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US3588891A - Self-monitoring field-contacts for automatic alarm systems - Google Patents

️Mon Jun 28 1971

United States Patent [72) Inventor Lester 11. Porter, Jr.

Dallas, Tex. [21] AppLNo. 711,360 [22] Filed Mar. 7, 1968 (45] Patented June 28, 1971 [73 Assignee Beta Corporation.

Dallas. 'l'ex.

[54] SELF-MONITORING FIELD-CONTACTS FOR AUTOMATIC ALARM SYSTEMS 4 Claims, 2 Drawing Figs.

[52] US. Cl 340/409, 320/1 [51] Int.

Cl G08b

29/00 [50] Field of Search 340/409, 213.1

[56.] References Cited UNITED STATES PATENTS 3,138,792 6/1964 Jenkins 340/409 3,351,934 11/1967 Vietz 340/409 3,430,231 2/1969 Weld 340/409 Primary ExaminerThomas B. l-labecker Attorneys-Oscar B. Brumback, Boyce C. Dent and Olin E.

Williams triggered by a capacitor charging circuit in response to either (a) the closing of a normally open field-contact because of a malfunction of the monitored equipment, or (b) the breakage (opening) or shorting out of the field-contact wires.

Nam/4L4 y- OPEN FIELD ca/vmc'r;

7 ANA/(M1614 me SELF -MONITORING FIELD-CONTACTS FOR AUTOMATIC ALARM SYSTEMS BACKGROUND OF THE INVENTION 1. Field of the Invention This invention relates generally to electrical communication: and more particularly to alarms or annunciators automatically responsive to a condition.

2. Description of the Prior Art Automatically responsive alarm or annunciator systems are used to provide a visual and/or audible indication of a malfunction in equipment being monitored. These systems can also be used to provide automatic shutdown of the monitored equipment if desired. An example of such an annunciator system is shown and described in copending application Ser. No. 430,577 entitled Improved Annunciator System" filed Feb. 5, I965 by Merle E. Martin now U.S. Pat. No. 3,480,938.

These annunciator systems work well to monitor equipment so long as the annunciator system itself is in good working order. A problem associated with such systems is that the wires from the field-contacts to the alarm point sometimes become broken or shorted out. In this event, even though the field-contact may be closed (or opened, as the case may be) by a malfunction, no alarm will be indicated. The monitored equipment can be extensively damaged before the malfunction is detected by the annunciator.

Accordingly, an object of this invention is to provide an alarm in the event that the field-contact wires become broken or shorted.

SUMMARY OF THE INVENTION These and other objects and novel features are accomplished by providing a capacitor charging circuit for triggering a conventional unipolarity current operated switching circuit, of which the latter circuit provides a signal to operate a visual and/or audible alarm. The capacitor charging circuit is charged by either (a) operation of field-contacts resulting from a malfunction or (b) the breakage or shorting out of the field-contact wires. The charging circuit includes a capacitor for triggering the switching circuit at the voltage level required for its operation. The charging circuit also includes a diode in parallel with a normally open field-contact (or in series with a normally closed field-contact) to block the polarity of current which would trigger the switching circuit but pass current of opposite polarity. Other diodes and resistors are used to direct only positive-polarity current (assuming the switching circuit is triggered by positive polarity voltage) to the capacitor in the event of wire breakage or shorting.

The above and further objects and novel features of the invention will appear more fully from the following detailed description when the same is read in connection with the accompanying drawing. It is to be expressly understood, however, that the drawing is not intended as a definition of the invention but is for the purpose of illustration only.

BRIEF DESCRIPTION OF THE DRAWING In the drawing wherein like parts are marked alike:

FIG. I is a schematic ,diagram illustrating an embodiment of the present invention in connection with an annunciator circuit wherein a normally open field-contact arrangement is used; and

FIG. 2 is a schematic diagram illustrating a circuit for adapting the invention illustrated in FIG. 1 for use with a normally closed field-contact arrangement.

DESCRIPTION OF THE PREFERRED CONSTRUCTION Referring now to FIG. I of the drawings, a conventional altemating current powered

transfonner

20 supplies AC current through line to point 1 of field-

contact

22. AC current is supplied from line 12 through a

charging network

26 to

input point

5 of a conventional switching circuit 24 (shown within the dotted lines).

