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Publication numberUS3813578 A
Publication typeGrant
Publication dateMay 28, 1974
Filing dateJan 3, 1973
Priority dateJan 3, 1973
Publication numberUS 3813578 A, US 3813578A, US-A-3813578, US3813578 A, US3813578A
InventorsTiffany F
Original AssigneeFisher Controls Co
Export CitationBiBTeX, EndNote, RefMan
External Links: USPTO, USPTO Assignment, Espacenet
Electrical safety barrier
US 3813578 A
Abstract
An electrical safety barrier for providing safe electrical interconnection between a safe area and a hazardous area. A circuit interconnects terminals for apparatus in the hazardous area. The circuit includes, in series, a diode, a current-limiting impedance, and current-interrupting means. Zener diodes, each of the same polarity, are connected on either side of the diode. Accordingly, the zener diodes provide independent fail-safe limiting of the voltage at the terminals in the hazardous area and yet can be independently tested.
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Description  (OCR text may contain errors)

Unite States Patent 1 1 Tiitany I 1111 3,813,578 1451 May 28, 1974 ELECTRICAL SAFETY BARRIER [75]. Inventor: Floyd L. Tiffany, Marshalltown,

Iowa

Fisher Controls Company, Inc., Marshalltown, Iowa Filed: Jan. 3, 1973 Appl, No.: 320,786

Assignee:

US. Cl .t 317/16, 317/18 C, 317/31 Int. Cl. H02h 3/20 Field of Search 317/18 C, 16, 31,33 R,

References Cited UNITED STATES PATENTS 6/1965 Massena ..317/I6 -2/l967 Blenhoff 3,624,449 11 1971 Morgan.... 317 16 x 3';631,'2 4 12/"1911 Morgan "317/16 x Primary Examiner.lames D. Trammell Attorney, Agent, or FirmPeter S. Gilster; Harold R. Patton; Neal E. Willis [5 7 ABSTRACT 4 Claims, 4 Drawing Figures zz I ,6 r 7? 1 A I as i PATENTEflm 28 m4 FIG.2

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FIG. 4

3 0 A 5 7 mw 4 My x x 7 .H

1 ELECTRICAL SAFETY BARRIER BACKGROUND OF THE INVENTION The invention relates to electrical safety barriers and more particularly to an improved electrical safety barrier of the intrinsic type and providing'fail-safe limiting of voltages. I

In the field of industrial control in which processes at remote locations are monitored and/or supplied with power from a central station, the use of electrical apparatus to provide the desired monitoring, power supplying, alarming and controlling functions, is increasing rapidly. In the petroleum and chemical industry wherein flammable or explosive materials at the remote locations present a potentially dangerous situation, it is extremely important, and often necessary, that steps be taken to protect against excessive electrical energy caused by various fault conditions or malfunctions.

Heretofore, it has been the general practice to'provide an electrical safety barrier which is interconnected with'electrical apparatus used in industrial control applications of the type mentioned above. The barrier device is electrically interposed between the safe area and the hazardous area and comprises circuitry which includes fuse devices, resistors, andvoltage regulating devices to limit the current and voltage to acceptably safe levels. Oneform of a typical electrical barrier device is shown in Brown U.S. Pat. No. 3,527,985. Typically, it is required that there be exposed-only those terminals of the barrier which are to be connected to circuitry or apparatus in the safe and. hazardous areas. Thus, devices of this type are conventionallyof encapsulated or potted tamper-proof construction.

Advantageously, such barriers employ aplurality of voltage-regulating devices, suchas zener diodes, for redundancy; .Since the'circuitry of the barrier is inaccessible because of the tamper-proof construction, difficulty may be encountered in periodically testing the zener diodes or other circuit components of the barrier, as is necessary. This has heretofore required the use of zener diodes carefully selected to have zener voltages of very close tolerances, a magnetic switch arrangement for isolating the zener diodes during testing, or the use of .a relatively large resistance separating the zener diodes. All of these approaches are objectionable resistance of the barrier may preclude monitoring or transmitting a signal of ample magnitude.

On the other hand, the use of a magnetic switch as shown in the aforesaid Brown patent offers noresistance to an ac. fault current and is inconsistant with the need for a high insertion impedance under fault conditions.

