Information
-
Patent Grant
-
6643112
-
Patent Number
6,643,112
-
Date Filed
Thursday, February 8, 200123 years ago
-
Date Issued
Tuesday, November 4, 200321 years ago
-
Inventors
-
Original Assignees
-
Examiners
- Sircus; Brian
- Rodriguez; Isabel
Agents
- Oblon, Spivak, McClelland, Maier & Neustadt, P.C.
-
CPC
-
US Classifications
Field of Search
US
- 361 2
- 361 3
- 361 7
- 361 14
- 361 152
- 361 160
- 361 189
- 361 190
- 218 2
- 218 3
- 218 6
- 218 7
- 218 17
-
International Classifications
-
Abstract
An electromechanical relay including a mechanical displacement electrical contact and a transistor parallel-connected with the electrical contact. The contact is closed for a voltage V corresponding to the forward direction of the transistor and a powering-on of the transistor that starts before the closure of the contact and ends after the closure. The contact is opened for a voltage V corresponding to the forward direction of the transistor and a powering-on of the transistor that starts before the closure of the contact and ends after the closure. Such an electromechanical relay may find particular application to electromechanical switches, hybrid relays.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to an electromechanical relay with semiconductor-assisted switching. The relay, designed for the selection switching of charges on an electrical network, can be used for this purpose on either an AC or a DC electrical network.
2. Discussions the Background
Electromechanical type relays have one or more mechanical displacement electrical contacts coupled to a mobile element of the magnetic circuit of an electromagnet. The electromagnet is controlled by supplying power to its coil which, by producing an induction flux in the magnetic circuit, drives the movement of the mobile element and the closing or opening of the electrical contacts of the relay.
The electrical contact usually comprises a fixed part and a mobile part, each having pads made of material that is a good electrical and thermal conductor. These pads, which are brought into contact when the relay is closed, must have low contact resistance in order to limit heating during the passage of the current.
The selection switching, by an electromechanical relay, of an electrical circuit under load, especially when the circuit is inductive, produces arcs between the contacts when the circuit is opened or closed. This phenomenon is commonly called sparking.
Indeed, when the closing of the relay is activated, the current is set up in the electrical current through the electrical contact, producing one or more electrical arcs due to rebounds between the mobile contact and the fixed contact.
At opening, the contact cuts off the current travelling through the electrical circuit. This again produces arcs between the contacts. This intensity increases with the level of the current to be cut off and the inductive character of the circuit.
These repeated arcs inevitably cause deterioration in the contact in the course of time and reduce the life of the contact.
In certain electromechanical relays, in order to limit the arc between the contact terminals during the selection switching, either a triac or two back-to-front parallel-connected thyristors are parallel mounted on the terminals of the mechanical displacement electrical contact. When the contact is being closed, a control circuit makes the triac conductive slightly before the closing of the contact. When the contact is being opened, this control circuit makes the same triac conductive slightly before the opening of the contact.
In this type of hybrid relay comprising a parallel-connected triac (or thyristors) on the mechanical displacement contact, the operation of making the contact conductive slightly before the switching of the contact makes almost all the electrical current flow into the fired triac (or thyristor). The opening or closing of the contact at this time will be done with a current appreciably lower than the current in the electrical circuit. The effective closing of the contact will cause the powering-off of the triac or the thyristors as they are short-circuited by the closed contact.
While these hybrid relays improve the lifetime of the contacts, they do not totally eliminate the arc at the time of the switching. Furthermore, as a result of the elasticity proper to the fixed and mobile parts of the contact, when the contact closes or opens, there are rebounds between this fixed part and this mobile part. Consequently, the closing or opening of the contact does not happen in a single operation.
