US3104384A

US3104384A - Alarm system

Info

Publication number: US3104384A
Application number: US818072A
Authority: US
Inventors: Matthew W Slate
Original assignee: Thompson Ramo Wooldridge Inc
Current assignee: Northrop Grumman Space and Mission Systems Corp
Priority date: 1959-06-04
Filing date: 1959-06-04
Publication date: 1963-09-17
Anticipated expiration: 1980-09-17

Description

M- W. SLATE ALARM SYSTEM Sept. 17, 1963 2 Sheets-Sheet 1 Filed June 4, 1959 INVENTOR.

MATTHEW W. SLATE ATTOR N EYS M. w. SLATE Sept. 17, 1963 ALARM SYSTEM 2 Sheets-Sheet 2.

Filed June 4;, 1959 IIB FIG. 4.

FIG. 5.

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United States Patent 3,104,384 ALARM SYSTEM Matthew W. State, Audubon, Ni, assigner, by mesne assignments, to Thompson Raine Wooldridge inc, Euclid, Gino, a corporation of Ohio Fiied .iune 4, 1959, Ser. No. $18,4i72 6 Claims. (6i. 34tl-215 This invention relates to an alarm system and is particularly adapted to fire alarms though it may be used in other systems.

One of the objects of the present invention is to provide an alarm system of the type involving the transmission of electrical signals without, however, involving the necessity for reliance on an electrical power supply provided by the electrical mains or by batteries. In accordance with the invention, one or more transmitters are arranged to produce current pulses which serve to operate one or more receivers which in turn may provide audible signals or which may trigger fire extinguishing means, or the like. Provisions are made for resetting both the transmitting and receiving means. In particular, high reliability is attained.

The general objects of the invention as well as subsidiary objects particularly relating to details of construction and operation will become apparent from the following description, read in conjunction with the accompanying drawings in which:

FIGURE 1 is a vertical section taken through a preferred form of receiver responsive to signals emitted from one or more transmitters;

FIGURE 2 is a plan view of the same;

FIGURE 3 is an elevation of the same looking toward the right in FIGURE 1;

FIGURE 4 is an elevation of a transmitter;

FIGURE 5 is a side elevation of the same;

FIGURE 6 is a plan view of the same; and

FIGURE 7 is a wiring diagram showing the interconnections between a plurality of transmitters and a plurality of receivers.

Reference will be first made to FIGURES 1, 2, and 3 showing a receiver. A frame 2. which may be mounted at any convenient location includes a bracket 4 which supports a magnet assembly consisting of a frame 6, a disc-shaped permanent magnet 8, a washer lit, and a core 12 secured together by a clamping screw 14. The elements 6, lit, and 12 may be of low retentivity steel. Permanent magnetism is provided by the permanent disc magnet 8 of a ceramic material such as one of the barium ferrites, or such as is commercially available under the trademarks Indox 1, Cromag, or the like having a high coercive force. Permanent magnets of this type have special characteristics of which those utilized here are the following:

The permanent magnetism is not destroyed even if the magnet is subjected to an opposing field which serves not only to reduce the net magnetic field to Zero but which may provide a considerable reversal of field. When such a magnetizing field is removed, the permanent magnet returns to and maintains its original strength. Utilized here, as will become apparent, is the neutralizing of the permanent magnet field by an electromagnetic field to reduce the net magnetic field to zero.

Another property of ceramic magnets of this type is that of retention of strong magnetism when the magnetic field is across a relatively short dimension such as between the faces of the disc 8. In other words, one face of the disc constitutes the north pole of the magnet and the other face the south pole. As will be evident, therefore, from FIGURE 1, the magnet disc 8 is in magnetic series with the other portions of the core structure comprising the

elements

6, 10 and 12.

ants-at A magnet winding 16 is supported by a spool surrounding the central core element 12.

An armature 18 of steel is pivoted in a slot 20 provided in the element 6 and is urged lightly toward magnetic circuit closing position by a spring 24. A tail portion 22 of the armature extends downwardly as shown.

The frame 2 mounts a bonnet 26 which is provided with a lower opening 28 threaded at 36 to receive the cap 32 of a cartridge 36, a gasket 34 being provided for gas tightness. The cartridge 36 contains a fluid under pressure such as carbon dioxide, Freon or the like, capable of yielding a substantial volume of gas upon release. A sealing member 38 normally closes the cartridge being held in the cap by the threaded annulus 40. A plunger 42 is mounted to slide in a bore in the bonnet 26, sealing being provided by the O-

rings

44 and 46. The lower end of the plunger 42 is cut off to provide a sharp edge at 48 suitable for penetration of the sealing member 38. Openings 50* are provided in the lower end of the plunger to permit free escape of gas, if the penetration occurs, and to the upper part of the opening 28 and then to an outlet at 52 which may be connected by tubing an element to be actuated to sound an alarm or effect other operation. For example, the connection may lead to a horn, to a bell actuator, to a fire door release, or such other device as may be desirably used as the response-actuated means.