SUMMARY OF THE INVENTION Among the several objects of the invention may be noted the provisions of an improved electrical safety barrier; the provision of such a barrier which is easily tested, which does not require close tolerance zener diodes in selecting difierences in zener voltages, or a large resistance between the zener diodes; th provision of such a barrier which provides a low insertion resistance under normal conditions and a high insertion resistance under fault conditions in order to limit the magnitude of an ac. fault current supplied to a hazardous area during the fault condition; and the provision of such a barrier which is simple and inexpensively constructed. Other objects and features will in part appar ent and in part pointed out hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS FIGS. 1-4 are schematic circuit diagramsof alternate configurations of the preferred electrical safety'barrier embodimentfor use under respective different condiparts throughout several views of the draw- DESCRIPTION or THE PREFERRED I I EMBODIMENT Referring now to FIG. 1, an electrical safety barrier of the invention comprises circuitry which is suitably potted, encapsulated or otherwise protected-by a tam per-proof enclosure (not shown). The barrier includes a first set of terminals T1 and T2 for connection to apparatus in a safe area to the left of a dashed line A. Such apparatus is here represented by a d.c. voltage source V supplying apotential to terminal TI which is positive with respect to terminal T2. A second set of terminals T3-and T4 is provided for connection to apparatussuch as a load L in a hazardous area to the right of a dashedline B. These sets of terminals maybe at opposite ends of the tamper-proof enclosure, which may be a few=inches in length, for example.

Terminals T2 and T4 are commonly connected and may be tied to earth ground by a fifth terminal T5 which is preferably constituted by one or more studs which project from the enclosure for' securing the barrier to a grounded bus bar. Such a ground in represented phantom A series circuit between cludes a fuse F, its small associated intrinsic resistance R1, a diode'D2 oriented to permit current flow in the direction from terminal T1 to terminal T3, and an impedance element such as a resistor R2.

Zener diodes D1 and D3 have their cathodes connected on opposite sides of diode D1 and their anodes interconnected with ground terminals T2, T4 and T5. The zener voltages of diodes D1 and D3 are selected so that the potential across terminals T3 and T4 under a fault condition will be regulated by the zener diodes so as not to exceed a safe level. The provision of two zener diodes provides a redundant, fail-safe feature in that each zener diode can independently regulate the potential across terminals T3 and T4 even though one of the zener diodes may experience an open circuit failure. Of course, if either zener diodes experiences a short circuit failure, the closed circuit to ground will prevent any potential from appearing across terminals T3 and Resistor R2 need be no larger than will limit the current to a safe value which will not ignite explosive mixtures, etc., in the hazardous area assuming short circuit conditions across terminals T3 and T4. Diode D2 is forward biased under normal operating conditions in which current flow is from terminal T1 to terminal T3.

terminals Tl and T3 in- 4 3 Accordingly, the resistance between terminals T1 and T3 is relatively low and the barrier provides a low insertion resistance.

In the event of a fault condition (such as a short circuit in the safe area) applying an ac. voltage across terminals T1 and T2, diode D2 advantageously blocks any flow of current in the direction from terminal T3 to terminal T1 and thereby limits the amount of energy which can flow into the hazardous area from the safe area assuming that fuse Fl has not blown. It will be understood that fuse F] has a rating appropriate to the use of the barrier in a certain application and its function is to interrupt the current flow if the current exceeds a predetermined maximum level. I

Although zener diodes D1 and D3 need not have close tolerances and need not-have widely different zener-voltages, they are selected so that the zener voltage of diode D3 is somewhat greater than that of diode D1. This facilitates testing of the two zener diodes. For this purpose, it is normally sufficient if the lower tolerance for the zener voltage of diode D3 is approximately equal to or greater than the higher'tolerance for the zener voltage of diode D1.

I All components of the barrier may be easily tested by use of the barrier terminals. First, a small current is established from terminal T1 to terminal T3 to verify that fuse F1 and diode D2 are intact. Then a test is made to insure that no current is passed from terminal T3 to terminal Tl, checking proper reverse blocking operation of diode D2. A test is nextmade to verify proper operation of diode D1. A current is established from terminal Tlto terminal T2 and a potential at terminal T3 is measured to see whether it is equal to the zener voltage of diode D1 less the drop across diode D2 (normally about 0.7 v.) and less the IR drop across resistor R2. If this potential at terminal T3 is correct, diode D1 can be assumed to be operating properly. Finally, a current is established from terminal T3 to terminal T4 to verify that diode D3 is intact and operating properly.

Where the barrier is to be used with very low signal voltages, zener diodes D1 and D3 may each be replaced by a pair of oppositely oriented paralleled semiconductor diodes. Satisfactory regulation at the low signal voltages is achieved by virtue of the clipping or limiting operation provided. by each such pair of diodes.

FIG. 2 illustrates a configuration for use where it is desired that current flows from terminal T3 to terminal Tl, i.e.. from the hazardous area to the safe area, and where terminal T3 is to be positive with respect to terminal T4. This arrangement is thus useful where apparatus in the hazardous area acts as the voltage source and monitoring or other apparatus in the safe area constitutes the load.

FIG. 3 shows an arrangement where current must flow from terminal T1 to terminal T3 but where terminal Tl is negative with respect to terminal T2.

