 |
Claims  |
|
|
What I claim is:
1. Two terminal timed switch device which serves to substantially connect
into but one side of an electric power circuit from which all operative
power is therefrom derived for operation of the time control functions
through utilization of the effects of current flow through the said device
during the timing period "on" state; said timed switch substantially
including:
a. a source of electric a.c. power;
b. an a.c. load means;
c. at least two conductive elements coupled between the said source and
said load, wherein the said elements form substantially a first electric
circuit path and a second electric circuit path for the effective flow of
electric energy between the said source and said load;
d. controlled switch element means coupled effectively in series with at
least one of the conductive element electric circuit paths so as to
alterably effect a condition of maximum electric current flow therethrough
during the timing period and negligible electric current flow therethrough
upon cessation of the said timing period;
e. control means coupled to said switch element means and cooperative
therewith so as to establish the instantaneous condition of electric
current flow therethrough;
f. time delay means including a combination of electronic semiconductor
circuit means, effective so as to provide a time related event signal
which couples to the said control means;
g. power supply means, the output of which is coupled to at least the said
control means and said time delay means so as to effect the operation
thereof; importantly having but two essential input terminals thereto;
said input terminals further being coupled in series with but one said
electric circuit path between the said source and said a.c. load and
operative to receive power therefrom during the period of maximum current
flow, whereas negligible, substantially zero power flow occurs once the
timing period is complete; and,
h. initiating means coupled effectively at least in parallel with said
switch element means and effectively in series with said power supply
means and operative to produce at least a momentary flow of current
through the electric circuit path between the said source and said load
and to thereby effect the control means to establish current flow through
the controlled switch element means for a finite period of time until the
said time related event signal occurs, whereupon the current flow through
the controlled switch element ceases.
2. Device of claim 1 wherein more particularly the said controlled switch
element means includes a thyristor, exemplified as a silicon controlled
rectifier or triac, coupled substantially in series with one of the said
conductive element electric circuit paths and cooperative therewith so as
to regulate the value of current flow through the said circuit path in
response to signals coupled to the said thyristor gate control element
means from the said control means.
3. Device of claim 1 wherein more particularly the said time delay means
includes a sequentiality of bistable logic circuit elements, effective at
least in part as a binary counter serving to produce a time related event
signal which is precisely derived from a continuum of clock pulse cycles,
with each said cycle having a period expressly some integral value which
is less than that of the said event signal overall time period.
4. Device of claim 1 wherein more particularly the said time delay means
includes a sequentiality of bistable logic circuit elements, effective at
least in part as a binary counter, so as to produce a time related event
signal which is precisely devived from a continuum of clock pulse cycles,
with each said cycle having a period which is derived from the inherent
a.c. frequency component provided by the said source of a.c. power.
5. Device of claim 1 wherein more particularly the said time delay means
includes a sequentiality of bistable logic circuit elements, effective at
least in part as a binary counter, so as to produce a time related event
signal which is precisely derived from a continuum of clock pulse cycles,
with each said cycle having a period which is effectively determined by a
mechanical resonant device having individual cycle periods each of which
is expressly less than that of the said event signal overall time period.
6. Device of claim 1 wherein more particularly the said time delay means
includes a level responsive switching circuit means which effects a time
related event signal therefrom as a result of the value of electric charge
accumulated in a charge retention device having reached a predeterminate
magnitude, in a prescribed time interval, as effected by the controlled
flow of current through a circuit combination including the retention
device, by way of a current flow restrictor.
7. Device of claim 1 wherein the said time delay means includes a
multitudinous selection of time related event signals, providing varietal
couplement options with the said control means, resulting in a said device
providing flexability in the choice of time delay values.
8. Device of claim 1 wherein the said time delay means includes a digital,
e.g. binary, interval delay means, as for example a counter, which serves
to provide steps of selectable values of time delay.