During a closing of the contact, rebounds at the time of the impact between the mobile part and the fixed part of the contact produce a sequence of repeated opening and closing operations whose number will depend essentially on the mechanical characteristics of the contact. These repeated contact opening and closing operations could produce repeated operations of firing and powering-off of the triac or thyristors that are parallel-connected to the electrical contact, and repeated arcs between the contacts whose intensity will depend on the level of the current in the electrical circuit and on its impedance. These arcs could have a very high level in the case of the selection switching of a circuit comprising self-inductance or capacitive loads.
The phenomenon is as follows (we shall describe the phenomenon in the case of a triac it being known that the same phenomenon occurs for back-to-front parallel-connected thyristors): when the closing of the relay is ordered, the triac is made conducive by the control circuit slightly before the closing of the contact in order to let electrical current into the triac. At the time of the first contact between the mobile part and the fixed part of the contact, the triac that is parallel-connected to the contact gets powered off since the voltage at this terminal is substantially zero. The triac is in the insulated state. All the electrical current passes at this point in time into the closed electrical contact. A first rebound of the contact occurs, causing the opening of the contact crossed by the totality of the current in the electrical circuit and the appearance of a selection switching arc. During a short instant of opening that follows the rebound of the contact, the voltage of the electrical circuit reappears at the terminals of the controlled triac, and this triac again gets refired and again lets through current from the electrical circuit into the triac. The contact closes again at the end of the first rebound, and powers off the triac which once again becomes insulated, prompting the passage of the electrical current into the contact. In the same way, a new rebound will reproduce a new selection switching arc of the terminals of the contact until the rebounds stop and the contact is definitively closed.
In the case of an AC network, when the contact is closed, these repetitive arcs will have an intensity all the greater as the selection switching is done for a current close to the maximum current of alternation of current.
When there is a command for opening the relay, the triac is activated just before the opening of the contact. The triac is short-circuited by the contact, the voltage at its terminals is substantially zero and it remains powered off. The contact is opened with the nominal current in the contact. This current disappears very swiftly when the voltage at the terminals of the triac becomes sufficient to fire it. However, a very brief arc occurs at the time of opening. A rebound produces repetitive arcs, in a manner similar to what happens at the time of closing.
SUMMARY OF THE INVENTION
In order to overcome the drawbacks of the prior art, the invention proposes an electromechanical relay designed to be inserted into an electrical circuit, the relay comprising a mechanical displacement electrical contact, a transistor parallel-connected with the electrical contact, means to command firstly the closing of the contact and the powering-on of the transistor in response to a first control signal and secondly the opening of the contact and the powering-on of the transistor in response to a second control signal, characterized in that the control means comprise means to:
generate, from the first control signal, a mechanical displacement contact closing signal that precedes the closing of the contact, this closure being done for a voltage V at the terminals of the contact that corresponds to the forward direction of the transistor;
generate, from the first control signal, independently of the closing signal, a first signal for powering on the transistor that starts before the closing of the contact and ends after this closing;
generate, from the second control signal, a mechanical displacement contact opening signal that precedes the opening of this contact, this opening being done for a current in the contact corresponding to the forward direction of the transistor;
generate, from the second control signal, independently of the opening signal, a second signal for powering on the transistor that starts before the opening of the contact and ends after this opening.
In a working of the relay according to the invention in a DC network, the transistor is biased constantly in the forward direction so that, during a command for closing or opening the relay, the transistor is powered on some instants before the closing or opening of the contact and the powering on is stopped some instants after the closing or opening of the contact after the end of the rebounds of the contact.
A parallel-connected transistor with the contact of the electromechanical relay according to the invention, when it is powered on in the forward direction, does not get powered off when it is short-circuited by the mechanical displacement contact which has the advantage, as compared with prior art relays using triacs and transistors, of continuing to be conductive during successive openings at the time of the rebounds of the contact. The transistor, which is powered on in the forward direction, totally eliminates the repetitive arcs due to rebounds at each opening of the contact, the current of the electrical circuit instantaneously passing into the transistor.