A spring 54 urges the plunger upwardly but is opposed by a strong spring 56 acting on the stop collar 58 carried by the upper end of the plunger. A restoring lever 64 is pivoted at 62 to the frame and is pivoted to the plunger 42 by a pin 64 providing a loose connection. Pivoted to the inner end of lever 6i) by pin 66 is a link 63 in turn pivoted by pin 7t) to a second link 72 which has its lower end pivoted to the frame by pin 74. A link 76 loosely mounted on pin 70 is urged upwardly by a tension spring $0 connected between it and the pin 66 to cause it to abut the edge '78 at the lower end of the link 68.

At this point it would be convenient to describe the operation of the receiver. In its set condition which is illustrated in FIGURE 1, the toggle comprising the

links

68 and 72 would collapse under the action of the strong spring 56 and the plunger 42 would be forced downwardly, if it were not for the abutment of the right-hand end of link 76 with the tail portion 22 of the armature 18 which is retained in the position illustrated by the permanent magnetic field provided by the magnet 8, in the absence of current flowing through the wiring 16. Tripping is effected by producing through the wiring 16 a momentary pulse sufficient to provide an electromagnetic field opposing that of the permanent magnet 3 to produce momentarily a zero net magnetic field and, accordingly, release of the armature 18. It has been found that the pulse duration serving to effect release of the armature may be very short. Once the field is reduced to or near zero and the armature moves to produce only a very small air gap between it and the core element 12, even though the pulse then terminates, the effective force to return the armature is very much less than the force which holds it in contact with the core.

Assuming the existence of such a momentary releasing pulse, the force exerted by the link 76 under the action of the spring 56 is so much greater than the force exerted by the light spring 24 and any magnetic force which may be produced by the pulse in reversing the previous magnetic field, that the armature will be swung counterclockwise with the collapse of the toggle and forcing of the link 76 by the cam action of the sloping armature below the lower end of the armature. The armature is then free to return under the action of spring 24 and is again clamped by the action of the magnetic field provided by magnet 8. The link 76 then lies below the tall 22 of the armature being held yieldingly upwardly and against it by the spring '80.

With collapse of the toggle, the spring 56 overcomes the action of the relatively light spring 54 and drives the sharp lower edge of the plunger through the member '38 thereby releasing gas from the cartridge 36 to cifect the desired operation. While gas pressure is exerted on the.

V abutting position under the action of spring 8% It will be evident from the foregoing description of operation, that-the receiver may be operated by a pulse of current in the proper direction through the wiring 16. This pulse may originate in any desired fashion, lfrom momentary closure of a direct current circuit or by momentary closure of an alternating current circuit, since it is found that release will be effected so quickly that it will occur during the half wave of a 60 cycle supply which is in the proper direction to oppose and neutralize the field of the permanent magnet 8. While, therefore, the receiver is of quite general utility even when conventional direct or alternating power supplies are available to produce releasing pulses, the arrangement is of particular a value when an electrical pulse of even very short duration may be supplied from a transmitting device which up erates independently of a conventional current source. Such operation is particularly desirable torsafety purposes, since a conventional source may fail, by neglect of batteries, or by the opening of an alternating supply circuit by some phenomenon such as a fire, which should be responsible for the tripping of the receiver.

FIGURES 4, 5 and 6 show a transmitter which is particularly desirable for use for the actuation of a receiver such, as that just described. As illustrated, the transmitter is responsive to heat through the use of a fusible link, but it will become evident that it may be otherwise tripped, such as by a device in the nature of a burglar alarm, a detector of radiation, or the like.

A frame 82 supports a magnetic assembly generally similar to that previously discussed and comprising a bracket 84, a'perrnanent cylindrical ceramic magnet 86 of the type referred to above, a washer 88 and a core 90, held in assembled relationship. A winding 92 surrounds the core 90. An armature 9d pivoted to the upper end of bracket 84 is urged toward closed position against the core Ml by the light spring 96. 1

The tail portion of the armature 94 carries a pair of insulated contact springs 98 and 100 which are normally sprung so as to be separated as illustrated in these figures. A yoke 162 is urged downwardly by a strong spring W6, connected between it and the frame. Downward movement is resisted by connections to the upper end of the yoke consisting of the link 108- which is hooked at 112 through a lower eye of a tus-ible link 1-14, the upper eye of which is held by a pin 1116 passing through openings in the frame and provided with a loop 118 by which it may be withdrawn and reinserted. An insulating button 110 provided on the lower end of link MP8 overlies the upper spring contact MN).

