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Claims  |
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What is claimed:
1. An electromagnetic switch comprising:
separable contacts;
electromagnetic means having a coil which is energized during a contact
closure cycle to close said separable contacts and to hold said separable
contacts closed, and which is deenergized to open said separable contacts;
power supply means for applying current to energize said coil; and
control means for sensing said current applied to said coil and regulating,
throughout said contact closure cycle, said current applied to said coil,
said control means including means regulating a closing current to a
plurality of different closing current references during a period of time
about as long as required for said separable contacts to seal closed and a
holding current to a holding current reference for holding said separable
contacts closed.
2. The electromagnetic switch as recited in claim 1, wherein said control
means comprises a microcomputer for generating said current references.
3. The electromagnetic switch as recited in claim 1, wherein said control
means further comprises:
first switching means, responsive to a first control signal, for
selectively enabling or inhibiting current flow through said coil from
said power supply means;
second switching means, responsive to a second control signal, for
selectively conducting current flow from said first switching means;
first control means for selectively generating said second control signal,
wherein said second control signal comprises a square wave switching
signal for actuating said second switching means between conductive and
non-conductive states; and
second control means for generating said first control signal, wherein said
first control signal comprises a switching signal for actuating said first
switching means between enabled and inhibited states, and further wherein
said first switching means is switched to said enabled state whenever said
square wave switching signal is generated and is switched to said
inhibited state whenever said square wave switching signal is not
generated.
4. The electromagnetic switch as recited in claim 3, wherein said square
wave switching signal comprises a pulse-width modulated signal having a
variable duty cycle and wherein said first control means is responsive to
a feedback signal for varying said variable duty cycle of said pulse-width
modulated signal in response thereto.
5. The electromagnetic switch as recited in claim 4, wherein said first
control means further comprises feedback means for sensing a level of
current flowing through said second switching means from said first
switching means, and for generating said feedback signal in relation
thereto.
6. The electromagnetic switch as recited in claim 5, wherein said first
control means includes means responding to a first input signal for
selectively enabling the generation of said square wave switching signal
and means responding to a second input signal for forcing said pulse-width
modulated signal between states corresponding to said closing current
references and said holding current reference.
7. The electromagnetic switch as recited in claim 6, wherein said control
means further includes a microcomputer which generates said first and said
second input signals in order to generate said closing current references
and said holding current reference.
8. The electromagnetic switch as recited in claim 6, wherein said means
responding to said second input signal attenuates said feedback signal in
response to said second input signal, in order to provide said closing
current references.
9. The electromagnetic switch as recited in claim 6, wherein said means
responding to said second input signal passes said feedback signal
unattenuated in response to said second input signal, in order to provide
said holding current reference.
10. The electromagnetic switch as recited in claim 5, wherein said feedback
means includes comparator means for comparing a predetermined reference
signal and said feedback signal, and for resetting said square wave
switching signal to an inhibiting state whenever said feedback signal is
greater than said predetermined reference signal.
11. The electromagnetic switch as recited in claim 3, wherein said second
control means further comprises fly-back diode means for selectively
conducting current from said first switching means to said power supply
means when said first switching means is enabled and said second switching
means is non-conductive.
12. The electromagnetic switch as recited in claim 1, wherein said means
regulating a closing current includes means providing an initial closing
current at a start of said contact closure cycle, means providing an
intermediate closing current which is smaller than said initial closing
current, means providing progressively smaller currents between said
initial closing current and said intermediate closing current, means
providing a final closing current which is larger than said initial
closing current, and means providing progressively smaller currents
between said final closing current and said holding current.
13. An electromagnetic switch comprising:
separable contacts;
electromagnetic means having a coil which is energized during a contact
closure cycle to close said separable contacts and to hold said separable
contacts closed, and which is deenergized to open said separable contacts,
said electromagnetic means also having a predetermined magnet pull curve
with a step change therein;
power supply means for applying current to energize said coil; and
control means for sensing said current applied to said coil and regulating,
throughout said contact closure cycle, said current applied to said coil
to a time-variable current reference to close said separable contacts and
to hold said separable contacts closed, said control means including means
for generating said time-variable current reference which substantially
follows the step change of the predetermined magnet pull curve.