In one embodiment of the relay according to the invention used in an AC network:
the first signal for powering on the transistor is generated when the voltage V corresponding to the forward direction of the transistor is close to the change in direction of the alternation of the voltage V at its terminals;
the second signal for powering on the transistor is generated when the current corresponding to the forward direction of the transistor is close to the change in direction of the alternation of current in the contact.
In the case of use in an AC network, the fact that the transistor is powered on during a closure of the contact, for a voltage in the forward direction of the transistor that is close to the change in alternation of voltage, namely close to a low voltage as compared with the maximum voltage of the network, means that it is possible to reduce the size of the transistor. Indeed, the current flowing through the transistor during the short period of powering on the transistor (as compared with the period of the AC voltage of the network), will have a low value, the voltage at the terminals of the network being close, at this time, to the change in alternation and therefore having a low value close to zero volts.
In the same way, an opening of the contact for a current in the forward direction close to a change in alternation of current, namely a current close to zero amperes, will mean that the size of the transistor can be reduced.
In the embodiments of the relay according to the invention, the transistor parallel-connected with the electrical contact may be chosen from among the IGBT (insulated gate bipolar transistor) type transistors, bipolar transistors or MOS transistors.
In a variant of the relay according to the invention, the transistor is series-connected with a diode providing protection against reverse voltages at the terminals of the transistors. The protection diode enables the use of the transistor in networks whose voltage is higher than the reverse voltage that can be borne by the transistor, this reverse voltage being borne by the diode.
In one embodiment, the relay according to the invention uses a microcontroller having, firstly, inputs respectively receiving the commands from the relay, a piece of information on current in the electrical circuit and a piece of information on voltage at the terminals of the mechanical displacement electrical contact and, secondly, a control output giving the control signals for opening and closing the contact and an output for powering on the transistor.
BRIEF DESCRIPTION OF THE DRAWINGS
Other features and advantages of the invention shall appear from the following description of an exemplary embodiment of an electromechanical relay, wherein:
FIG. 1
is a diagrammatic drawing of a relay according to the invention working in an AC network;
FIGS. 2
a
,
2
b
,
2
c
,
2
d
,
2
e
are state graphs pertaining to the different elements of the relay when the closing is commanded;
FIGS. 3
a
,
3
b
,
3
c
,
3
d
,
3
e
are state graphs pertaining to the different elements of the relay when the opening is commanded;
DESCRIPTION OF THE PREFERRED EMBODIMENTS
FIG. 1
is a diagrammatic drawing of a relay according to the invention inserted into an AC electrical circuit CE with a rated voltage U at its supply terminals E
1
and E
2
.
The electrical circuit CE supplies a load
12
by means of a mechanical displacement electrical contact
14
of the relay. The relay according to the invention essentially comprises a microcontroller
10
providing for the opening and closing of the relay; the mechanical displacement electrical contact
14
; an N channel IGBT type transistor
15
series-connected by its emitter E with the anode of a protection diode
16
, the assembly formed by the series-connected transistor
15
and diode
16
being parallel-connected to the contact
14
actuated by a coil
17
of an electromagnet
18
; a voltage detector
20
of the voltage at the terminals of the contact
14
. The microcontroller
10
furthermore comprises a current detector
22
of the current I travelling through the electrical circuit CE and crossing the contact
14
of the relay.
Two inputs
24
and
26
of the current detector
22
are connected to the two terminals
28
and
30
of the shunt
32
series-connected in the electrical circuit CE, the shunt giving a voltage ul at its terminals
28
and
30
that is proportional to the value of the current I in the electrical circuit.
The microcontroller
10
has a logic input
34
connected to a control input CD of the relay, a control output
36
supplying, by means of an amplifier
38
, the coil
17
of the electromagnet
18
and a conduction output
19
connected to the control input G of the IGBT type transistor
15
.
A current detection input
40
and a voltage detection input
42
of the microcontroller
10
are respectively connected to a current information output
44
of the current detector
22
and a voltage information output
46
of the voltage detector
20
.