9. Device of claim 1 wherein the said time delay means includes a digital,
e.g. binary, interval delay means, as for example a counter, which serves
to provide steps of selectable values of time delay and wherein further
the said selected digital time delay serves to couple to the enabling
input of an analog time delay element, e.g. a one-shot flip-flop or the
like, which includes an adjustment which allows for the quasi-infinite
setting of incremental time delays for producing a time related event
signal which is substantially the sum of the selected digital time delay
and the incremental analog time delay.
10. Device of claim 1 wherein more particularly the said power supply means
includes a current responsive transformer, including at least a primary
portion and a secondary portion, wherein the said primary portion is
effectively coupled in series with but one of the said conductive elements
and responsive therewith to produce a resulting magnetic coupling into the
said secondary portion, as a result of current flow between the said a.c.
power source and the a.c. load through the conductive element coupling,
thereby setting up an a.c. potential value in the said secondary portion
which is at least rectified and filtered and employed as a source of d.c.
potential for the operation of the several semiconductor elements which
serve to make up some part of the several function means which comprise
the said timed switch.
11. Device of claim 1 wherein more particularly the said power supply means
includes a thyristor device coupled effectively in series with but one of
the said conductive elements and is operative as an interrupter device
which serves to effectively inhibit current flow through the said
conductive element during a small percentage of at least one half-cycle of
each a.c. power full-cycle waveform pair of alternate half-cycles,
whereupon further when the said electric potential value developed across
the thyristor due to current flow to the said load increases to a finite
preconductive value, the said thyristor will be in effect turned-on to a
state of maximal conductance resulting in a minimal electric potential
value to be developed across the said thyristor; the purpose being to
utilize the preconductive value of electric potential to charge an
electric accumulator, usually by way of a unilateral conductive device,
e.g. a diode or the like, so as to serve as a source of d.c. potential
during the timing period for the operation of the several semiconductor
elements which serve to make up some part of the several functions which
comprise the said timed switch.
12. Device of claim 1 wherein more particularly the timed switch means
function is initiated by the onset of maximum electric current flow
between the said source of electric a.c. power and the said a.c. load as
usually produced by the temporary closure of a mechanical switch means or
the like connected substantially in parallel with the said controlled
switch element means, yet effectively in series with the serial electric
circuit path produced by the said power supply means said two essential
input terminals and one of the conductive elements coupling the said
source to the said a.c. load, the result of which is to establish
conditions in the circuit functions of the device which will firstly
initialize, then start a series of events which combine to produce a
control function signal suited for continuing the condition of maximum
current flow between the said source and said a.c. load even after the
said mechanical switch means or the like is returned to a normally
non-closed state, with said control function signal continuing for a
finite period of time until the said time delay means produces a said time
related event signal, the effect being that once the said event signal
occurs, the electric circuit path condition between the said a.c. source
and said a.c. load will relax to a condition of negligible electric
current flow.
13. Device of claim 1 wherein at least a temporary connection is
established through at least one of the conductive element circuit paths,
so as to act substantially in parallel, e.g. as a shunt across, the said
controlled switch element; whereby current flow is established between the
said source and the said load firstly by the said temporary connection,
which serves to also initiate the said time delay means function and
thereby enable the said control means; and thereafter by the action of the
said controlled switch element; wherein further such current flow
continues either for a finite time period until a negating time related
event signal occurs from the said time delay means or else the circuit,
including any of the conductive elements coupled between the source and
the load, is interrupted in an effective manner so as to cause the current
flow between the source and the load to cease thereby allowing the time
delay means and control means to reset.
14. Device of claim 1 wherein the said time delay means function commences
when a connective circuit path is operably established, as by a switch or
the like, between the said source and the said a.c. load by an operator;
said time delay function is enabled so as to produce a time related event
signal some finite time interval after said connective circuit path is
made; wherein further substantial current flow between the said source and
the said load by way of the connective circuit path is maintained in a
state of operative maxima by the low on-state impedance of the said
controlled switch element until such finite timing period interval has
elapsed whereupon the said time related event signal occurs thereby
effecting a state of maximum impedance through the said controlled switch
element which produces a state of negligible current flow to be effected
between the said a.c. source and said a.c. load.
