US3325799A - Mattress alarm - Google Patents

Description

June 13, 1967 R FARR|$ 3,325,799

MATTRESS ALARM Filed June 13, 1964 ROBERT L. FARR/S INVENTOR.

BY W

ATTORNEY United States Patent 3,325,799 MATTRES ALARM Robert L. Farris, Fort Worth, Tern, msignor of onediaif to Edwin Greines Cohen, Fort Worth, Terr. Filed July 13, W64, Ser. No. 382,251 3 Claims. (Ci. 340-279) This invention relates to alarm mechanisms and has reference to a mattress alarm for hospitals or the like.

In nurseries, rest homes and hospitals patients or occupants not under individual surveillance or care are subject to the hazard of drug reactions or side effects, and can lapse into coma and may expire without detection for Want of the ability to attract attention to their calamitons circumstances. Indeed, if a patient stops breathing and approaches death, the possibility of discovery in time for life-saving emergency treatment is quite remote in the absence of a special nurse or other attendant who might render or seek immediate aid.

In a normal respiration cycle a patient imports reactive forces to the mattress upon which he lies, and such forces, if kept under constant surveillance could be used as a clear indication of continuing life processes. Conversely, any alarm or indication brought about by the absence of such motion upon a mattress would indicate that the patient has discontinued processes necessary for continuation of life, or has left the bed; either even should be called to the immediate attention of attendants on duty since the latter could mean that the patient has fallen from the bed and may be grieviously injured.

It is the absence, rather than the presence, of reactive forces upon a hospital mattress which indicates a cause for alarm. It is the abnormal, rather than the normal, circumstance which gives rise to the need for continuous rather than periodic surveillance. If a nurses attention can be called immediately to the abnormal status of a given patient, then the routine burden of maintaining periodic surveillance for a great number of patients can be greatly reduced and the probability of timely discovery of impairment or interruption of necessary life processes can be greatly enhanced.

Accordingly, an object of the present invention is to provide an alarm responsive to reactive forces upon a mattress.

Another object of the invention, an alarm which is operative upon the absence of, rather than the presence of, reactive forces upon a mattress.

A further object of the invention is to provide an alarm system capable of indicating the discontinuance of respiration of a patient, but which has no part of the alarm system actually attached to the body of the patient.

An important object of the invention is to provide an alarm adaptable to detect reactive forces upon a mattress as may be caused by the breathing of a patient without detecting lesser motions such as breeze ripples upon bed covers which might falsely indicate a situation of well being.

A particular obiect of the invention is to provide a hospital alarm capable of the detection of the absence of reactive forces upon a mattress corresponding in time intervals to normal respiration cycles.

A further object of the invention is to provide a hospital alarm which may continue to operate for an extended period of time in the event of a power failure.

An additional object of the invention is to provide a hospital alarm system which may be used simultaneously for a number of patients, indicating only abnormal circumstances, if any, of one or more of those patients.

These and other objects will become apparent from the following description and the accompanying drawing, wherein:

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FIGURE 1 is a perspective view of a mattress having strain gauges and straps attached thereto in accordance with the present invention.

FIGURE 2 is a schematic diagram shown partially in block form of an electrical circuit of the present invention.

FIGURE 3 is a partially fragmentary perspective view of an alternate form of the invention.

FIGURE 4- is an enlarged front elevational view of a shutter illustrated as a component in FIGURE 3.

FIGURE 5 is a partially sectional side elevational view of the alternate form of the invention illustrated in FIG- URE 3 and is shown with ancillary electrical components in schematic form.