14. The electromagnetic switch as recited in claim 13, wherein said current
includes an initial closing current at a start of said contact closure
cycle; an intermediate closing current which is smaller than said initial
closing current; progressively smaller currents between said initial
closing current and said intermediate closing current; a final closing
current which is larger than said initial closing current; a holding
current which is smaller than said intermediate closing current; and
progressively smaller currents between said final closing current and said
holding current.
15. The electromagnetic switch as recited in claim 14, wherein said means
for generating said time-variable current reference which substantially
follows the step change of the predetermined magnet pull curve includes
means for generating said time-variable current reference which
corresponds to said initial closing current, means for generating said
progressively smaller currents between said initial closing current and
said intermediate closing current, means for generating said final closing
current, and means for generating said progressively smaller currents
between said final closing current and said holding current, said final
closing current being generated at about a time of closing said separable
contacts.
16. An improved control system for use with an electromagnetic contactor
having a coil for actuating said electromagnetic contactor, separable
contacts actuated by said coil, and a close input for closing said
separable contacts in a contact closure cycle, said control system
comprising:
closed-loop control means for sensing current applied to said coil and
regulating, throughout said contact closure cycle, said current applied to
said coil whenever said close input is active, said control means further
for inhibiting said current applied to said coil whenever said close input
is inactive, said control means including means regulating a closing
current to a plurality of different closing current references during a
period of time about as long as required for said separable contacts to
seal closed and a holding current to a holding current reference for
holding said separable contacts closed.
17. The improved control system as recited in claim 16, wherein said
closed-loop control means comprises:
first switching means, responsive to a first control signal, for
selectively enabling or inhibiting current flow through said coil from a
source of power;
second switching means, responsive to a second control signal, for
selectively conducting current flow from said first switching means;
first control means for selectively generating said second control signal,
wherein said second control signal comprises a square wave switching
signal for actuating said second switching means between conductive and
non-conductive states; and
second control means for generating said first control signal, wherein said
first control signal comprises a switching signal for actuating said first
switching means between enabled and inhibited states, and further wherein
said first switching means is switched to said enabled state whenever said
square wave switching signal is generated and is switched to said
inhibited state whenever said square wave switching signal is not
generated.
18. The improved control system as recited in claim 16 wherein said coil
has a predetermined magnet pull curve with a step change therein; and
wherein said control means includes means for generating a time-variable
current reference which substantially follows the step change of said
predetermined magnet pull curve. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to closure of electromagnetic devices and more
particularly to closure of electromagnetic contactors in which electrical
contacts are closed and held closed by controlling application of current
to a coil of an electromagnet.
2. Background of Information
Electromagnetic contactors are electrically operated switches used for
controlling motors and other types of electrical loads. Contactors include
a set of movable electrical contacts which are brought into contact with a
set of fixed contacts to close the contactor. The contacts are biased open
by a kickout spring. A second spring, called a contact spring, begins to
compress as the moving contacts first touch the fixed contacts. The
contact spring determines the amount of current that can be carried by the
contactor and the amount of contact wear that can be tolerated. The
movable contacts are carried by an armature of an electromagnet.
Energization of the electromagnet overcomes the spring forces and closes
the contacts.
In earlier contactors, the energy applied to a coil of the electromagnet
was substantially in excess of that required to effect closure. While it
is desirable to have a positive closing to preclude welding of the
contacts, the excess energy is unnecessary and even harmful. If the
armature of the electromagnet seats while traveling at a high velocity,
the excess kinetic energy is absorbed by the mechanical system as shock,
noise, heat, vibration and contact bounce.
One type of electromagnetic contactor is disclosed in U.S. Pat. No.