15. Device of claim 1 wherein the time delay function is initiated by the
movement of a magnet in proximal relationship with a magnetically
responsive switch element, the result being that to afford the sealed
protection of the timer elements from the effects of a hostile
environment, wherein the main coupling between the actuation means,
controlled by an outside force, and the timer control elements is by way
of the presence or absence of the magnetic field lines produced by the
said magnet.
16. Device of claim 1 wherein the time delay function is initiated by a
light value signal provided by a photoresponsive element, thereby
producing a timed switch control function which occurs some finite time
after the light value passes through a predescribed bounding value.
17. Device of claim 1 wherein the electric control action is that of a
delay interval before load shut-off, once effective conductive element
paths are made between the said a.c. source and said a.c. load means.
18. Device of claim 1 wherein a tell-tale lamp gives indication that the
time delay function is active. |
|
 |
|
 |
Claims |
|
|
|
Description |
|
|
SUMMARY
The invention describes a two terminal timed switch which, in one form, can
provide a ready replacement or substitute for the ordinary electric wall
switch as used by the building trades. The use of a timed switch can save
much energy through the effectual shut-off of forgotten switches, or the
delayed turn-off or turn-on of hallway lights, garage lights, and the
like.
Switches providing time delayed action are known which use thermal
elements, mechanical motors, pneumatic devices, and the like which connect
only in one side of a load circuit. Electric timed switches are also known
which couple in but one side of a load circuit, drawing power for the
operation thereof through the load even when the load circuit provided by
the timed switch is in the "off" state. This invention describes a
significant improvement in that all-electronic timing and control circuit
elements are employed which afford better reliability, excellent
precision, environmental resistance, and low-cost manufacture, while
drawing no current through the load when in the "off" state. Known
electronic timing elements can be had which require connection to both
sides of the electric circuit, i.e. three terminal: input, output, and
common. In-so-far as is known, this invention teaches the first truely two
terminal electronic timer, i.e. input and output only, no common required;
and which draw no current through the load for the sustained operation
thereof when the load is in the timed "off" state. The advantage of this
is that no hazardous electric potential is present at the load during the
off state in the new invention, whereas the substantial finite current in
the earlier timers during the "off" state can induce injury into a workman
or other unsuspecting user when servicing a circuit containing one of the
earlier class of electronic timers. The advantage afforded by this is that
of safe installation, especially in old construction. This is beneficially
significant for the acceptance of the invention by building inspectors and
other safety experts or the like as a widely applicable energy saving
device because the most ordinary S.P.S.T. wall switch, popular for the
control of lights and the like in homes as well as business, requires but
two wires for satisfactory operation. As a result and for the sake of
economy, usual trade practice is to run a single length of so-called
Romex, or two wire type NM cable, between a light fixture and a wall
mounted toggle switch. This practice of course affords no third wire
option, e.g. common, at the switch location therefore limiting the choice
of a timed switch to that of one of the two-terminal mechanical varieties
prior to my invention if a safe state of no current flow was required
during the load timed "off" state. This teaching unfolds a vast
improvement for this class of application, as now the better performing
electronic timing techniques can be practically used with but a two
terminal connection. This is accomplished by deriving the functional
electric voltage values required for satisfactory semiconductor circuit
operation by way of utilizing the current flow between the source and the
load, through but one circuit leg, to produce the necessary functional
voltage values. The invention is further described to usually provide a
delayed-off function. Remote control and over-ride circuit modes are
depicted, giving good exhibit of the flexability of the invention's
essence. Time delays from that of but a few seconds to that of hours,
days, or even longer can be provided by variant implementations of the
instant teachings. The absolute precision of the delay, while not usually
of great import in building related applications, is inherent in that some
part of the delay cycle is derived from a constant frequency source. This
means of time determination does provide more reliable and predictable
service, particularly in seldomly actuated applications and for use in
environmentally hostile locations.