In the drawing, amattress 10, including the usual upper andlower bindings 11 and 12, in centrally and longitudinally encircled by alongitudinal strap 13 connected at its opposite ends to corresponding ends of a verticallystrain gauge 14 positioned at the foot of the mattress.Transverse straps 15 and 16 are spaced from one another and transversely encircle themattress 10 and are respectively connected at their opposite ends to corresponding ends of vertically disposedstrain gauges 17 and 18 positioned at one side of the mattress. Acircumferential strap 19 encircles themattress 10 between thebindings 11 and 12 thereof and is connected at its opposite ends to corresponding ends of a horizontally disposed strain gauge 24), also positioned at one side of the mattress. Thestraps 13, 15, 16 and 19 are tightly fitted to the mattress and hold the same in compression so that the bulk of the matress tends to extend the straps and hold thestrain gauges 14, 17, 18 and 20 in a partially extended or stretched condition. Other straps and strain gauges (not shown) may be placed about the mattress at various positions and orientations with the strain gauges located at the sides or lower surface of the mattress.

For purposes of the present invention, a strain gauge may be defined as an electrical device having a resistance or output which varies in accordance with changes in applied extending or compressing forces. A particular construction for a strain gauge to be located Within a mattress is described herein in connection with an alternate form of the invention, but it is to be understood that a variety of strain gauges including simple carbon compression devices as are Well known in the art may be used with the present invention.

Electrically, each strain gauge is part of a separate circuit adapted to give an alarm in the absence of a change of physical forces upon at least one strain gauge secured to a mattress. With particular reference to FIGURE 2,strain gauges 14 and 2 3 have been arbitrarily selected for purposes of illustration and are shown as variable resistances which are each connected at one end through acable 21 to the negative terminal of thebattery 22. Preferably, thebattery 22 is a storage cell provided with a trickle charger (not shown) connected to a conventional AC outlet. Thestrain gauges 14 and 20 are respectively connected at their other ends tovariable resistors 23 and 24 which are, in turn, connected to the positive terminal end of thebattery 22 by acommon conductor 25. Hence, onestrain gauge 14 and itsvariable resistor 23 are connected in parallel with theother strain gauge 20 and itsvariable resistor 24 with respect to the terminals of thebattery 22. Each strain gauge attached to, or constructed Within a mattress is wired in series with a Variable resistor and in parallel with all other paired strain gauges and variable resistors of that mattress.

Considering now only onestrain gauge 14, theinput line 26 of aDC amplifier 27 is wired to the electrical junction of that strain gauge and itscorresponding variable resistor 23. The output of the DC amplifier is electrically connected to a diode 28 which is, in turn, connected to the input of a pulse shaper 29 which may be any square wave generating device having a positive output and an input responsive to positive pulses of extremely low frequency. The output of the pulse shaper 29 is fed to the input of amonostable multivibrator 30 which is wellknown in the art and often termed a one-shot. Theoutput 31 of themonostable multivibrator 30 is electrically connected to the positive terminal of thebattery 22 through aresistor 32, and one terminal of adiode 33 is also connected to theoutput line 31 of themonostable multivibrator 30 and the other terminal of the diode is connected to the input of an amplifier (Class A) 34. The output of theClass A amplifier 34 is connected to one terminal of the coil of a normally closed double pole single throw relay 35; the other terminal of the coil of the relay 35 is connected to the positive terminal of thebattery 22. Acondenser 36 has one of its terminals wired to the output of theClass A amplifier 34 and its other terminal electrically connected to the terminal of thebattery 22 through avariable resistor 37. A first armature 38 of the normally closed double pole single throw relay 35 is electrically connected to one terminal of an AC power source (not shown) and the contact point 39 of the first armature 38 is connected to one electrical terminal of a light bulb 40 or to any other visual or audible alarm device or signal. The other terminal of the light bulb 40 is connected to one end of the coil of a normally closed single polesingle throw relay 41, whereas the other end of the coil of the single pole single throw relay is connected to the other terminal of the previously described AC power source. The other armature 43 of the double pole single throw relay 35 is connected to an auxilliary battery (not shown) which may be provided with a trickle charger. Thecontact point 44 of the second armature 43 of the double pole single throw relay 35 is electrically connected to thearmature 45 of the single polesingle throw relay 41. The contact point of the single polesingle throw relay 41 is wired to anauxilliary alarm device 47 which is, in turn, wired to theother terminal 48 of the auxilliary battery previously described. Theauxiliary alarm 47 may be any visual or audible alarm or signaling device or may be several such devices in combination and preferably includes an electrically triggered but spring wound bell-type alarm.