4,893,102. This system reduces contact bounce which may occur when the
respective contacts of the electromagnetic contactor impact each other
during an actuation cycle. This is achieved by controlling energization of
the contactor coil in four separate stages: (1) an acceleration stage; (2)
a coast stage; (3) a grab stage; and (4) a hold stage. When at rest, the
contacts are held in a normally open position by the force of the kickout
spring disposed within the contactor assembly. In the acceleration stage,
the contactor coil is fully energized and the contacts are accelerated
toward a closed position at a maximum rate. In the coast stage, the
contact mechanism has already achieved enough velocity to achieve closure,
so energization of the contactor coil is reduced or eliminated entirely to
reduce the force of contact closure impact to a minimum level. In the grab
stage, the system evaluates a closing velocity of the contactor mechanism
and adjusts energization of the contactor coil to ensure the contactor
mechanism has enough momentum to guarantee contact closure. Finally, in
the hold stage, energization of the contactor coil is reduced to a level
sufficient to counteract the force of the kickout spring and maintain the
contacts in a closed position.
U.S. Pat. No. 5,128,825 is directed to an electromagnetic contactor which
accommodates to dynamic conditions of the contactor coil and supply
voltage to provide consistent closure characteristics of low impact
velocity and reduced contact bounce of about 6 ms. The contactor gates a
first voltage pulse to the coil of the contactor electromagnet at a fixed,
preferably full, conduction angle, and monitors the electrical response of
the coil, namely the peak current. The conduction angle of the second
pulse is then adjusted based upon the peak current produced by the first
voltage pulse and the voltage of the first pulse to provide, together with
the first voltage pulse, a constant amount of electrical energy to the
coil despite variations in coil resistance and supply voltage. The third
and subsequent voltage pulses to the coil of the contactor are gated at
conduction angles preselected in order that, with constant energy supplied
by the first and second voltage pulses, the contacts touch and then seal
at a substantially constant point in a selected pulse. Contact closure can
occur at the third pulse, or in a large contactor where more energy is
required, at a later pulse. Contact touch and sealing consistently occur
on declining coil current in order to achieve low impact velocity and
reduced contact bounce.
Normally, the third and subsequent pulses are gated to the contactor coil
at constant, preselected conduction angles. However, under marginal
conditions for closure where the peak current produced by the first
voltage pulse is below a predetermined value, a second set of conduction
angles is used to gate the third and subsequent voltage pulses to the
coil. This second set of conduction angles produces a substantially full
conduction of the third and subsequent pulses.
While the microcomputer controlled contactor of U.S. Pat. No. 5,128,825 is
a great improvement over earlier contactors, and goes a long way toward
providing positive closure with reduced contact bounce by accounting for
dynamic changes in the characteristics of the contactor electromagnet,
there is room for improvement. Although the volt-amps (VA) required for
closure is premeasured and a recipe is predetermined for closing the
contactor with low bounce, several limitations include: (1) the recipe is
not calculated during operation and, thus, is stored in the limited
non-volatile memory of the microcomputer; (2) the recipe covers a wide VA
range and, therefore, is not optimized for the very low or the very high
ends of the VA range; (3) the recipe provides control without feedback
and, hence, abrupt changes in the line voltage and line frequency are not
included in the closure control algorithm; and (4) stored recipes require
significant digital logic and, thus, additional cost to implement.
There is a need, therefore, for an improved contactor which provides a
consistent closing time and a consistent armature closing velocity with
minimum contact bounce.
There is a further need for such a contactor which consistently reduces
armature closing velocity and, thus, contact bounce time.
There is an additional need for such a contactor which takes into account
dynamic changes in line frequency and line voltage.
There is a more particular need for such a contactor which generally
operates independently of the line frequency and voltage.
SUMMARY OF THE INVENTION
These and other needs are satisfied by the invention which is directed to
an electromagnetic contactor having an electromagnet coil and a
closed-loop current regulator which accommodates to dynamic conditions of
the line voltage, the line frequency and the coil impedance in order to
provide a consistent armature closing time and closing velocity with
minimum contact bounce. The contactor in accordance with the invention
uses field effect transistors (FET's) to gate current to the coil, a
feedback resistor to sense current in the coil, and a feedback comparator
having a current reference signal. The current feedback is adjusted in
order that the current reference signal is selected from a first closing
current reference during contact closure and a second holding current
reference after closure. A microcomputer generates these current
references as a function of time thereby providing a consistent contactor
closing time and closing velocity. In this manner, the coil current is
regulated, throughout the contact closure cycle, to a selected current
reference to close the separable contacts and to hold the separable
contacts closed.