DESCRIPTION OF DRAWING FIGURES
Eight sheets of drawings providing seventeen figures exhibit the teachings
of this invention as:
FIG. 1 Functional diagram showing the interrelationship of the several
essential elements comprising the timed switch.
FIG. 2 Wiring diagram showing the timed switch as a replacement for an
ordinary wall switch or the like.
FIG. 3 Circuit diagram for one embodiment of the teaching providing a
delayed OFF function after the circuit is turned on and having binary time
increments.
FIG. 4 Waveform representations for the circuit described in FIG. 3.
FIg. 5 Circuit diagram for one embodiment of the teaching providing a
delayed OFF function after the circuit is turned on and further showing
decimal time increments and a solid state d.c. power supply.
FIG. 6A Hookup showing the use of a remote OFF control station for the
switch.
FIG. 6B Hookup variation for FIG. 6A showing plural control stations.
FIG. 7 Hookup showing the use of remote ON control stations for the switch.
FIG. 8A Hookup showing the use of remote ON and OFF control stations for
the switch.
FIG. 8B Hookup variation for FIG. 8A showing but a single control station.
FIG. 9 Circuit diagram for one embodiment of the teaching providing a
delayed ON function after circuit energization and further showing a local
time base clock source.
FIG. 10 Waveform representations for the circuit described in FIG. 9.
FIG. 11 Functional diagram showing the interrelationship of the several
essential elements forming a combination of an analog timing element with
the invention essence.
FIG. 12 Circuit detail operative with FIG. 5 to combine incremental analog
delay with the step selected digital delay.
FIG. 13 Circuit detail operative with FIG. 9 so as to provide light
activated control of the timer, as by daylight.
FIG. 14 Circuit detail operative with FIG. 5 so as to provide light
activated control of the timer, as by daylight.
FIG. 15 Circuit detail operative with FIG. 5 so as to provide indirect
magnetic field influence control of the switching function while retaining
minimum current flow through the switch element.
DESCRIPTION OF INVENTION
The gist of the two-terminal timer is taught in FIG. 1. The expression
two-terminal timer refers to an electrical control device which operates
to act upon an electrical circuit after some finite time period has
elapsed, and furthermore wherein such operation takes effect in only one
side of a power circuit and derives power therefrom only when the said
load timed state is "on". Usually the timer is installed in the HOT side
of a circuit, and therefore no common or return is needed. This is of
course basis for considerable improvement over any other known timer
device employing electronic timing techniques, as the usual electronic
timer requires the common, or neutral, for proper operation, or else draws
substantial current via way of the load even when in the load timed "off"
state if of the earlier "two wire" variety. The value in this is to be
found in particular in the use of my invention in old construction, e.g.
pre-existing buildings and the like, where no common or neutral may be
available at the preferred timer switch location. This comes about because
it is usual practice to simply run two wires to the usual wall toggle
switch, etc. in commercial building practice, so as to save on wire cost
and to some extent, labor. FIG. 1 shows a two terminal connection in that
the timer 1 is connected to the hot side L2 of the line, whereas the
common L1 side goes directly to the load 2 and therefore has no direct
connection with the timer device. The artisian will quickly recognize that
as a common and typical wiring installation in houses, stores, and other
building types. No load current will flow until the switch 3 is briefly
closed, whereupon current will flow from input terminal L2 to the load 2
via terminal L3. The current flow so produced will pass also through the
input of a current energized power supply 4, exampled as the primary of a
current transformer or the like. The result is that a d.c. value +E, -E
will be produced which will serve to power the other circuit means which
comprise the timer, in particular the timing signal source 5, the timing
period gate 6, and the switch control driver 7. In addition, a brief reset
signal will be produced by the reset function 9 which serves to initialize
at least the timing signal source 5. The switch control driver 7 will
immediately produce a switch drive signal which will effectively close
switch 8, thereby serving to maintain circuit current flow from the
primary source to the load even when the switch 3 once again opens. The
timing signal source 5 will proceed to produce a delayed signal component
which will act upon the period timing gate 6 after some time has elapsed
as predetermined by the timing signal source 5. When the time period is
up, the timing period gate 6 produces a signal which will act upon the
switch control driver 7 in such a way as to negate the holding action
produced in the switch device 8. Thus current flow to the load 2 via line
L3 will cease. In a typical form for my invention, a brief closure of but
a fraction of a second for switch 3 as produced for example by finger
depression of a momentary contact switch 3 arrangement will serve to
initiate the aforesaid circuit action. The time period which ensues, while
usually pre-established as a particular value or range of values, will in
the typical timer produce a timing period which lasts at least several
minutes. The artisian will of course realize that my invention finds
application for any imaginable time period from merely a few seconds or
less to that of hours, days, or even longer. Furthermore the load 2, while
shown as a lamp load, may of course be any sort of electrically driven
load as for example, a heating device, motor, transformer, or the like.