In operation, motion (including breathing) of a person upon amattress 10 causes changes in the tension of thelongitudinal strap 13; these changes are imparted to the opposite ends of thestrain gauge 14 as changes in tension which alter the electrical resistance of the strain gauge. Thevariable resistance 23 regulates the current which flows through the strain gauge within its range of operating resistances and can be adjusted to control the detection sensitivity of the invention. Any change in the resistance of thestrain gauge 14 results in a change in theinput line 26 of theDC amplifier 27, but only the positive going portions of change cycles appearing at the output of the DC amplifier are passed by the diode 28 which serves as a pulse clipper. In the pulse shaper 29, rectified waves, or other positive going pulses passed by the diode 28 are transformed to square wave pulses. It should be noted that the output of the pulse shaper 29 may occur as pulses of various amplitudes passing into the input of themonostable multivibrator 30, but the output pulses of the monostable multivibrator are inherently constant in amplitude and time duration. Thediode 33 passes only the positive going portions of the output of themonostable multivibrator 30 which are amplified by theClass A amplifier 34 and impressed upon the coil of the double pole single throw relay 35 and thecondenser 36. The Class A amplifier is biased to output in the absence of a pulse from themonostable multivibrator 30, so that output pulses of the Class A amplifier tend to charge thecondenser 36 and to keep the normally closed double pole single throw relay 35 in its abnormal or open state. Thevariable condenser 37 controls the leakage and hence the 4 discharge of thecondenser 36 and thus determines the frequency with which pulses must appear at the output of theClass A amplifier 34 in order to keep the normally closed double pole single throw relay 35 in its abnormal or open state. Negative going transient pulses which may appear at the output of the monostable multivibrator are blocked by thediode 33 and are diverted to the positive terminal of thebattery 22 through theresistor 32.

Upon failure of a pulse to appear at the output of the Class A amplifier within a preset time internal, current sufiicient to maintain the double pole single throw relay in its abnormal state will cease to flow through the coil of that relay and its ar-matures 38 and 43 will return to their normal condition in electrical contact with theirrespective contact points 39 and 44. AC current flowing through the first described armature 38 and its contact point 39 lights the filament of the bulb 40 which is wired in series with the coil of the single polesingle throw relay 41; through the single polesingle throw relay 41 the AC current which operates the alarm light 40 also interrupts the auxilliary DC circuit which would otherwise flow through the second armature 43 of the double pole single throw relay and itscontact point 44 to operate theauxilliary alarm 47.Variable condensers 14 and 37 respectively control the sensitivity of detection of motion of the invention and the time domain of pulses necessary to keep an alarm from operating.

The horizontally disposedstrain gauge 20 is connected in the same manner as describedvertical strain gauge 14 to a DC amplifier, clipper, pulse shaper, monostable multivibrator, and diode as previously described for a vertically disposedstrain gauge 14. In the same manner, each strain gauge is electrically connected to an identical set of components as previously described for the vertically disposedstrain gauge 14, but the output for the diodes corresponding to thediode 33 previously described are connected in common to the input of theClass A amplifier 34 with theirrespective terminals 49 through 51 and acommon conductor 52 as indicated in FIGURE 2. Hence, a change in physical forces upon any strain gauge, results in the appearance of a positive pulse at the input of the Class A amplifier and of an output pulse therefrom which charges acondenser 36 and maintains the double'pole single throw relay in its abnormal or open condition.

An alternate form of the invention in illustrated FIG- URES 3, 4 and 5, compression type strain gauges are interiorly located within themattress 10 and extend between an upper and lower surface thereof. Generally, the strain gauge illustrated consists of a frame extending between upper and lower surfaces of the mattress and having the resilient portion integrally constructed as part of the frame so that motion anti-compression of the mattress is detected as a corresponding compression of the frame. A light bulb is supported by the lower portion of the frame and a relative motion between the shutter and the light bulb causes variations in the resistance of photo conductive cells carried by the frame.