Switching circuit

24 is illustrated herein as being a Schmitt trigger although it can be an SCR (silicon controlled rectifier) or any other type of switch operable at a selected voltage level of one polarity (positive herein).

Switching circuit

24 is connected at

points

9 and 10 to

power return line

14 which is center-tapped into the secondary of

transformer

20 in a conventional manner.

The charging network 26 (shown within the dotted lines) includes a

capacitor

40 connected, through

resistor

42 and

diode

44, by line 11 to

point

2 of field-

contact

22 and connected by

line

13 to

point

3 of power return line I4. Line 12 is connected to point 4 of line II and includes

resistor

46 in series with a

diode

48.

A voltage divider network for

charging capacitor

40, when the capacitor is charged along the line II voltage path, is provided by

resistor

42 and a resistor R4 in parallel with capacitor 4 Another voltage divider network for

charging capacitor

40, i

when the capacitor is charged along the line I5 voltage path, is provided by

resistor

52 in series with the

capacitor

40 and

resistor

50 in parallel with the capacitor.

Diode

54 and

resistor

52 are not essential for effective operation of the circuit but they do provide closer control of the charging rate of

capacitor

40 by forming a parallel path with

diode

48,

diode

44 and

resistor

42.

Connected between

point

5 and

power return line

14 is a conventional Schmitt trigger circuit which provides a signal to power return line I4 when it is triggered by

capacitor

40 when the capacitor reaches the operating voltage level of the trigger circuit. Briefly, the Schmitt trigger 24 is a regenerative bistable circuit whose state depends on the amplitude of the input voltage. Assuming that

transistor

56 is nonconducting, the base of

transistor

58 is biased by the voltage divider consisting of

resistors

60, 62, and 64. The emitters of

transistors

56 and 58 are of equal voltage due to the forward bias voltage required by

transistor

58. When the input voltage reaches the operating level,

transistor

56 begins to conduct and regeneratively turns off

transistor

58. Transistor Q2 will again conduct when the input voltage is lowered. The input voltage is supplied by the charging of

capacitor

40 when either contacts 22 close in response to a malfunction or if the power lines to the field-

contact

22 become broken or shorted.

Also connected between power supply line 12 and

power return line

14 by way of

lines

19 and 21 is an

annunciator alarm circuit

30. Preferably the annunciator is of the type described in copending application Ser. No. 430,577; however, any of the conventional annunciator alarm systems which cause a light to glow, a horn to sound, a bell to ring or any other conventional alarm indication can, of course, be used.

OPERATION In the normal operation ofa known annunciator, the annunciator is connected between the power and return lines as, for example,

annunciator

30 is connected by

lines

19 and 21 across power lines l2 and I4. Upon a malfunctioning of the equipment being monitored, normally

open contacts

22 will close, and

annunciator

30 will be activated to indicate that malfunctioning has occurred. So long as the lines to the fieldcontacts are in proper working order,

annunciator

30 monitors the operation of the equipment being monitored. However, should the lines to the field-contacts become broken or shorted due to vibration, accident, and the like, the equipment monitored by

contacts

22 and

annunciator

30 may malfunction and yet

annunciator

30 would not indicate the malfunction. This could result in extensive damage to the monitored equipment.

The possibility of the annunciator not indicating a malfunction of the system is remedied in accordance with this invention. Referring back to FIG. I, alternating current is supplied to normally open field-

contact

22 from

transformer

20.

Diode

66 blocks the polarity of current which would trigger switching

circuit

24 through charging

circuit

26, but will pass the opposite polarity. When the

field contact

22 closes, as from a malfunction,

capacitor

40 will be charged through

diode

44 and

resistor

42 when the cycle of alternating current in line is positive with respect to

line

14. When capacitor 40 charges to .the trigger voltage level of switching

circuit

24. the latter will activate the

alarm

30. When the cycle of alternating current in line 12 is positive with respect to

line

14. positive voltage is applied to

resistor

46.