The hookup of my novel timer as the replacement for a regular switch is
shown in FIG. 2. The leads 10A from the usual terminals 12, 13 on a
lighting device 2A or the like are transferred from the removed regular
switch 14, e.g. the common wall toggle switch or such, leads 10B and
instead connect to the new TIMED SWITCH 1 input L2 and output L3. Common
line L1 connects to the light 2A terminal 11, whilst input L2 connects
through terminal 13 to switch input L2. The result is a "DELAYED OFF"
function, initiated by a momentary contact switch which forms part of the
timer as depicted earlier in FIG. 1.
The circuit form for one preferred embodiment is depicted in FIG. 3. No
load current flows until the momentary switch 3A, when briefly closed,
initiates current flow between the input terminal L2 and the load 2 via
output terminal L3. Transformer 15 connects in series with this current
flow and, therefore, a voltage is determined in the secondary in accord
with the well understood action of a pair of magnetically coupled coils.
The transformer 15 secondary voltage, which is de-spiked by the action of
capacitor 54, couples to a rectifier arrangement including diodes 16A,
16B, 16C, 16D. The rectifier output on line AA is a pulsating d.c. value,
the frequency of which is:
F.sub.p =2F.sub.L
where:
F.sub.p =pulsating d.c. frequency; and,
F.sub.L =input line frequency.
With common 60 hertz (50 hertz) utility power input, the pulsating d.c.
frequency F.sub.p will be 120 hertz (100 hertz), or said another way, the
period will be:
T.sub.p =1/F.sub.p
where: T.sub.p =pulsating d.c. interpulse time period (seconds). Again this
becomes 8.33 milliseconds (10 milliseconds) for 60 hertz (50 hertz)
utility power.
This pulsating d.c. value F.sub.p, better depicted as waveform AA in FIG.
4, couples by way of a resistor 21 to the base of a NPN transistor 20. The
result is a pulsating clock rate frequency in the collector thereof,
across load resistor 22, which is a waveform AB of improved rise time as
applied to the CLOCK input 23 of a divide-by-two connected J-K flip-flop
24. The output 25 is 60 hertz (50 hertz) which couples to the input of a
second divide-by-two flip-flop 26. The resultant 30 hertz (25 hertz)
output 27 produces a timing waveform AC which feeds the CLOCK input of the
divide-by- 2.sup.14 counter 30, for example a R.C.A. type CD-4020 C-MOS
binary counter or the like. The result is a plurality of outputs which may
be selected by way of jumper connection (or switch) 31 so as to produce a
variety of timing waveforms AD as coupled to PNP transistor 32 by way of
resistor 33. With the exampled CD-4020 integrated circuit counter 30, the
following time increments may be expected as the resultant timer cycle:
______________________________________
Jumper 31 connected
Elapsed Time
to counter 30 output:
60 hertz 50 hertz
______________________________________
Q4 0.267 second 0.320 second
Q5 0.533 second 0.640 second
Q6 1.067 seconds 1.280 seconds
Q7 2.133 seconds 2.560 seconds
Q8 4.267 seconds 5.120 seconds
Q9 8.533 seconds 10.240
seconds
Q10 17.067 seconds 20.480
seconds
Q11 34.133 seconds 40.960
seconds
Q12 1.138 minutes 1.365 minutes
Q13 2.276 minutes 2.730 minutes
Q14 4.551 minutes 5.460 minutes
______________________________________
It is necessary to understand the operation prior to the time cycle
completion. When power is first applied, as produced by current flow
between L2 and L3 through the transformer 15, a d.c. voltage will develop
across the capacitor 19 by way of steering diode 18. This produces an
operating d.c. value +Vc for the circuits on line 50. This rapid rise in
+V.sub.c value couples through capacitor 52 to the reset R.sub.0 input on