The electrical connections between a plurality of transmitters and a plurality of receivers are shown in FIGURE 7 in which the transmitter coils are indicated at 92 and the receiver coils are indicated at 16. As will be seen from FIGURE 7 the receiver coils are connected in iparallel and this is also trueof the transmitter coils in which, however, the coils 92 are normally disconnected from the circuit by the normally opened contacts 98 and 1%. The circuit of FIGURE 7 shows how a number of receivers may be actuated by the tripping by any one of a number of transmitters; but it will be evident that a single set of one transmitter and one receiver may be associated. When a plurality of receivers are used, the windings must, of course, be designed so that the transmitted signals are ampleto effect operations of all the receivers.

The operation of a transmitter is as follows:

Upon failure of the fusible link 114, or by some other action which will release the link 168, as, for example, by the pulling out of a pin such as 118 by the opening of a door (in a burglary protective system), or thelike,'the spring 106 will snap downwardly the yoke W2, causing the button 110 "first to produce engagement by the contacts 98 and 10b and secondly to rock the armature 94 away from the core '90. The rapid establishment of an air gap in the magnetic circuit and consequent collapses of the magnetic field will produce a pulse of current serving to energize momentarily the one or more windings 16 as previously described, thereby effecting operation of the one 'or more receivers. By reason of the fact that only the

contacts

98 and 100* of the transmitter which is tripped will be closed, the other transmitter coils, if there be more than one transmitter, will be cut out of the circuit and, accordingly, will not shunt the output.

The normal condition of a transmitter may be restored by replacing the fusible link, the link ltld being raised in this operation or by some other restoring operation against the action of spring 106. In this restoring operation, it' may be noted, even if the receivers have been reset, the polarity "of the pulse emitted from the coil 92 by the closure of its magnetic circuit will be of opposite polarity from that capable of efiecting tripping of receivers. It will be obvious that proper polarity conditions must be observed so that upon tripping of any trinsr'nitter the connected receiver or receivers will be tripped by the current pulse neutralization of their permanent magnetic fields.

It will be evident that various changes in details of construction and operation may be made without departure from the invention.

What is claimed is:

l. The combination comprising a permanently magneti'zed magnetic'core, a movable armature normally associated with said core in a position substantially closing the magnetic circuit of said core and held thereby in said position, signalling means connected to said armature, said signalling means being operable by movement of the armature from said position in a direction to open said magnetic circuit, means biasing said armature in opposition to the holding action thereon of said magnetic core, a winding associated with said core and adapted to be energized to produce a field neutralizing the permanent field'thereof, thereby to effect release of the armature and operation of said signalling means, a second permanently magnetized magnetic core, a movable armature normally associated with said second core in a position substantially closing the magnetic circuit thereof, a winding on said second core, means operable to move the second-; mentioned armature to a position to open the magnetic circuit of said second core, thereby to generate an electrical pulse in the second-mentioned winding, and a circuit for'transmitting said pulse to the first-mentioned winding to effect the aforesaid release of the firstmentioned armature.

2. Means for operating a signalling means comprising 7 a container of compressed gas adapted to be punctured for release of the 'gas, a puncturing member, means mounting said member forrnovement into engagement with a portion of said container to be punctured, a strong spring biasing said member toward said container portion, a permanently magnetized core, .a movable armature normally associated with said core in a position substantially closing the magnetic circuit of said core and held thereby in said position, a toggle linkage. connected to said member adapted to be held in a normal position restricting movement of said member under the influence of said spring and to be released to permit such movement, said toggle linkage being held in said normal position by said armature when the same is held in said position substantially closing the magnetic circuit of the core, and means for releasing said armature from the core, thereby to release said toggle linkage, comprising a coil associated with the core and means producing a current pulse through said coil to produce a field neutralizing the permanent field of the core.

3. Means for operating a signalling means as defined in claim 2 comprising a permanently magnetized second core, a second movable armature normally associated with said second core in a position substantially closing the magnetic circuit thereof, a winding on said second core coupled to a transmitting circuit, and means operable to move said second armature to a position to open said magnetic circuit, thereby to generate the electric pulse and efiect operation of said signalling means, said transmitting circuit transmitting said pulse to said coil.

4. The combination comprising a permanently magnetized magnetic core, a movable armature normally associated with said core in a position substantially closing the magnetic circuit of said core and held thereby in said position, signalling means connected to said armature, said signalling means being operable by movement of the armature (from said position in a direction to open said magnetic circuit, means biasing said armature in opposition to the holding raction thereon of said magnetic core, a winding associated with said core and adapted to be energized to produce a field neutralizing the permanent field thereof, thereby to effect release of the armature and operation of said signalling means, a second permanently magnetized magnetic core, a movable armature normally associated with said second core in a position substantially closing the magnetic circuit thereof, a winding on said second core, a normally open switch, means providing a series circuit including said switch and the windings on the first-mentioned and second cores, and means operable substantially concurrently to close said switch and move the second-mentioned armature to a position to open the magnetic circuit of said second core, thereby to generate an electrical pulse in the second-mentioned winding, said pulse being transmitted by said circuit to the first-mentioned winding to elfect the aforesaid release of the first-mentioned armature.