A first control signal corresponding to a voltage Vc in the low state applied, through the control input CD of the relay, to the logic input
34
of the microcontroller drives the closing of the electrical contact
14
of the relay. A second control signal, corresponding to a voltage Vc in the high state, applied to the same control input CD of the relay, drives the opening of the same contact.
Hereinafter we shall explain the working of the relay by means of the diagram of FIG.
1
and the state graphs corresponding to the states in time of the inputs and outputs of the different elements of the relay.
1) Closing of the relay
(See
FIGS. 1
,
2
a
,
2
b
,
2
c
,
2
d
,
2
e
)
In an initial state before a point in time t
0
, the voltage Vc applied to the control input CD of the relay is in the low state and the relay is in the open state. In this open state of the relay, the contact
14
is open and the transistor
15
is off, and the potential at the conduction output
19
of the microcontroller
10
is in the low state (close to zero volts).
FIG. 2
a
shows the logic level control voltage Vc as a function of time.
FIG. 2
b
shows the voltage Dv at the voltage information output
46
of the voltage detector
20
.
The voltage Dv is in the form of square waves whose leading and trailing edges occur respectively at the points in time tv
1
, tv
2
, tv
3
, tv
4
, tv
5
, tvn, corresponding to the changes in the direction of the half waves of the voltage V at the terminals of the contact
14
, a leading edge corresponding to the passage from the negative voltage half wave V to the positive voltage half wave V, and a trailing edge representing the reverse. Since the contact
14
is open before the point in time t
0
, the voltage V at the terminals of the contact is substantially equal to the voltage U of the electrical circuit.
Since the relay is in the open state, it is desired to close it at the point in time to by applying the second control signal to its input CD in the form of a logic level in the high state of the control voltage Vc.
At this instant t
0
, the control voltage Vc goes from the state
0
(open relay) to the state
1
. This logic level at the high state, applied to the control input CD of the relay, is transmitted to the logic input
34
of the microcontroller which activates a sequence of closing the relay.
The voltage detector
20
gives the microcontroller the information on change in alternation enabling it to determine the start of the positive half waves of the voltage U of the electrical network CE corresponding to the forward direction of the N channel type IGBT transistor
15
. The microcontroller controls the contact by anticipation so that the selection switching is done in the half wave corresponding to the forward direction of the transistor
15
. To this end, the microcontroller, after the appearance of the first relay control signal at the instant t
0
, computes a first waiting period dTR
1
for the generation, at the powering-on output
19
of the microcontroller, of a first powering-on signal producing the saturation of the transistor
15
at the time tc (high state on
FIG. 2
e
) in the half wave corresponding to the forward direction of the transistor and at a point in time corresponding to the change in alternation (tv
4
) of the voltage at the terminals of the contact
14
.
The microcontroller
10
computes a second waiting period dTC
2
to generate a signal for closing the contact (high state at the control output
36
) which, by means of the amplifier
38
, powers the control coil
17
(
FIG. 2
c
) for the contact
14
. The second waiting period dTC
2
will be computed so that the contact will be closed at the time t
2
shortly after the saturation of the transistor
15
. The duration of the first powering-on signal of the transistor will be adjusted by the microcontroller
10
so that the saturation period Dc
1
of the transistor
15
after the closing of the contact
14
is sufficient to eliminate the effects of rebounds, if any, of the contact as described above.
The closing signal is shown in
FIG. 2
c
by the passage, at the time t
1
, of the logic output
36
of the microcontroller from the low state (
0
in the figure) to the high state (
1
). The passage to the state
1
of the logic output
36
leads to the powering of the coil
17
of the electromagnet
18
of the relay by means of the amplifier
38
and to the closing of the electrical contact
14
after a closing time dT
1
that corresponds to the characteristic delay time of the electromechanical relay between its command at the instant t
1
(power supply to the coil
17
) and the closing of the electrical contact at a following instant t
2
.