The arrangement of FIG. 4. is useful for situations where current flow is to be from terminal T3 to terminal Tl but where terminal T3 is negative with respect to terminal T4. v i

In FIG. 4, the zener voltage of diode D3 must be 4 greater than that of diode D1 while in FIGS. 2 and 3 the opposite is true.

In view of the foregoing, it will be seen that the several objects of the invention are achieved and other advantageous results attained.

As various changes could be made in the constructions herein illustrated without departing from the scope of the invention, it is intended that all mater contained in the above description shall be interpreted as illustrative and not in a limiting sense.

What is claimed is:

l. A fail-safe and easily tested electrical safety barrier for providing'safe electrical interconnection between a safe area and a hazardous area, said barrier comprising:

first terminal means for connection with apparatus in said safe area; second terminal means for connection with apparatus in said hazardous area; I a circuit interconnecting said firstand second terminal means, said circuit including in series relationship: I diode means for permitting only unidirectional flow of current between said first and second terminalmean's, said diode means being forward biased under normal operating conditions to provide low insertion resistance between said safe and hazardous areas;

current-limitingmeans for limiting said flow of current; and

current-interrupting means adapted to interrupt saidflow of current if the current exceeds a predetermined maximum;

first and second voltage regulating devices each connected with said circuit on opposite sides of said diode. means, each of said voltage regulating means being adapted for limiting the voltage at said second terminal means to a safe value during abnormal operating conditions, said regulating devices being independent whereby the voltage at said second terminal means is limited regardless of failure of one of said regulating devices, and whereby each of said regulating devices can be independently tested by passing current through either of said first and second terminal means; and

ground terminals respectively associated with each of said first and second terminal means; said ground terminals having a common connection, said zener diodes each having one side connected to said 4 fuse.

Patent Citations
Cited PatentFiling datePublication dateApplicantTitle
US3187224 *Aug 21, 1961Jun 1, 1965Honeywell IncControlling apparatus for protecting low current sensitive measuring instruments
US3305849 *Oct 11, 1962Feb 21, 1967Houston Fearless CorpCircuit for preventing accidental erasure of clock signals
US3624449 *Aug 24, 1970Nov 30, 1971Sybron CorpIntrinsically safe transmitter system
US3631264 *Feb 11, 1970Dec 28, 1971Sybron CorpIntrinsically safe electrical barrier system and improvements therein
Referenced by
Citing PatentFiling datePublication dateApplicantTitle
US3946278 *Dec 19, 1973Mar 23, 1976Westinghouse Air Brake CompanyFail-safe four leaded zener diode arrangement
US3955132 *Jun 18, 1974May 4, 1976Coal Industry (Patents) LimitedIntrinsically safe power supply apparatus
US3997733 *May 1, 1975Dec 14, 1976Browne-Davies Electronic CorporationIntrinsically safe communication systems
US4149209 *Jan 6, 1977Apr 10, 1979Rca CorporationOver-voltage amplitude prevention circuit for high voltage and deflection generating system
US4420840 *Aug 17, 1981Dec 13, 1983Livermore Thomas RIntrinsically safe photoelectric sensing
US4550358 *Feb 13, 1984Oct 29, 1985Sunbeam CorporationProtective circuit for portable electric appliances
US6266220 *Jun 9, 1997Jul 24, 2001Sami S. LahoudInternal surge protector device
US6756666 *Dec 13, 2000Jun 29, 2004Nec CorporationSurface mount package including terminal on its side
US7091631 *Aug 14, 2002Aug 15, 2006Pepperl & Fuchs GmbhIntrinsically secure device for supplying redundant current-voltage
US8848332Dec 14, 2012Sep 30, 2014Siemens AktiengesellschaftIntrinsically safe energy limiting circuit
US20040252428 *Aug 14, 2002Dec 16, 2004Martin JunkerIntrinsically secure device for supplying redundant current-voltage
EP0310281A2 *Sep 20, 1988Apr 5, 1989Measurement Technology LimitedElectrical safety barriers
EP0629030A1 *Sep 20, 1988Dec 14, 1994Measurement Technology LimitedElectrical safety barriers
EP1782516A2 *Aug 24, 2005May 9, 2007Itron, Inc.Resistor dropper power supply with surge protection
EP1782516A4 *Aug 24, 2005Jul 30, 2008Itron IncResistor dropper power supply with surge protection
EP2605355A1 *Dec 15, 2011Jun 19, 2013Siemens AktiengesellschaftIntrinsically safe energy limiting circuit
WO2006026297A2Aug 24, 2005Mar 9, 2006Itron Electricity Metering IncResistor dropper power supply with surge protection
Classifications
U.S. Classification361/88, 361/104, 361/58
International ClassificationH02H9/00
Cooperative ClassificationH02H9/008
European ClassificationH02H9/00E