Search Images Maps Play YouTube News Gmail Drive More »
Sign in
Screen reader users: click this link for accessible mode. Accessible mode has the same essential features but works better with your reader.


  1. Advanced Patent Search
Publication numberUS3017513 A
Publication typeGrant
Publication dateJan 16, 1962
Filing dateOct 8, 1959
Priority dateOct 8, 1959
Publication numberUS 3017513 A, US 3017513A, US-A-3017513, US3017513 A, US3017513A
InventorsStephen J Messelt
Original AssigneePerkin Elmer Corp
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Fire detection apparatus
US 3017513 A
Abstract  available in
Previous page
Next page
Claims  available in
Description  (OCR text may contain errors)

Jan. 16, 1962 s. J. MESSELT 3,017,


j STEPHEN J. MESSELT mm tatcs 3,0175% Patented Jan. 16, .1952


ration of New York Filed Oct. 8, 1959, Ser. No. 845,280

1 Claim. (Cl. 250-83.3)

This invention relates to fire detection systems and, more particularly, to a portable, infra-red fire detection apparatus.

Many scientific advances have been made in the field of fire fighting in the past few years. Many of these advances are at least partially nullified, however, by the difficulty of pin-pointing the exact location of hidden blazes. Smoke is one of the major problems of all fire fighters. Smoke fills a building in a matter of moments, obscuring the fire. Not only can the blaze continue its destructive course behind the obscuring screen but extensive water damage may be done in the necessary effort to reach all possible points of combustion.

Furthermore, even the apparent extinguishment of a fire may not result in its eradication. Unseen blazes often remain within walls and partitions. There is little visible indication of the existence of such fires. A fireman may use his hand to locate hot spots on a wall but this is a slow and time consuming procedure. Fires within wall spaces are notoriously rapid spreading. Air spaces act like flues in spreading the blaze from floor to floor.

It will be readily appreciated that firemen investigating burning buildings, carrying protective equipment, working under all sorts of weather conditions and in all types of structures, cannot be burdened with heavy, cumbersome equipment. This is particularly true when haste is imperative.

It is, therefore, the primary object of the present invention to provide a fire detection apparatus.

Other objects of this invention are to provide such an apparatus sensitive to infra-red radiation; having a selfcontained power supply; portable and easy to handle by one man; fast acting and reliable; and rugged and adaptable to operation under severe conditions.

The above objects are achieved by providing fire detection apparatus including focusing means adapted to receive and focus radiation from an inspected area and a detector positioned at substantially the focal point of the focusing means. The detector is part of an electronic circuit designed to produce an electrical signal responsive to the radiation. Indicating means are also provided responsive to the electrical signal to disclose the presence of fire in an inspected area.

The manner in which the above objects are attained will be more apparent from the following description taken together with the figures of the attached drawing, wherein FIG. 1 is a sectional elevational view of a detection apparatus of the invention; and

FIG. 2 is a schematic block diagram of a circuit usable in the present invention.

The apparatus of FIG. 1 includes a tubular barrel member which may be constructed of metal or other suitable material. A pistol grip 12 is provided to afford the user a positive, comfortable grip. A window 14 is enclosed within the barrel near its open end. A paraboloidal mirror 16 is positioned within the barrel to receive rays of entering infra-red radiation 18. Infra-red detector 20 is positioned on a bracket 22 at the focal point of reflector 16. A toroidal supporting member 24 is secured within barrel 10 as a support for mirror 16 which is bonded thereto. Member 24 may be of any suitable material but in the illustrated embodiment is of rubber or plastic to provide shock absorbing qualities. The

necessary circuit elements are reduced to printed circuit form and are positioned as members 26 within the barrel by means of supporting screws 28. A meter 30 for visual observation is mounted at the rear of the apparatus, electrically connected to the circuit by wires 32. Wires 34 are connected to a calibration knob 36. The wires interconnecting the detector and the various printed circuit boards are not shown. A battery 38 positioned within a suitable compartment within grip 12 provides the necessary power for operation.

The electrical circuit of the device as illustrated in the block diagram of FIG. 2 includes the detector 20, preamplifier 40, amplifier 42, rectifier 44, and meter 30. A

variable oscillator 46 may also be provided along with head phones 48 for producing an useful when visibility is limited. components is of standard construction and well known in the art, it has not been considered necessary to illustrate the circuits in more detailed fashion.

The primary function of window 14 is to maintain cleanliness within barrel 10 and thereby protect the surface of reflector 16. Window 14, however, may also be used as a filter, for example, to eliminate visible light which might give erroneous readings.