Let Vmax be the maximum voltage at the terminals of the open contact
14
and Vε the voltage at the terminals of the same contact at the time of its closing at the instant t
2
, the transistor
15
being, at this point in time t
2
, in the saturated state (or conductive state). The voltage Vε will be the saturation voltage of the transistor
15
namely about 2.1 volts, a very low value as compared with the maximum voltage Vmax at the terminals of the contact.
The closing of the contact with very low voltage Vε at its terminals produces practically no electrical arc between the contacts when current is set up in the contact.
2) Opening of the relay
(See
FIGS. 1
,
3
a
,
3
b
,
3
c
,
3
d
and
3
e
)
In an initial state before the time t
10
, the relay is in the closed state, the voltage Vc applied to the control input CD of the relay being in the high state.
FIG. 3
a
shows the logic level control voltage Vc as a function of time.
FIG. 3
b
shows the voltage Di at the current information output
44
of the current detector
20
.
With the contact closed, the current of the electrical circuit flows through the contact
14
, and the shunt
32
gives the microcontroller the current information corresponding to Di.
The voltage Di is in the form of square waves whose leading and trailing edges occur respectively at the points in time ti
1
, ti
2
, ti
3
, ti
4
, ti
5
, . . . , tin, corresponding to the changes in direction of the current half waves I in the electrical circuit, a leading edge corresponding to the passage from the negative current half wave to the positive current half wave and a trailing edge corresponding to the reverse.
Since the relay is in the closed state, it is opened at the instant t
10
by applying the first control signal to its input CD in the form of a logic level of the control voltage Vc in the low state.
At this point in time t
10
, the control voltage Vc goes from the state
1
(closed relay) to the state
0
. This low state logic level is transmitted to the logic input
34
of the microcontroller which activates a sequence of opening the relay.
The current detector
22
gives the microcontroller the half-wave changing information that it can use to determine the starting of the positive half waves of the current in the electrical network CE. The microcontroller controls the contact by anticipation so that the switching is done in the half wave corresponding to the forward direction of the transistor
15
. To this end, the microcontroller, after the appearance of the first control signal of the relay of the instant t
10
, computes a third waiting period dTR
3
for the generation, at the powering-on output
19
of the microcontroller, of a second powering-on signal (high state in
FIG. 3
e
) producing the saturation of the transistor
15
in the half-wave corresponding to the forward direction of the transistor and at a point in time ti
5
close to the change in alternation of the current in the contact
14
.
The microcontroller
10
computes a fourth waiting period dTC
4
to generate a signal for opening the contact
14
(low state at the control output
36
) using the amplifier
38
to interrupt the supply of the control coil of the contact
14
. The fourth waiting period dTC
4
is computed so that the contact is closed shortly after the saturation of the transistor
15
.
The duration of the second signal for powering on the transistor will be set by the microcontroller
10
so that the duration of saturation Dc
2
of the transistor
15
after the opening of the contact
14
is sufficient to eliminate the effects of rebounds, if any, of the contact. If the second signal for powering on the IGBT transistor
15
stops shortly after the passage through zero of the current (at the time ti
5
), the transistor
15
will open naturally at the passage through zero of the current owing to the blocking of the series-mounted diode
16
. This prevents disturbances of the network.
The closing signal is shown in
FIG. 3
c
by the passage of the logic output
36
of the microcontroller, at the time t
11
, from the high state (
1
in the figure) to the low state (
0
). The passage of the logic output
36
to the state
0
causes the switching of the supply of the coil
17
of the electromagnet
18
of the relay and the closing of the electrical contact
14
after a closing time dT
2
corresponding to the delay time that is characteristic of the electromechanical relay between the time when it is commanded at the instant t
1
(switching of the supply of the coil
17
) and the opening of the electrical contact at a following instant t
12
.