counter 30; however the reset quickly returns to near ground by the
discharge action of resistor 51. The result is a reset pulse a few
milliseconds (or less) in duration will serve to reset the counter state
outputs to all zeros (logic "0" or LOW). Accordingly the LOW output on
line 31 will serve to turn-on PNP transistor 32, effectively saturating
the device with the result that the collector thereof will be near the
+V.sub.c value as shown in waveform AE. This value couples to the base of
NPN transistor 35 through resistor 36, in turn saturating the transistor
and resultingly drawing the collector value across load resistor 39 as
appearing at connection AF near to ground level. This will cause the
unilateral conductive device, or diode 38 to conduct, with the result that
PNP transistor 37 will be properly forward biased into an ON state. In the
shown hookup, the emitter and base of transistor 37 will be properly
forward biased into an ON state. In the shown hookup, the emitter and base
of transistor 37 are NOT supplied from the +V.sub.c line, but rather from
the source of 120 hertz (100 hertz) pulsating d.c., albeit positive in
sign. The effect is that when the PNP transistor 37 is turned on through
diode 38, the collector current through resistor 46 and therefore as
coupled to the gate of thyristor 45 (a TRIAC in the example) will pulsate
in accord with the 120 hertz (100 hertz) rate as shown in waveform AG.
When the counter 30 output state on the selected line reaches the desired
count and goes logic "1" or HIGH, the transistor 32 will turn-off. The
result is that the transistors 35 and 37 will accordingly turn-off and the
thyristor 45 will commutate on the next half-cycle zero crossing in accord
with well known practice. In the shown hookup, the timing period is equal
to:
T.sub.t =(1/F.sub.AC)(2.sup.Qn-1)
where:
T.sub.t =timing period in seconds;
F.sub.AC =clock input waveform a.c. frequency on counter 30; and
Qn=selected Q line output on counter 30.
The output timing function for FIG. 3 appears as waveform AH in FIG. 4. The
elapsed times for the waveforms of FIG. 4 are shown as interval AT. It
will also be apparent that the control actions all occur on clock pulse
ABA edges ABB, referring to edges ACA, ACB, ADA, AEA, AFA, AGA, AGB, and
AHA. The time period for the clock pulse appears as AAA, being 2F.sub.L as
previously defined.
Yet another timer offering some improvement over the aforesaid circuit of
FIG. 3 appears in FIG. 5. Two particular merits for this new circuit
include:
a. independence from load current variation as an effect on +Vc value; and,
b. time increments in decimal value.
The circuit of FIG. 5 dispenses with the current transformer of FIG. 3 and
instead uses the novelty of a d.c. power supply for +Vc which is virtually
indedpendent of any reasonable change in load 2 value; the maximum value
being that set by the power handling capability of the power passing
semiconductors, e.g. thyristors 45, 70 and diode 71. The operation of the
d.c. power supply is fully published in U.S. Pat. No. 4,300,090 issued
Nov. 10, 1981, "Direct Current Power Supply" to which the artisian is
referred.
Circuit operation is initiated by a momentary connection, as by a push
switch or the like, between external control line L4 and the controlled
line L3. The resultant current flow to the load will flow through the
components of the d.c. power supply including thyristor 70 and diode 71
with the result that when input L2 is negative relative to common L1,
diode 71 will pass current; whilst in the opposite mode when input L2 is
positive relative to common L1, the thyristor 70 will INHIBIT current flow
until zener diode 72 conducts drawing current through resistor 73 and the
thyristor 70 gate.