Alternatively, a control circuit generates a time-variable current
reference which substantially follows a predetermined magnet pull curve of
the electromagnet coil. The predetermined magnet pull curve has an initial
closing current at a start of the contact closure cycle, an intermediate
closing current which is smaller than the initial closing current,
progressively smaller currents between the initial closing current and the
intermediate closing current, a final closing current which is larger than
the initial closing current, a holding current which is smaller than the
intermediate closing current, and progressively smaller currents between
the final closing current and the holding current. The control circuit
generates the current reference which corresponds to the initial closing
current, generates progressively smaller currents between the initial
closing current and an intermediate closing current, generates the final
closing current which is larger than the initial closing current, and
generates progressively smaller currents between the final closing current
and the holding current. The final closing current is generated at about
the time of closing the separable contacts.
It is an object of the invention to provide an improved contactor which
uses closed-loop current control throughout a contact closing and holding
cycle in order to provide the appropriate energy required for consistent
closing time and closing velocity with minimum contact bounce.
It is another object of the invention to provide an improved contactor
having a control circuit for making current reference adjustments within
the very short time frame of the contact closure cycle.
BRIEF DESCRIPTION OF THE DRAWINGS
A full understanding of the invention can be gained from the following
description of the preferred embodiment when read in conjunction with the
accompanying drawings in which:
FIG. 1 is a vertical sectional view showing a spatial relationship of a
contactor coil and contacts in a typical three-phase contactor system
incorporating the subject invention;
FIGS. 2A-2C are a schematic circuit diagram and partial block diagram of a
microcomputer-based control system for generating current references and
controlling contactor coil current in accordance with the invention;
FIG. 3 illustrates a coil current waveform, main contact position and
armature velocity for a contactor operated in accordance with the
invention;
FIG. 4A is a schematic diagram of a contactor coil switching arrangement in
accordance with the present invention;
FIG. 4B is a schematic diagram of a circuit used to generate switching
signals for the contactor coil switching arrangement of FIGS. 2B and 4A;
FIG. 4C is a schematic diagram of a feedback circuit used to regulate
current flow in the contactor coil of FIGS. 2B and 4A;
FIG. 4D is a schematic diagram of a feedback circuit used to regulate
current flow in the contactor coil of FIGS. 2B and 4A in accordance with
an alternative embodiment of the invention;
FIG. 5 is a flow chart of a microcomputer firmware routine for generating
current references in accordance with the embodiment of FIGS. 4A-4C;
FIG. 6 is a magnet pull curve illustrating coil current regulation in
accordance with the alternative embodiment of FIG. 4D; and
FIG. 7 illustrates a coil current reference signal, a coil current waveform
and a main contact position for a contactor operated in accordance with
the alternative embodiment of FIG. 4D.
DESCRIPTION OF THE PREFERRED EMBODIMENT
Referring to FIG. 1, a contactor or motor starter 10 has an insulated
housing 12. A complete description of an electromagnetic contactor is
disclosed in U.S. Pat. No. 4,893,102 issued Jan. 9, 1990 and U.S. Pat. No.
5,315,471, issued May 24, 1994, which are herein incorporated by
reference. A pair of spaced apart terminals 14,16 for each phase (only one
phase is shown) are provided for connecting an electrical load, such as a
motor winding which is to be controlled by the contactor 10, to a power
source. Terminal 14 is interconnected with an internal conductor 20
leading to a fixed contact 22 while terminal 16 is interconnected with an
internal conductor 24 connected to a fixed contact 26. A contact carrier
or armature 42 supports an electrically conductive contact bridge 44
having movable contacts 46,48 at opposite ends which are complementary
with the fixed contacts 22,26, respectively.
Movement of the armature 42 and, therefore, the contact bridge 44 and
movable contacts 46,48 is effected by a magnet 36 having a coil SC. The
coil SC is, in turn, controlled by a circuit board 128 to be described in
detail below. The armature 42 is spring biased to the position shown in
FIG. 1 in which the contact pairs 22,46 and 26,48 are opened to interrupt
the circuit between terminals 14 and 16. When the coil SC is energized,
the armature 42 is pulled down against the magnet 36 in order to close the
contact pairs 22,46 and 26,48. Therefore, the circuit is completed to
energize the load, such as a motor winding connected to the contactor 10.