5. The combination comprising a plurality of first permanently magnetized cores, each of said first cores having a winding associated therewith and adapted to be energized to produce a field neutralizing the permanent field thereof, said windings being connected in a parallel circuit, a plurality of second permanently magnetized cores, each of said second cores being provided with a winding halving associated in series therewith a normally open switch, each second-mentioned winding and its associated switch being connected in a parallel circuit with the other said second mentioned windings and their associatcd switches, a circuit connecting the first and secondmentioned parallel circuits for the transmission of electrical pulses from the second to the first-mentioned windings, a plurality of movable armatures each normally associated with one of said first cores in a position substantially closing the magnetic circuit of the core and held thereby in said position, a plurality of signalling means each connected to one of said armatures, each of said signalling means being operable by movement of its associated armature in opposition to the holding action thereon of its magnetic core, the said winding of each of said first cores being adapted to be energized to produce a field neutralizing the permanent field thereof, thereby to effect release of its associated armature and operation thereby of signalling means, a plurality of second mo-v able armatures each associated with one of said second cores in .a position substantially closing the magnetic circuit thereof, and means for producing an electrical pulse from any of said second-mentioned windings comprising means operable substantially concurrently to close the said switch in series therewith and to move its associated armature to open the magnetic circuit of the core, said pulse being transmitted to the first-mentioned windings to effect operation of said signalling means.

6. The combination comprising a permanently magnetized ceramic core, a mova le armat re normally associated with said core in a position substantially closing the magnetic circuit of said core and held thereby in said position, signalling means connected to said armature, said signalling means being operable by movement of the armature from said position in a direction to open said magnetic circuit, means biasing said armature in opposition to the holding action thereon of said ceramic core, a winding associated with said core and adapted to be energized to produce a field neutralizing the permanent field thereof, thereby to eifect release of the armature and operation of said signalling means, a second permanently magnetized ceramic core, a movable armature normally associated with said second core in a position substan tially closing the magnetic circuit thereof, a winding on said second core, means operable to move the secondmentioncd armature to a position to open the magnetic circuit of said second core, thereby to generate an electrical pulse in the second-mentioned winding, and a circuit for transmitting said pulse to the first-mentioned winding to effect the aforesaid release of the first-mentioned armature.

References Cited in the file of this patent UNITED STATES PATENTS 908,063 Aylward Dec. 29, 1908 1,300,922 Brown Apr. 15, 1919 1,613,802 Mollard Jan. 11, 1927 1,976,347 Johnson Oct. 9, 1934 2,191,825 Stevens Feb. 27, 1940 2,452,034 Cambell Oct. 26, 1948 2,506,983 Williams May 9, 1950 2,727,159 Sunderlin Dec. 13, 1955 2,814,795 Spooner Nov. 26, 1957 2,840,033 Nitohman June 24, 1958 2,845,614 Bell July 29, 1958 2,882,853 Reeves Apr. 21, 1959 2,915,681 Troy Dec. 1, 1959 2,916,323 Molyneaux Dec. 8, 1959 2,919,323 Drescher Dec. 29, 1959 2,919,324 Schuessler Dec. 29, 1959 2,923,841 Graif-Baker 2 Feb. 2, 1960

Claims

1. THE COMBINATION COMPRISING A PERMANENTLY MAGNETIZED MAGNETIC CORE, A MOVABLE ARMATURE NORMALLY ASSOCIATED WITH SAID CORE IN A POSITION SUBSTANTIALLY CLOSING THE MAGNETIC CIRCUIT OF SAID CORE AND HELD THEREBY IN SAID POSITION, SIGNALLING MEANS CONNECTED TO SAID ARMATURE, SAID SIGNALLING MEANS BEING OPERABLE BY MOVEMENT OF THE ARMATURE FROM SAID POSITION IN A DIRECTION TO OPEN SAID MAGNETIC CIRCUIT, MEANS BIASING SAID ARMATURE IN OPPOSITION TO THE HOLDING ACTION THEREON OF SAID MAGNETIC CORE, A WINDING ASSOCIATED WITH SAID CORE AND ADAPTED TO BE ENERGIZED TO PRODUCE A FIELD NEUTRALIZING THE PERMANENT FIELD THEREOF, THEREBY TO EFFECT RELEASE OF THE ARMATURE AND OPERATION OF SAID SIGNALLING MEANS, A SECOND PERMANENTLY MAGNETIZED MAGNETIC CORE, A MOVABLE ARMATURE NORMALLY ASSOCIATED WITH SAID SECOND CORE IN A POSITION SUBSTAN-