For this particular reference to FIGURE 3, anupper plate 53 and alower plate 54 are horizontally disposed, one above the other, and are positioned interiorly of themattress 10 in contact with the upper and lower surfaces thereof. Anupper compression post 55 of tubular construct on is aflixed to the lower surface of theupper compresslon plate 53 and projects perpendicularly downwardly therefrom. In like manner, thelower compression post 56 is afiixed to the upper surface of thelower compression plate 54 and projects upwardly therefrom in coaxial alignment with theupper compression post 55. An upper photoconductive cell 57 is aflixed to the lower end of theupper compression post 55, and a lower photoconductive cell 58 is aflixed to the upper end of thelower compression post 56. The photoconductive cells 57 and 58 are spaced from one another and each is oriented so that its light sensitive parts face horizontally and rearwardly. Theresilient spacer 59 is respectively attached at its upper and lower surfaces to the upper and lower photoconductive cells 57 and 58; preferably, theresilient spacer 59 is constructed as a block of rubber. Alamp bracket 60 projects upwardly from thelower compression plate 54 at a position thereon spaced rearwardly from thelower compression plate 56. Alight socket 61 projects forwardly from thelamp 60 at the level of theresilient spacer 59 and alight bulb 52 is received by thesocket 61. Ashutter 63 comprising an elongated metal plate having anaperture 64 consisting of notched or saw-toothed lateral edges 65 is attached to and depends downwardly from theupper compression plate 53 between alight bulb 62 and the photoconductive cells 57 and 58. The lower end of theshutter 63 is spaced from but connected to thelower compression plate 54 by a coil spring at 66 having a spring tension which is very small when compared to the force required to achieve significant compression of theresilient spacer 59.

As shown in FIGURE 5, the photoconductive cells 57 and 59 are wired in series and are directly connected to the positive terminal of a DC.power source 67. The other terminal of the series wired photoconductive cells 57 and 59 is connected to thebase 68 of atransistor 69 having its collector 70 connected to the negative terminal of the DC.power source 67 through a resistor at 71. Theemitter 72 of thetransmitter 69 is connected to the positive terminal of the DC.power source 67 through a biasingresistor 73 and theemitter 72 is also connected to the base 74 of asecond transistor 75 having itsemitter 76 electrically connected to the positive terminal of the DC.power source 67 and having its collector electrically connected to the input of a DC. amplifier like theDC amplifier 27 previously described, and also having its collector connected to the negative terminal of the DC.power source 67 through atransistor 79.

In operation of the alternate form of the invention, displacement of thecompression plates 53 and 54 relative to one another, displaces theshutter 63 relative to thebulb 62 and also, to a certain extent, displaces the photoconductive cells 57 and 58 relative to one another. Linear displacement of theshutter 63 may be substantially identical with the linear displacement of anupper photo cell 57, but proximity of the shutter to thebulb 62 eliects a difference in the angular displacement of these two elements with respect to the bulb so that a change in the amount of illumination passing through the shutter to the upper photo conductive cell is accomplished. It should be noted that characteristics of the illustrated strain gauge can be altered merely by changing the configuration of the edges of the aperture so that within a given range the electrical characteristics of the strain gauge can be made linear with respect to applied pressure, or can be given exponential or logarithmic characteristics, if desired. On the other hand, caution should be exercised to make certain that anedge 65 of theaperture 64 is not such that displacement of thecompression plates 53 and 54 relative to one another does not bring about complementary effects in the photoconductive cells 57 and 58. Because the two cells are wired in series with one another, the net efiect of displacement of the shutter is the sum of the resistances of the two photoconductive cells 57 and 58; if theedge 65 of theaperture 64 of theshutter 63 is such that increase in illumination on one photo conductive cell leads at the same time to a decrease in illumination of the other photo conductive cell, then the two will tend to compensate for one another and the total electrical resistance will remain unaltered. Simple geometric considerations may be used to avoid this result when its avoidance is desired.