FIGS. 2A-2C together illustrate a schematic circuit diagram and partial
block diagram for the control board 128 which generates current references
and controls operation of coil SC. The heart of the control circuit 128 is
a microprocessor provided on the integrated circuit chip CU1. A suitable
microprocessor chip CU1 is the "sure chip plus" which is disclosed in more
detail in U.S. Pat. No. 5,270,898, issued Dec. 14, 1993, which is herein
incorporated by reference. The chip CU1 includes a multiplexer, a
processor, an EEPROM memory, and analog and digital input and output
interfaces. The pins of CU1, shown in FIGS. 2A-2B herein, are disclosed in
greater detail in FIG. 82 and column 114, line 46 through column 117, line
46 of U.S. Pat. No. 5,270,898. Pin VDD of CU1 is connected to voltage
CVDD. The EEPROM, A/D and RAM sub-systems of CU1 are disclosed in greater
detail in column 8, line 13 through column 11, line 22 of U.S. Pat. No.
5,270,898.
Referring to FIG. 2A, four input terminals labeled 1-4, are provided on an
input connector CJ1. Terminal 4 is connected to system common or ground
and is designated the "C" input. Terminal 1 of the connector CJ1 inputs a
start signal which is identified as "3" and is applied to the chip CU1 to
start the motor. Terminal 2 of the connector CJ1 provides a permit signal
"P" which must be present in order for the motor to run. Terminal 3 of the
connector CJ1 receives the 120 volt line voltage which is designated as
the signal "E". This line voltage signal "E" provides power for operation
of the microprocessor CU1 and for energization of the contactor coil SC.
The signals "3", "P" and "E" are respectively passed through low pass
filters formed by the resistors CR1-CR3 and capacitors CC1-CC3 before
being applied to the chip CU1. A varistor CMV1 protects the control board
128 from surges in the line voltage signal "E".
A power supply circuit PSC, which is fed by the line voltage signal "E",
provides regulated voltages for the chip CU1. Current transformers
CL1A,CL1B, CL1C monitor the three-phase load current for input to the chip
CU1 through multiplexer inputs MUX0,MUX1,MUX2, respectively. The system
voltage as represented by the "E" signal is input through multiplexer
input MUX3.
Referring now to FIG. 2B, the line voltage signal "E" is rectified by the
bridge circuit formed by the diodes CCR10-CCR13 to generate a pulsating DC
voltage+VDC at terminal 108 for energizing the contactor coil SC. An
optional filter (not shown) may filter the+VDC voltage between DC power
terminal 108 and DC ground terminal 110. A current regulator system 100
induces current flow in the contactor coil SC via the switching action of
transistors 104, 106. Specifically, when each of transistors 104,106 are
forward biased or "turned-on", current flows from the DC power terminal
108, through coil SC, transistors 104, 106 and feedback resistor 324, to
DC ground terminal 110. When current flows through contactor coil SC, the
resulting magnetic field moves armature 42 (see FIG. 1), thereby closing
contact pairs 22,46 and 26,48.
The level of current flow through contactor coil SC is controlled by the
duty cycle of transistor 106 which is regulated by contactor coil drive
circuit 132. Contactor coil conduction control circuit 130 provides for
biasing of transistor 104 during the time that the coil SC is energized
and the contactor is closed and, also, provides for a rapid turn-off of
transistor 104 whenever the contactor is opened. Contactor coil drive
circuit 132 generates a pulse-width modulated switching signal used for
activating contactor coil SC. In addition, contactor coil drive circuit
132 regulates a level of current flowing in the transistors 104,106 during
contactor coil conduction cycles via the pulse-width modulated switching
signal. Fly-back diode 133 provides a path for current flow through
contactor coil SC and transistor 104 during positive transitions of the
pulse-width modulated switching signal which occur during contactor coil
conduction cycles. A coil current sense signal COIL I SENSE is filtered by
a low pass filter of FIG. 2A formed by resistor CR7 and capacitor CC12
before being input to the chip CU1. Current regulation is provided through
feedback comparator 134 which senses the current flowing through contactor
coil SC during contactor coil conduction cycles and generates an error
signal for adjusting the duty cycle of the pulse-width modulated signal
generated by contactor coil drive circuit 132.