Let Imax be the maximum current in the closed contact
14
, the current in the same contact at the time of its opening at the instant t
12
will disappear very quickly flowing into the saturated transistor and producing no electrical arc when the contact is open.
The relay according to the invention has advantages as compared to the prior art relays among which we may mention the following:
an improvement in the longevity of the contacts that brings it close to the mechanical longevity;
an improvement in performance enabling a reduction in the size of the relay;
the transistor and the diode used could be smaller-sized owing to a short time of use during the switching;
a reduction in the switching noise on the upline network;
a reduction of the acoustic noise owing to the reduction in the size of the relay.
Claims
- 1. An electromechanical relay designed to be inserted into an electrical circuit, the relay comprising:a mechanical displacement electrical contact; a transistor parallel-connected with the electrical contact; means for commanding a closing of the contact and a powering-on of the transistor in response to a first control signal and for commanding an opening of the contact and the powering-on of the transistor in response to a second control signal, wherein the means for commanding: generates, from the first control signal, a mechanical displacement contact closing signal that precedes the closing of the contact, the closing of the contact being done for a voltage V at terminals of the contact that correspond to a forward direction of the transistor, generates, from the first control signal, independently of the closing signal, a first signal for powering on the transistor that starts before the closing of the contact and ends after the closing of the contact, generates, from the second control signal, a mechanical displacement contact opening signal that precedes the opening of the contact, the opening of the contact being done for a current in the contact corresponding to the forward direction of the transistor, and generates, from the second control signal, independently of the opening signal, a second signal for powering on the transistor that starts before the opening of the contact and ends after the opening of the contact, wherein the means for commanding comprises a microcontroller having inputs that respectively receive control commands for the relay, a piece of information on current I in the electrical circuit and a piece of information on voltage V at the terminals of the contact and a control output giving the first and second control signals for opening and closing the contact and an output for powering on the transistor, and wherein the microcontroller has computation means for computing, after an appearance of the first control signal from the relay: a first waiting period for generating, at the powering-on output of the microcontroller, a first powering-on signal producing a saturation of the transistor in a half-wave corresponding to the forward direction of the transistor and at a point in time close to the change in alternation of the voltage at the terminals of the contact, and second waiting period for generating a signal for closing the contact which, by the amplifier, powers the control coil for the contact, the second waiting period being computed so that the contact will be closed shortly after the saturation of the transistor.
- 2. The electromechanical relay according to claim 1, wherein when the relay is powered with alternating current:the first signal for powering on the transistor is generated when the voltage V corresponding to the forward direction of the transistor is close to a change in direction of an alternation of the voltage V at its terminal, and the second signal for powering on the transistor is generated when the current corresponding to the forward direction of the transistor is close to a change in direction of the alternation of current in the contact.
- 3. The electromechanical relay according to claim 1, wherein the transistor parallel-connected with the electrical contact is chosen from among IGBT type transistors, bipolar transistors or MOS transistors.
- 4. The electromechanical relay according to claim 1, wherein the transistor is series-connected with a diode for protection against reverse voltages at terminals of the transistor.
- 5. The electromechanical relay according to claim 1, wherein the transistor is an N channel IGBT type transistor, the transistor is series-connected by an emitter of the transistor with an anode of the protection diode, an assembly formed by the transistor and the diode in series being parallel-connected to the contact, and the contact being actuated by a coil of an electromagnet.
- 6. The electromechanical relay according to claim 5, further comprising:a voltage detector for detecting the voltage V at the terminals of the contact; a current detector for detecting the current I crossing the electrical circuit and crossing the contact, two inputs of the current detector being connected to two terminals of a shunt in series in the electrical circuit, the shunt giving, at its terminals, a voltage proportional to a value of the current I in the electrical circuit, wherein the microcontroller includes a logic input connected to a control input of the relay, a control output supplying, by an amplifier, the coil of the electromagnet and a conduction output connected to the gate of the IGBT transistor, and wherein a current detection input and a voltage detection input of the microcontroller is respectively connected to a current information output of the current detector and to a voltage information output of the voltage detector.