The brief period during each half-cycle prior to the turn-on of the silicon
controlled rectifier 70 results in a recurring unipolarity pulse between
the thyristor anode and cathode which is coupled by a unilateral
conductive device, or diode 74, to an accumulator, e.g. capacitor 75. The
result is a d.c. value +Vc is developed across the capacitor 75 which
powers the circuit elements. What is important is that the value of the
unidirectional pulse is fully independent of the LOAD current when that
current is above a minimum value of but a few watts, due to the action of
the zener diode solely responding to the power input waveform voltage
magnitude component.
The increase in +Vc d.c. value, when first turned on, is delayed in
application to the inputs of NAND gate 87 and inverter 57 by the
integration effect of resistor 56 having to charge capacitor 55 first.
This results in a logic "1" or HIGH at the inverter 57 and gate 87 outputs
as coupled to the respective counter 90 and counter 85 reset R.sub.0
inputs.
This timely action results in the resetting of the counters to zero state.
The clock rate is provided from the connection 82 which contains a
fundamental pulsating d.c. component (due to the action of the aforesaid
thyristor 70) at the line source frequency F.sub.L ; e.g. 60 (50) hertz.
The resultant pulses couple through resistor 81 into two cascade inverters
80, 83 for waveshape enhancement prior to coupling to counter 85, say
C-MOS type CD-4040, which operates in the shown configuration as a
divide-by-3,600 function together with decode NAND gate 86 feeding back to
the reset R.sub.0 line through NAND gate 87. The result is a series of
one-minute ticks, or clock pulses, coupled to CK input 89 on counter 90.
While I describe 60 hertz operation, decoding instruction changes to
produce a divide-by-3,000 action in counter 85 will allow 50 hertz
operation; other combinations being equally obvious to the experienced
practitioner.
Counter 90 is exampled as the widely used C-MOS type CD-4017
counter-decoder. The counter, R.sub.0 input 58 having been reset, rests
with all outputs 1 through 9 at a logic LOW value. Output 0 is logic HIGH,
and therefore is invalid as a function. The nine outputs 1 through 9 are,
accordingly, coupled to a selector switch 91 (or else jumpers are used).
Line 0 is also shown connected: the result is either the mechanical
rotation stops on the switch prevent selection of position "0"; or else
this position serves as a timer over-ride function, which is to say that
the controlled load 2 is ON only for so long as the external closure
between line connections L3 and L4 exists, but no time delay function
ensues.
As long as the switch 91 rotor connection 92 is logic LOW, PNP transistor
95 is forward biased through resistor 93, causing substantial collector
current flow through resistor 46 and thus the gate of triac 45 including
gate shunt resistor 47. The result is the triac 45 is turned ON, thereby
serving the load 2. The OFF signal occurs when the time function
completes:
T.sub.t =(1/F.sub.L)(M.multidot.D.sub.n) seconds;
where:
M=effective division factor of counter 85; and,
D.sub.n =division factor of counter 90 output as selected by switch 91.
When the desired count is reached, the rotor 92 line goes to a logic HIGH
state: e.g., PNP transistor 95 is shut off. The controlled load 2 is
subsequently disconnected, current flow in line L3 ceases and the result
is current between terminals L2 and L3 ceases. The timer is thereby
disabled.
The hookup for a lamp load 2A having remote OFF action in conjunction with
the new timed switch appears in FIG. 6A. What is provided is:
1. The circuit is turned ON at the timed switch 1 by the action of
momentary switch 3 (FIG. 1); and,
2. The circuit may be turned OFF prematurely (i.e., before the time cycle
completes) by a separate momentary normally closed switch 100 usually
connected between the line L3 timer output and the load L5 line.
FIG. 6B depicts some variation, in that two or more switches 101, 102 are
shown, whereby any one switch may be momentarily opened, resulting in the
premature interruption of the circuit current flow.