Contactor coil drive circuit 132 also responds to two control signals
designated TIME.sub.-- OPEN and FETDRIVE which are generated by processor
CU1 (see FIGS. 2A and 2C). The specific function of the TIME.sub.-- OPEN
and FETDRIVE signals is discussed in detail below with FIGS. 4B and 4C.
Briefly however, upon receiving a start signal and a permit signal,
processor CU1 simultaneously generates the TIME.sub.-- OPEN and FETDRIVE
control signals to energize the contactor coil SC with a predetermined
closing current. Then, after a predetermined time interval, the FETDRIVE
signal is reset, in order to continue to energize contactor coil SC with a
predetermined holding current. The coil current is regulated throughout
the entire contact closure cycle. Upon removal of the permit signal,
processor CU1 resets the TIME.sub.-- OPEN signal to cancel the pulse-width
modulated switching signal, thereby deactivating contactor coil SC.
The contactor 10 provides overload protection for the load, such as a
motor, connected to the contactor. Dip switch CSW2 has eight switches of
which five switches are used to select the rated current for the motor
being controlled through the inputs PA0-PA4 of the chip CU1. The other
three switches of dip switch CSW2 are provided to select two trip delays
through inputs PA5 and PA6, and a manual/automatic thermal reset through
input PA7.
Turning to FIG. 2C, an external capacitor CC11 stores a motor heat profile
characteristic value generated by the chip CU1. This value is applied to
the capacitor CC11 through a port PC4 and a resistor CR30. The value of
the heat profile characteristic stored in the capacitor CC11 decays by
discharge through a resistor CR31 at a rate which mimics the cooling of a
motor controlled by the contactor 10 when power has been removed from the
circuit board 128. The charge stored on the capacitor CC11 is read by the
chip CU1 through the multiplexer input MUX5 which is connected to the
capacitor CC11 through a resistor CR36.
The contactor 10 can be reset remotely by a signal received through a
connector CJ2 and applied to the chip CU1 as a REMOTE RESET SENSE signal.
The chip CU1 also generates an LEDOUT signal through the connector CJ2 for
energization of an LED on a remote console for indicating the operating
mode of the contactor. The contactor 10 can also be reset locally by
activation of the switch CSW3. The microprocessor based contactor can
communicate with, and be controlled by, a remote station through a serial
data input port SDI and a serial data output port SDO synchronized by a
clock signal which is input through port SCK. The remote clock signal and
the serial data input and output signals are connected to the remote
system through terminals on the connector CJ2.
FIG. 3 illustrates: (A) a coil current waveform; (B) main contact position;
and (C) armature velocity, respectively, for the exemplary embodiment of
FIGS. 1 and 2B. The force required to close an electromagnetic device
(e.g., magnet 36 having coil SC) is proportional to ampere-turns in the
coil of the device. Thus, knowing the number of turns in the coil, coil
current can be regulated in order to provide a known closing force.
Furthermore, knowing the closing force, an accurate value for the closing
time may be predetermined using empirical data.
In particular, whenever contactor 10 closes contacts 22,46 and 26,48, the
current in coil SC is regulated from an initial zero amperes to a fixed
closing current reference of approximately 12 A. This value of closing
current overcomes the friction, inertia and spring forces of the
mechanical system of contactor 10; provides a substantially constant
armature closing velocity at closure, in order to prevent the contacts
22,26,46, 48 from reopening; and ensures that the armature 42 does not
stall at the touch point but continues through with sufficient velocity to
ensure a magnet-armature seal position without undue shock and contact
bounce. In this manner, contact bounce time is reduced from a prior art
time of 6 ms to about 2 ms. Furthermore, the peak armature velocity at
closing is relatively independent of power line voltage and power line
frequency. After the unit is closed, the coil current is reduced from the
closing current reference to a holding current reference of approximately
1 A. Because the magnet-armature gap is small in the seal position, the
coil current is reduced to, and is held constant at the holding current
value, in order to maintain the closed position of armature 42.
