to signify a plunger of a relay, in the case of a solenoid type of relay.
The following effects are obtained by the first to fifth embodiments described above.
(1) With each of the above embodiments 11A˜11C, the relay apparatus 11 comprises a plurality of coils (L1, L2, LP) which include at least a No. 1 (electromagnetic) coil L1 and a No. 2 coil L2, a No. 1 core 119 and a No. 2 core 129 positioned in respective central cavities in the No. 1 and No. 2 coils L1 and L2, and a yoke Yk. In the case of the relay apparatus 11A shown in
(2) With a relay apparatus having such a magnetic circuit configuration, when the respective directions of current flow through the No. 1 coil L1 and the No. 2 coil L2 are made such that the magnetic fluxes ϕ1, ϕ2 produced by the coils L1 and L2 (flowing in the No. 1 core 119 and No. 2 core 129) are mutually opposite in direction, respective parts of the magnetic fluxes produced by the coils L1 and L2 which flow through the third magnetic circuit (MC3) become mutually reinforced, as illustrated in
(3) When it is required to reliably activate one of two relays of a relay apparatus 11 prior to the other, e.g., the relay RL2 of the relay apparatus 11A, this can be achieved by making the respective directions of current flow through the No. 1 coil L1 and the No. 2 coil L2 such that the magnetic fluxes ϕ1, ϕ2 produced by the coils L1 and L2 flow in same direction through the No. 1 core 119 and No. 2 core 129 respectively. As a result, the respective parts of the magnetic fluxes ϕ1, ϕ2 produced by the coils L1 and L2 which flow through the third magnetic circuit (MC3) become mutually opposed and so cancel one another, as illustrated in
(4) A relay system 10 (10A˜10D) includes first switching devices SW1, SW2 for separately producing magnetic excitation of a plurality of coils comprising at least a first coil (L1) and a second coil (L2) of relays RL1, RL2 respectively, for actuating a first contact switch CS1 and a second contact switch CS2 by magnetic attraction, and a second switching device SW3 connected between the first coil and second coil. Changeover of the first coil and second coil between being connected in parallel and being connected in series is executed by on/off actuation of the first switching devices SW1, SW2 and second switching device(s) SW3 (see
If for example the first and second coils have identical resistance values, the value of current required to be supplied in the series-connected condition of the coils L1, L2 for maintaining the relays RL1I and RL2 activated (i.e., both of the contact switches CS1 and CS2 in the on state) is ¼ of the value that is supplied in the parallel-connected condition of the coils L1, L2. Hence, in the series-connected condition of the coils L1, L2, the power consumption of the relay apparatus 11 can be reduced by 75%.
(5) In addition, the coils L1 and L2 are preferably configured such that, with the same value of supply voltage applied to each, a specific one of the coils (in the embodiments, No. 2 coil L2) produces a greater magnetizing force than the other coil (in the embodiments, No. 1 coil L1). Specifically, the coils L1 may be formed with a higher resistance value than the No. 2 coil L2.
The effect of this is as follows, referring to
(6) A relay system configuration may be utilized (see
(7) A relay system configuration may be utilized (see
(8) A relay system configuration may be utilized (see
| Number | Date | Country | Kind |
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| 2015-072042 | Mar 2015 | JP | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 2528777 | Persons | Nov 1950 | A |
| 7671711 | Suzuki | Mar 2010 | B2 |
| 9514872 | Rallabandi | Dec 2016 | B2 |
| 20110075315 | Dickerhoof et al. | Mar 2011 | A1 |
| 20130207750 | Daitoku et al. | Aug 2013 | A1 |
| 20130222089 | Daitoku et al. | Aug 2013 | A1 |
| 20140225691 | Tanaka et al. | Aug 2014 | A1 |
| 20160293365 | Tanaka et al. | Oct 2016 | A1 |
| Number | Date | Country |
|---|---|---|
| S56-030224 | Mar 1981 | JP |
| 2002-184284 | Jun 2002 | JP |
| 2010-212035 | Sep 2010 | JP |
| 2010-287455 | Dec 2010 | JP |
| 2012-152071 | Aug 2012 | JP |
| 2013-164900 | Aug 2013 | JP |
| 2013-179243 | Sep 2013 | JP |
| 2013-211514 | Oct 2013 | JP |
| 2014-170738 | Sep 2014 | JP |
| Number | Date | Country | |
|---|---|---|---|
| 20160293368 A1 | Oct 2016 | US |