Line

10 is then negative with respect to both line 12 and

line

14. Current will flow from line 12 through

resistor

46,

diode

48, and

diode

66 to

line

10. The current flow will hold

line

15 negative with respect to

line

14. This will produce no switching action in

switch

24, but

ifline

10 or line ll should be broken (opened), the current flow from line 12 to

line

10 would cease and

line

15 would then become positive with respect,to line 14 when line 12 is positive with respect to

line

14.

Capacitor

40 will then charge to the trigger voltage level through

diode

54 and

resistor

50 and through

di'ode

44 and

resistor

42, thereby triggering switching

circuit

24 for activating

alarm

30. If

line

10 and line ll should short together,

capacitor

40 will charge to trigger voltage level through

diode

44 and

resistor

42 since

diode

48 blocks current from flowing through

diode

54 and

resistor

50.

During normal operation, when there are no fault signals generated by closing of

contacts

22 or opening or shorting of the power supply lines to

contacts

22, then capacitor 40 will discharge through

resistor

50 before the operating level of

switch

24 is reached.

The invention will work equally well with normally closed field-contacts. in the embodiment illustrated in FIG. 2, diode 68 (corresponding to

diode

66 of FIG. I) is placed in series with a normally closed field-

contact

28 connected to line 10 between the field-contact and line 31. Line 31 corresponds to line 11 of the previously described charging circuit.

In operation,

diode

68 will block current through field-

contact

28 when

line

10 is positive with respect to line 12 and

line

14, but current will flow when line I0 is negative with respect to line 12 thereby holding

line

15 negative with respect to

line

14. When the field-

contact

28 opens, as from a malfunction,

capacitor

40 will charge to a positive voltage through

diode

54 and resistor R3. When

capacitor

40 reaches the trigger voltage of switching

circuit

24, the latter will activate the

alarm

30.

-Should

line

10 and line 31 short together,

capacitor

40 will charge, when

line

10 is positive, through

diode

44 and resistor R1 and subsequently trigger switching

circuit

24.

SUMMARY The foregoing describes a switching circuit that triggers on a positive current. For negative operation, the diodes would be installed in the reverse direction. In each case the principle of operation would remain the same. v

Thus, it can be seen that the charging circuit can be used to monitor either normally open or normally closed field-con tacts. It will trigger any switching circuit triggered by unipolarity voltage. whether positive or negative. In the event of a break or short in the wires leading to or from the fieldcontacts, the switching circuit will activate the annunciator alarm. Accordingly, the circuit provides an advantageous safety feature to prevent damage to monitored equipment due to defective wiring to the field-contacts.

Having thus described the invention in its best embodiment and mode of operation, that which is desired to be claimed by Letters Patent is: 1

I claim:

I. A field-contact circuit for providing an alarm indication of a malfunction in an annunciator system, comprising:

a first current path connecting a first current source through a field-contact and a charging network means to an alarm means in said annunciator system;

a second current path connecting a second current source through said charging network means to said alarm means; I said charging network means connected to said first and second current paths and being selectively responsive to: said field-contact operating in response to a fault in equipinent monitored by said annunciator system, and to a defect in said first current path,

said charging network means including a capacitance chargeable to an operating voltage level from current in said first current path during operation of said field-contact and chargeable from current in said second current path in response to a defect in said first current path;

a trigger circuit means connected between said field-contact and said alarm means operative in response to said operating voltage level of said capacitance for operating said alarm means;

first current-blocking means connected in parallel with said field-contact for blocking current of one polarity tending to flow through said first current path and for passing current of the opposite polarity through said first current path;

second current-blocking means connected in said second current path for blocking current of one polarity tending to flow through said second current path and for passing current of the opposite polarity through said second current path; and v a first resistance in said first current path and a second resistance in said second current path forming a voltage divider with a third resistance connected in both said first and second current paths across said capacitance for charging said capacitance to said operating voltage level,

whereby operation of i said field-contact charges said capacitance to said operating voltage level for operating said trigger circuit means. I

2. The charging circuit of claim 1 wherein said trigger circuit means is a Schmitt trigger.

3. The charging circuit ofclaim 1 wherein said field-contact is normally open.

4. The charging circuit ofclaim 1 wherein said field-contact is normally closed and said first current-blocking means is in series with said normally closed field-contact in said first current path.