For the detection of fire sources, a detector responsive to a temperature of approximately 210 F. is required. However, in order to provide some margin of safety and, at the same time, compensate for the insulating qualities of walls and partitions, the apparatus is preferably made sensitive to heat sources of F. In addition, for maximum efficiency, the heat source should be detectable at a distance of ten feet. The energy emitted by a black body radiator at 150 F. is 7X10 watts/cm. By using a three inch paraboloidal reflector to focus the radiation, the available energy at a detector is approximately 1.26 10- watts.

The detector should be of the uncooled type and have a spectral response within a wavelength band not absorbed by the atmosphere. Examples of usable wavelengths are 3.5 to 4.3 and 5.0,!L. The noise equivalent power of the detector should provide a good signal to noise ratio at 126x10 watts.

Several detectors will satisfy the foregoing requirements-a bolometer, lead selenide, or lead sulfide, to name a few.

Because of the drift problems encountered in the DC. amplification of detector signals, it is preferable to utilize an AC. amplifier. In order to do this, the signal must be chopped. In order to eliminate the necessity for a mechanical chopper, the detector may be wired into an AC. bridge circuit excited by an oscillator. Any of a number of easily portable battery sources may be utilized for a power supply. In the described embodiment, a rechargeable 9 volt mercury battery is employed.

It will now be seen that in order to locate the existence of hot spots, an operator need only scan an area, such as a wall, by pointing the apparatus in the proper direction. The infra-red energy, guided through barrel 10 and focused on the detector by the reflector, will cause a signal to flow in the electrical circuit. The signal, amplified and impressed on a meter or headphone, will thus give a physical indication of the presence of fire.

It will be apparent that the device of the present invention has wide application in all fields in which the location of heat sources is of importance. It will be further apparent to those skilled in the art that the apparatus of this invention is capable of many variations. The tubular radiation path, for example. is not limited to a construction of circular cross section but may be of any convenient shape such as square, octagonal, or oval. The

foregoing description is therefore to be construed as descriptive rather than limiting.

audible signal especially As each of the electrical I claim:

Fire detection apparatus comprising a tubular barrel having an infrared permeable window at one end thereof, said window being of substantially disk-like configuration and lying in a plane perpendicular to the longitudinal axis of said barrel; pistol grip means attached to said barrel for supporting the apparatus in a users hand; paraboloidal reflector means positioned in said barrel to receive the radiation passed by said window and focus said radiation on a finite area between said window and said reflector; detector means selected from the group consisting of lead selenide, lead sulphide, and bolometers positioned to receive the focused radiation, said detector being responsive to radiation Wavelengths selected from the group consisting of about 3.5;1, to 4.3 4 and approximately 5,u.; electronic alternating current circuit means within said barrel means for producing an electrical signal responsive to the radiation on said detector; battery means within said pistol grip for supplying electric power to said circuit means; and indicating means responsive to said electric signal to disclose the presence of fire in an inspected area.

References Cited in the file of this patent Osborne: Airborne Infrared UNITED STATES PATENTS OTHER REFERENCES Warning System Measures Range, Electronics, July 1, 1957, pp. 190192.

Osborne: Infrared Detector Aids Medical Diagnosis, Electronics, October 1, 1957, pp. 115-157.