It should also be noted that aperture configuration of theshutter 63, as illustrated, can provide gain control characteristics for the output of the strain gauge in that respiratory motion of a heavy person may yield substantially the same result as that of a much lighter person, the only difference being that difierent saw tooth edges are 6 interposed between thelamp 62 and the photoconductive cells 57 and 58.

The invention is not limited to the exemplary construction herein shown and described, but may be made in various ways within the scope of the intended claims.

What is claimed is:

1. In an alarm including a mattress,

a strap exteriorly encompassing said mattress and having opposite ends terminating at a side of said mattress,

an electrical resistance type strain gauge having its operative opposite ends respectively attached to said opposite ends of said strap,

means providing an electrical potential across the resistive component of said strain gauge,

electrical pulsing means for producing a pulse for substantially each change in electrical current flowing through said resistive component of said strain gauge,

and alarm means connected to said pulsing means and responsive to the prolonged absence of electrical pulses of said pulsing means.

2. The invention as defined in claim 1 and wherein said alarm means includes a normally closed single throw relay,

a signal device wired in series with the armature of said relay and the normally closed contact point thereof,

a diode wired in series with the coil of said relay,

a condenser wired in parallel with said coil of said relay and in series with said diode,

a resistor wired in series with said condenser and in parallel with said coil of said relay,

and means electrically connecting said diode to said pulsing means.

3. In a mattress,

an alarm including an electrical strain gauge for producing a series of current changes having a given rate of occurrence in response to a series of strains placed upon said strain gauge,

means operatively connecting said strain gauge to exter-ior surfaces of said mattress,

pulsing means electrically connected to said strain gauge and responsive to changes in electrical current in said strain gauge,

means providing an electrical potential across said strain gauge,

and alarm means for providing a perceptable indication in response to a rate of occurrence of said pulses below said given rate.

References Cited UNITED STATES PATENTS 884,121 4/1908 Apold 340282 1,969,554 8/ 1934 Glouderman 340-272 2,260,715 10/ 1941 Ketchem.

2,666,650 1/1954 MacDonnel.

2,726,380 12/1955 Campisi 340279 2,787,834 4/1957 Shoup 88-14 X 2,831,181 4/1958 Warner 340-279 X 3,002,185 9/1961 Bases 340-279 3,034,341 5/1962 Golubovic 73-88 3,163,856 12/1964 Kirby 340279 3,184,961 5/1965 Bell 7388 FOREIGN PATENTS 919,765 2/ 1963 England.

OTHER REFERENCES Publication, IBM Technical Disclosure Bulletin, Respiration Transducer, Willis, vol. 6, No. 6, November 1963, copy in 250-221.

NEIL C. READ, Primary Examiner.

R. M. GOLDMAN, D. L. TRAFTON,

Assistant Examiners.

Claims (1)

1. IN AN ALARM INCLUDING A MATTRESS, A STRAP EXTERIORLY ENCOMPASSING SAID MATTRESS AND HAVING OPPOSITE ENDS TERMINATING AT A SIDE OF SAID MATTRESS, AN ELECTRICAL RESISTANCE TYPE STRAIN GAUGE HAVING ITS OPERATIVE OPPOSITE ENDS RESPECTIVELY ATTACHED TO SAID OPPOSITE ENDS OF SAID STRAP, MEANS PROVIDING AN ELECTRICAL POTENTIAL ACROSS THE RESISTIVE COMPONENT OF SAID STRAIN GAUGE, ELECTRICAL PULSING MEANS FOR PRODUCING A PULSE FOR SUBSTANTIALLY EACH CHANGE IN ELECTRICAL CURRENT FLOWING THROUGH SAID RESISTIVE COMPONENT OF SAID STRAIN GAUGE, AND ALARM MEANS CONNECTED TO SAID PULSING MEANS AND RESPONSIVE TO THE PROLONGED ABSENCE OF ELECTRICAL PULSES OF SAID PULSING MEANS.

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