The hookup for a lamp load 2A having remote ON action in conjunction with
the new timed switch appears in FIG. 7. What is provided is:
1. The circuit is turned ON at the timed switch 1 by the action of
momentary switch 3 (FIG. 1); and,
2. The circuit is also able to be turned ON at any one of several remote
locations by the momentary action of any remote normally open switch 105,
106.
The hookup for an arrangement providing for either remote ON or remote OFF
control by several remote switch locations appears in FIG. 8A. The ON
state is initiated by any one normally open momentary action switch 105A,
106A as explained for FIG. 7, whilst the OFF state is accomplished by any
one normally closed momentary action switch 101A, 102A as explained for
FIG. 6B.
The hookup variation depicted in FIG. 8B accordingly shows but one remote
switch position.
While I have described the invention in terms of a digitally programmed
timer: the essence of my invention, being that of a two terminal timer,
can be implemented with analog timing techniques. FIG. 11 gives
illustration of my teaching using an analog interval timer 65 as a timing
element having a continuous variable time adjustment 66. My preferred
embodiment also employs a digital timing delay function 60 for course
preset delay, bringing the analog delay into play for incremental
adjustment. The circuit depicted in FIG. 12, together with the circuit
described earlier for FIG. 5 best shows my teaching. Through connecting
the rotor 92 of switch 91 to the input 151 of NOR gate 155 instead of to
resistor 93, the analog delay will serve to complement the decimal-step
delays produced by the circuit of FIG. 5. The reset signal produced by
gate 57 couples 152 to NOR gate 156 serving to initialize the circuit upon
turn-on so the latch effected by cross coupled gates 155, 156 will be
reset with gate 156 output 157 logic LOW to the R.sub.0 input of timer 150
which is exampled as a C-MOS device, for this illustration an Intersil
type ICM-7555 or the like. When the digital timer logic HIGH state occurs
on input 151, the latch will be reset and timer 150 input R.sub.0 will go
logic HIGH, serving to enable the analog timer 150. At the same time the
sudden change to logic LOW at the output of gate 155 will produce a
differentiated trigger pulse for the V.sub.T input of the timer 150. The
analog timer will then progress through its pre-established time cycle
period as defined by the effective value of timing resistances 170, 171
together with capacitor 172 as coupled to the discharge (DIS) and
threshold (TH) inputs of the timer device in a manner well known in the
so-called "555" family of integrated circuit timers. The delay accordingly
becomes:
T.sub.AD =(R.sub.A +R.sub.Beff)C.sub.A seconds;
where:
R.sub.A =resistor 171 in megohms;
R.sub.Beff =effective value of potentiometer 170 in megohms; and,
C.sub.A =capacitor 172 in micorfarads;
which upon completion produces a logic LOW state at the output 161 as
coupled to NOR gate 160. The NOR gate 160 is satisfied with both inputs
LOW so as to produce a logic HIGH output on the line which couples to
resistor 93' and in turn connects 162 to transistor 95 in FIG. 5 thereby
serving to satisfy the circuit conditions for FIG. 5. With the circuit of
FIG. 5, one minute steps are produced by the selection established by
switch 91. Therefore if the analog timer 150 nominal component selections
allow for about a one minute analog delay, the result will be a nice
arrangement wherein the switch 91 selects the one minute steps whilst the
analog time adjustment 170 affords a goodly fill in of time increments
with nearly infinite resolution. The best practice of the combination is
to establish the R.sub.A, R.sub.B values to permit analog adjustment
between about one minute and two minutes: viz, a 2:1 range. Under this
condition the effective overal time delay sequence values become
equivalent to:
T.sub.BD =T.sub.t +T.sub.AT ;
or for the cited example:
T.sub.BD.sbsb.min =T.sub.t +60 seconds; and,
T.sub.BD.sbsb.max =T+120 seconds;
where:
T.sub.BD =effective overall time period of combined circuits of FIG. 5 and
FIG. 12; and,
T.sub.AT =analog timer delay value;
thus providing for the quasi-infinite setting of incremental time delays
for producing | | |