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US842314 *Nov 11, 1905Jan 29, 1907CfcmugPyrometer.
US2491192 *Nov 11, 1944Dec 13, 1949Gen Motors CorpSealed heat ray detector
US2674155 *Jul 19, 1950Apr 6, 1954Nat Res DevPyrometer
US2738432 *Jan 9, 1953Mar 13, 1956Gilford Saul RMeterless radiac survey instrument
US2798962 *Jul 18, 1956Jul 9, 1957Servo Corp Of AmericaTotal-radiation pyrometer
US2871366 *Dec 29, 1955Jan 27, 1959Librascope IncApparatus for sensing radioactivity
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3110814 *Jul 11, 1961Nov 12, 1963Charles E WrightLight responsive device for producing sounds
US3444739 *Dec 22, 1965May 20, 1969Kettering Scient Research IncRadiant energy measuring instrument
US3761713 *Jul 13, 1971Sep 25, 1973Us InteriorMethod of detecting loose rock
US4494881 *Mar 10, 1982Jan 22, 1985Everest Charles EIntra-optical light beam sighting system for an infrared thermometer
US4634294 *May 12, 1981Jan 6, 1987Raytek, Inc.Hand-held digital temperature measuring instrument
US5352039 *Aug 6, 1991Oct 4, 1994OrtomedicRemote temperature and/or temperature difference measuring device
US5422484 *Dec 19, 1990Jun 6, 1995Alenia Spazio SpaInfrared sensor suitable for fire fighting applications
US5751215 *Nov 21, 1996May 12, 1998Hall, Jr.; Joseph F.Fire finding apparatus
US5790040 *Dec 13, 1996Aug 4, 1998Interactive Technologies, Inc.Battery-operated security system sensors
US6719456Oct 23, 2001Apr 13, 2004Randall S. MundtMethods and apparatus for firefighting
US7250603Mar 24, 2006Jul 31, 2007Draeger Safety, Inc.Crawling handle for thermal imaging camera
US7420672Jun 20, 2007Sep 2, 2008Ahura CorporationMethod and apparatus for conducting Raman spectroscopy
US7499159Jul 11, 2006Mar 3, 2009Ahura CorporationMethod and apparatus for conducting Raman spectroscopy using a remote optical probe
US7548311Jun 27, 2006Jun 16, 2009Ahura CorporationMethod and apparatus for conducting Raman spectroscopy
US7595877Oct 29, 2007Sep 29, 2009Ahura CorporationLow profile spectrometer and raman analyzer utilizing the same
US7636157Apr 29, 2005Dec 22, 2009Ahura CorporationMethod and apparatus for conducting Raman spectroscopy
US7701571Aug 22, 2007Apr 20, 2010Ahura Scientific Inc.Raman spectrometry assembly
US7767963Dec 8, 2006Aug 3, 2010Draeger Safety, Inc.Thermal imaging camera internal damping system
US7773645Nov 7, 2006Aug 10, 2010Ahura Scientific Inc.Uncooled external cavity laser operating over an extended temperature range
US8107069Sep 9, 2009Jan 31, 2012Ahura Scientific Inc.Method and apparatus for conducting Raman spectroscopy
US20050248759 *Apr 29, 2005Nov 10, 2005Peidong WangMethod and apparatus for conducting Raman spectroscopy
US20060045151 *Apr 29, 2005Mar 2, 2006Daryoosh VakhshooriExternal cavity wavelength stabilized Raman lasers insensitive to temperature and/or external mechanical stresses, and Raman analyzer utilizing the same
US20060088069 *Aug 30, 2005Apr 27, 2006Daryoosh VakhshooriUncooled, low profile, external cavity wavelength stabilized laser, and portable Raman analyzer utilizing the same
US20060170917 *Aug 30, 2005Aug 3, 2006Daryoosh VakhshooriUse of free-space coupling between laser assembly, optical probe head assembly, spectrometer assembly and/or other optical elements for portable optical applications such as Raman instruments
US20060245700 *Jun 29, 2006Nov 2, 2006Draka Comteq B.V.Groove cable
US20070024848 *Jul 11, 2006Feb 1, 2007Knopp Kevin JMethod and apparatus for conducting RAMAN spectroscopy using a remote optical probe
US20070116069 *Nov 7, 2006May 24, 2007Peidong WangUncooled external cavity laser operating over an extended temperature range
US20080024777 *Jun 20, 2007Jan 31, 2008Peidong WangMethod and apparatus for conducting Raman spectroscopy
US20080170223 *Oct 29, 2007Jul 17, 2008Daryoosh VakhshooriLow Profile Spectrometer and Raman Analyzer Utilizing the Same
US20090033928 *Aug 22, 2007Feb 5, 2009Masud AzimiRaman spectrometry assembly
US20090251694 *Jun 15, 2009Oct 8, 2009Ahura Scientific Inc.Method and Apparatus for Conducting Raman Spectroscopy
US20100290042 *Apr 4, 2008Nov 18, 2010Ahura Corporation, A Massachusetts CorporationUse of Free-space Coupling Between Laser Assembly, Optical Probe Head Assembly, Spectrometer Assembly and/or Other Optical Elements for Portable Optical Applications Such as Raman Instruments
US20100296085 *Apr 20, 2010Nov 25, 2010Ahura Scientific Inc.Raman spectrometry assembly
EP2706331A1 *Jul 4, 2013Mar 12, 2014Robert Bosch GmbhTemperature measuring apparatus, in particular hand-held infrared measurement device
WO1991009389A1 *Dec 19, 1990Jun 27, 1991Selenia Industrie Elettroniche Associate S.P.A.Infrared sensor suitable for fire fighting applications
WO1992002792A1 *Aug 6, 1991Feb 20, 1992OrtomedicRemote temperature and/or temperature difference measuring device
U.S. Classification250/347, 250/339.15, 374/124, 356/141.2, 250/353
International ClassificationG01J5/04, G08B17/12
Cooperative ClassificationG01J5/02, G01J5/0205, G01J5/08, G08B17/12, G01J5/0806, G01J5/0265, G01J5/04
European ClassificationG01J5/02A, G01J5/02H, G01J5/08B1, G08B17/12, G01J5/04, G01J5/02, G01J5/08