Referring now to FIGS. 4A and 4B, the contactor coil conduction control
circuit 130 and the contactor coil drive circuit 132 are shown in
schematic form. Contactor coil SC is driven with a pulse-width modulated
drive signal coupled to terminal 302. The pulse-width modulated drive
signal is generated by monostable multivibrator 402, which is discussed in
greater detail below, and drives complementary transistors 304,306 which
are coupled in a push-pull configuration. Transistor 304, a p-channel FET,
and transistor 306, an n-channel FET, have their respective gates coupled
together. The respective source and drain terminals of transistors 304,306
are coupled via resistor 308. The drain terminal of transistor 306 is the
output terminal 312 of the push-pull pair 304,306. A power supply 314
generates+V DC power from the+VDC voltage between terminals 108, 110. The
+V DC power and ground connections for transistors 304,306 are provided
through terminals 109 and 110, respectively.
In the power supply 314, the anode of a zener diode MCR5 is connected to DC
ground terminal 110. The parallel combination of resistors MR23A,MR23B is
connected between+VDC power terminal 108 and the cathode of zener diode
MCR5. The cathode of zener diode MCR5 is connected to the gate of
transistor MQ3 and provides a reference voltage thereto. The cathode of a
zener diode MCR6 is connected to the gate of transistor MQ3 and the anode
of the zener diode MCR6 is connected to the source of transistor MQ3. A
resistor MR25 is connected in parallel with the zener diode MCR6. The
parallel combination of the resistor MR25 and the zener diode MCR6 protect
the gate of transistor MQ3 from an excessive gate-source voltage. The
drain of the transistor MQ3 is connected to a resistor MR24 which is
connected to the +VDC power terminal 108. The source of the transistor MQ3
is connected to the anode of a diode MCR7. The cathode of the diode MCR7
is connected to the+V power terminal 109. A capacitor MC6 is
interconnected between the+V power terminal 109 and the DC ground terminal
110. The voltage+V at terminal 109 is determined by the discharge
characteristic of capacitor MC6 which discharges through the remainder of
the circuit connected to the terminal 109.
When the voltage of the+VDC power terminal 108 is greater than the voltage
of the+V power terminal 109, transistor MQ3 operates in the linear region
and sources current through diode MCR7 to charge capacitor MC6. When the
pulsating DC voltage of the+VDC power terminal 108 is less than the
voltage of the +V power terminal 109, transistor MQ3 turns off. This
occurs near the zero crossing of the line voltage "E" of FIG. 2B. The
diode MCR7 prevents the discharge of the capacitor MC6 through the
transistor MQ3. In this manner, the power supply 314 converts a generally
pulsating DC voltage formed by the output of the full-wave bridge
CCR10-CCR13 of FIG. 2B at+VDC power terminal 108 to a generally DC voltage
at+V power terminal 109.
In the configuration shown in FIG. 4A, whenever the pulse-width modulated
signal coupled to terminal 302 is driven low, transistor 304 is forced
into conduction, thus generating an output current at terminal 312. During
positive going phases of the pulse-width modulated signal, transistor 304
turns off and transistor 306 turns on, thus rapidly driving terminal 312
low. Accordingly, the signal present at terminal 312 is a phase-inverted,
current amplified version of the pulse-width modulated signal coupled to
terminal 302.
The signal generated at terminal 312 is coupled to the respective gate
terminals of switching transistors 106a, 106b through resistors 316,318,
respectively. Respective zener diodes 320,322 are coupled between the gate
terminals of transistors 106a, 106b and DC ground terminal 110 to provide
protection for the respective transistors in the presence of high voltage
transient signals. The respective source terminals of transistors 106a,
106b are coupled to DC ground terminal 110 via feedback resistor 324. As
is discussed in greater detail below, resistor 324 generates a voltage at
terminal 326 which is related to the level of current flowing in contactor
coil SC. The respective drain terminals of transistors 106a, 106b are
coupled to reference node 325 which is further coupled to the source
terminals of switching transistors 104a, 104b. Reference node 325 is
coupled to DC power terminal 108 through fly-back diode 133.