- 7. An electromechanical relay designed to be inserted into an electrical circuit, the relay comprising:a mechanical displacement electrical contact; a transistor parallel-connected with the electrical contact; means for commanding a closing of the contact and a powering-on of the transistor in response to a first control signal and for commanding an opening of the contact and the powering-on of the transistor in response to a second control signal, wherein the means for commanding: generates, from the first control signal, a mechanical displacement contact closing signal that precedes the closing of the contact, the closing of the contact being done for a voltage V at terminals of the contact that correspond to a forward direction of the transistor, generates, from the first control signal, independently of the closing signal, a first signal for powering on the transistor that starts before the closing of the contact and ends after the closing of the contact, generates, from the second control signal, a mechanical displacement contact opening signal that precedes the opening of the contact, the opening of the contact being done for a current in the contact corresponding to the forward direction of the transistor, and generates, from the second control signal, independently of the opening signal, a second signal for powering on the transistor that starts before the opening of the contact and ends after the opening of the contact, wherein the means for commanding comprises a microcontroller having inputs that respectively receive control commands for the relay, a piece of information on current I in the electrical circuit and a piece of information on voltage V at the terminals of the mechanical displacement electrical contact and a control output giving the first and second control signals for opening and closing the contact and an output for powering on the transistor, and wherein the microcontroller has computation means for computing, after an appearance of the first command from the relay: a third waiting period for generating, at the powering-on output of the microcontroller, a second powering-on signal producing a saturation of the transistor in a half-wave corresponding to the forward direction of the transistor and at a point in time close to the change in alternation of the current in the contact, and a fourth waiting period for generating a signal for opening the contact using the amplifier to interrupt the supply of the control coil, the fourth waiting period being computed so that the contact is closed shortly after the saturation of the transistor.
- 8. The electromechanical relay according to claim 7, wherein when the relay is powered with alternating current:the first signal for powering on the transistor is generated when the voltage V corresponding to the forward direction of the transistor is close to a change in direction of an alternation of the voltage V at its terminal, and the second signal for powering on the transistor is generated when the current corresponding to the forward direction of the transistor is close to a change in direction of the alternation of current in the contact.
- 9. The electromechanical relay according to claim 7, wherein the transistor parallel-connected with the electrical contact is chosen from among IGBT type transistors, bipolar transistors or MOS transistors.
- 10. The electromechanical relay according to claim 7, wherein the transistor is series-connected with a diode for protection against reverse voltages at terminals of the transistor.
- 11. The electromechanical relay according to claim 7, wherein the transistor is an N channel IGBT type transistor, the transistor is series-connected by an emitter of the transistor with an anode of the protection diode, an assembly formed by the transistor and the diode in series being parallel-connected to the contact, and the contact being actuated by a coil of an electromagnet.
- 12. The electromechanical relay according to claim 11, further comprising:a voltage detector for detecting the voltage V at the terminals of the contact; a current detector for detecting the current I crossing the electrical circuit and crossing the contact, two inputs of the current detector being connected to two terminals of a shunt in series in the electrical circuit, the shunt giving, at its terminals, a voltage proportional to a value of the current I in the electrical circuit, wherein the microcontroller includes a logic input connected to a control input of the relay, a control output supplying, by an amplifier, the coil of the electromagnet and a conduction output connected to the gate of the IGBT transistor, and wherein a current detection input and a voltage detection input of the microcontroller is respectively connected to a current information output of the current detector and to a voltage information output of the voltage detector.
- 13. An electromechanical relay designed to be inserted into an electrical circuit, the relay comprising:a mechanical displacement electrical contact; a transistor parallel-connected with the electrical contact; a microcontroller configured to command a closing of the contact and a powering-on of the transistor in response to a first control signal and to command an opening of the contact and the powering-on of the transistor in response to a second control signal, wherein the microcontroller: generates, from the first control signal, a mechanical displacement contact closing signal that precedes the closing of the contact, the closing of the contact being done for a voltage V at terminals of the contact that correspond to a forward direction of the transistor, generates, from the first control signal, independently of the closing signal, a first signal for powering on the transistor that starts before the closing of the contact and ends after the closing of the contact, generates, from the second control signal, a mechanical displacement contact opening signal that precedes the opening of the contact, the opening of the contact being done for a current in the contact corresponding to the forward direction of the transistor, and generates, from the second control signal, independently of the opening signal, a second signal for powering on the transistor that starts before the opening of the contact and ends after the opening of the contact, wherein the the microcontroller has inputs that respectively receive control commands for the relay, a piece of information on current I in the electrical circuit and a piece of information on voltage V at the terminals of the contact and a control output giving the first and second control signals for opening and closing the contact and an output for powering on the transistor, and wherein the microcontroller computes, after an appearance of the first control signal from the relay: a first waiting period for generating, at the powering-on output of the microcontroller, a first powering-on signal producing a saturation of the transistor in a half-wave corresponding to the forward direction of the transistor and at a point in time close to the change in alternation of the voltage at the terminals of the contact, and second waiting period for generating a signal for closing the contact which, by the amplifier, powers the control coil for the contact, the second waiting period being computed so that the contact will be closed shortly after the saturation of the transistor.
- 14. An electromechanical relay designed to be inserted into an electrical circuit, the relay comprising:a mechanical displacement electrical contact; a transistor parallel-connected with the electrical contact; a microcontroller configured to control a closing of the contact and a powering-on of the transistor in response to a first control signal and to command an opening of the contact and the powering-on of the transistor in response to a second control signal, wherein the microcontroller: generates, from the first control signal, a mechanical displacement contact closing signal that precedes the closing of the contact, the closing of the contact being done for a voltage V at terminals of the contact that correspond to a forward direction of the transistor, generates, from the first control signal, independently of the closing signal, a first signal for powering on the transistor that starts before the closing of the contact and ends after the closing of the contact, generates, from the second control signal, a mechanical displacement contact opening signal that precedes the opening of the contact, the opening of the contact being done for a current in the contact corresponding to the forward direction of the transistor, and generates, from the second control signal, independently of the opening signal, a second signal for powering on the transistor that starts before the opening of the contact and ends after the opening of the contact, wherein the microcontroller has inputs that respectively receive control commands for the relay, a piece of information on current I in the electrical circuit and a piece of information on voltage V at the terminals of the mechanical displacement electrical contact and a control output giving the first and second control signals for opening and closing the contact and an output for powering on the transistor, and wherein the microcontroller computes, after an appearance of the first command from the relay: a third waiting period for generating, at the powering-on output of the microcontroller, a second powering-on signal producing a saturation of the transistor in a half-wave corresponding to the forward direction of the transistor and at a point in time close to the change in alternation of the current in the contact, and a fourth waiting period for generating a signal for opening the contact using the amplifier to interrupt the supply of the control coil, the fourth waiting period being computed so that the contact is closed shortly after the saturation of the transistor.
Priority Claims (1)
Number |
Date |
Country |
Kind |
99 07218 |
Jun 1999 |
FR |
|
PCT Information
Filing Document |
Filing Date |
Country |
Kind |
PCT/FR00/01378 |
|
WO |
00 |
Publishing Document |
Publishing Date |
Country |
Kind |
WO00/75947 |
12/14/2000 |
WO |
A |
US Referenced Citations (4)
Foreign Referenced Citations (5)
Number |
Date |
Country |
42 44 116 |
Mar 1994 |
DE |
0 660 348 |
Jun 1995 |
EP |
2 525 386 |
Oct 1983 |
FR |
2 579 007 |
Sep 1986 |
FR |
2 185 856 |
Jul 1987 |
GB |