The respective drain terminals of switching transistors 104a, 104b are
coupled in parallel to one terminal (CJ3 terminal 2 of FIG. 2B) of
contactor coil SC. The opposite end of contactor coil SC is coupled to DC
power terminal 108, in order that whenever transistors 104a-104b and
106a-106b are forward biased, current flows from DC power terminal 108,
through contactor coil SC, through transistors 104a-104b and 106a-106b,
and through feedback resistor 324 to DC ground terminal 110. During
periods when transistors 106a-106b are turned-off and transistors
104a-104b remain conductive, current circulates through contactor coil SC,
switching transistors 104a-104b and fly-back diode 133. Parallel
transistor pairs 104a-104b and 106a-106b are employed to increase the
current handling capacity of the circuit 300. Those skilled in the art
will appreciate that the pairs 104a-104b and 106a-106b may be replaced by
single transistors in many applications.
Bias for transistors 104a-104b is controlled by contactor coil conduction
control circuit 130 which includes NPN transistor 330 disposed with its
collector coupled to DC power terminal 108 and its base coupled to DC
power terminal 108 via resistor 332. Voltage reference zener diode 334 is
coupled between the base of transistor 330 and reference node 325.
Accordingly, resistor 332 and zener diode 334 provide a relatively stable
bias network for transistor 330. The emitter of transistor 330 is coupled
to the gate terminals of switching transistors 104a, 104b via diode 338
and resistors 340,342, respectively. The common junction of resistors 340,
342 and diode 338 is further coupled to a delay network 336 formed by a
resistor 344 and a capacitor 346. Clamping zener diodes 348,350 are
coupled between the respective gate terminals of transistors 104a, 104b
and reference node 325.
In operation, the circuit 300 is activated by the presence of the
pulse-width modulated switching signal coupled to terminal 302. During
negative transitions of the pulse-width modulated signal, transistor 304
conducts, thus injecting current into the gate terminals of transistors
106a-106b causing the transistors 106a-106b to conduct. When transistors
106a-106b turn-on, reference node 325 and the source terminals of
transistors 104a-104b are coupled to ground through transistors 106a-106b.
In this state, as discussed in greater detail below, whenever capacitor
346 is charged, transistors 104a-104b begin to conduct and a closing
current, or a holding current, is induced in contactor coil SC.
Bias for transistors 104a-104b is generated by transistor 330 which
generates a relatively constant current whenever reference node 325 is
driven low by transistors 106a-106b. In other words, when reference node
325 is driven low by transistors 106a-106b, current flows from the emitter
of transistor 330, through diode 338 and delay network 336, to reference
node 325. This action generates a positive voltage at the gate terminals
of transistors 104a-104b which is sufficient to bias and turn-on these
transistors. Furthermore, whenever transistor 330 conducts, capacitor 346
charges to a voltage approximately equal to the voltage of the zener
reference 334.
Whenever the pulse-width modulated signal is present at terminal 302,
transistors 106a-106b are rapidly switched between conductive and
non-conductive states at a frequency of the pulse-width modulated signal.
However, because of the relatively long time constant of delay network 336
with respect to the pulse-width modulated signal, transistors 104a-104b
remain conductive during both positive and negative cycles of the
pulse-width modulated signal. Therefore, during non-conductive states of
transistors 106a-106b, while transistors 104a-104b remain conductive,
current circulates through contactor coil SC and transistors 104a-104b via
fly-back diode 133. However, once the pulse-width modulated signal is
terminated, capacitor 346 is discharged by resistor 344. Once the voltage
across capacitor 346 falls below the switching threshold of transistors
104a-104b, transistors 104a-104b turn-off, thus interrupting the current
circulating between contactor coil SC and fly-back diode 133. In the
exemplary embodiment, capacitor 346 is discharged to the switching
threshold of transistors 104a-104b in approximately 9 ms. Once current
flow through contactor coil SC is interrupted, contactor coil flux rapidly
collapses and the contactor immediately opens.
Referring now to FIGS. 4B and 4C, the pulse-width modulated signal coupled
to terminal 302 is generated by multivibrator 402 which is triggered by
duty cycle generator 404 formed by resistor 406 and capacitor 412. In
operation, capacitor 412 is continuously charged via resistor 406 which is
coupled between+V power terminal 109 and ca | | |
