US2336504A - Thermostatic switch - Google Patents

Thermostatic switch Download PDF

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US2336504A
US2336504A US382687A US38268741A US2336504A US 2336504 A US2336504 A US 2336504A US 382687 A US382687 A US 382687A US 38268741 A US38268741 A US 38268741A US 2336504 A US2336504 A US 2336504A
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resistance
layer
strip
contact
switch
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US382687A
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Ruben Samuel
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    • HELECTRICITY
    • H05ELECTRIC TECHNIQUES NOT OTHERWISE PROVIDED FOR
    • H05BELECTRIC HEATING; ELECTRIC LIGHT SOURCES NOT OTHERWISE PROVIDED FOR; CIRCUIT ARRANGEMENTS FOR ELECTRIC LIGHT SOURCES, IN GENERAL
    • H05B41/00Circuit arrangements or apparatus for igniting or operating discharge lamps
    • H05B41/02Details
    • H05B41/04Starting switches
    • H05B41/06Starting switches thermal only

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  • This invention relates to a thermostatic switch for starting fluorescent lamps.
  • An object of the invention is to improve therinostatic switches and parts thereof.
  • Another object is to improve the starting switches for fluorescent lamps and the like.
  • the invention comprises the features of construction, combination of elements, arrangement of parts, .and methods of manufacture and op eration referred to above or which will be brought out and exemplified in the disclosure hereinafter set forth, including the illustrations in the drawing.
  • FIG. l is a top view partly in section of a thermostatic switch suitable for starting fluorescent lamps embodying features of the present invention
  • Figure 2 is a vertical section thereof
  • Figure 3 is another vertical section looking at the opposite side of the active element
  • Figure 4 is a section on the line 1-4 of Figure 2;
  • Figure 5 is an outside perspective view of the complete device.
  • Figure 6 shows a circuit in which the device may be employed.
  • the fluorescent lamps having heat filaments for thermionic emission, thesemust be heated to electron emissive temperature prior to the application of line voltage.
  • the switch must open an inductive circuit so as to provide a transientbreakdown voltage for the ,gas column, which voltage is higher than the to overcome some of the limitations in present types of switches.
  • the switch preferably comprises a heater element of high resistancewhich is applied to one side of an insulating layer, preferably a thin sheet of low thermal expansion, such as sheet mica. Adjacent to the opposite side of the sheet is a strip of material having a high coeflicient of expansion. The operation is dependent upon the difference in expansion coeflicient. Due to low mass and close relation of elem rs a quick acting device is had, insensitive to external mechanical conditions such as vibration, operation or position.
  • FIG. 1 illustrates a device of this invention.
  • the complete switch comprising a piece of mica 10 which, by way of example, may have the dimensions x 1 /4" x 5 mil thick. It is mounted on steel channel supports I l and I2 which clamp it firmly and also make electrical contact with the other elements.
  • a strip of brass or beryllium bronze 13 having a silver contact I4 in the center is riveted at both ends to mica plate In by rivets l5 and I6 and the upper end makes electric contact with support H at l1.
  • Strip l3 may be 5 mils thick, for example.
  • the integral heating element comprises a layer of resistance material 20, such as graphite, which is applied from a colloidal solution. and baked on.
  • the width of the layer may be about and its resistance 9500 ohms, for example.
  • One end of the resistance layer 20 is connected to support I l and the other end to support l2.
  • Supports H and [2 are connected, by flexible leads 29 and 30 to connector prongs 2
  • the unit flts into a circular aluminum container 24 which has a fibre wall lining 25 to prevent short circuit of supports II and I2. Th construction provides a compact plug-in unit.
  • the device may be connected in a fluorescent lamp circuit as a starting device therefor in the manner shown in Figure 6.
  • the tubular fluorescent lamp 26 having filament electrodes in each end thereof is connected to the electric power supply line 21, the thermostatic starting switch described above and an inductive reactance 28 as follows: from one side of the power supply line through reactance 28, one filament electrode of tube 26, the resistance 20 of the thermostatic starting switch and the second filament electrode of tube 26 to the opposite side of the power supply line.
  • the reactance 28 may, by way of example, have a reactance of about 300 ohms.
  • the thin resistance layer can be obtained in several ways. For example, it can be produced by use of colloidal graphite solution such as a 5% solution derived from commercial aqueous solution known as Aquadag. It can be obtained by mixing micronized graphite (Dixon) with a binder such as a 5% solution of urea formaldehyde resin in butanol xylol solvent. It can also be obtained from a platinic chloride solution. Where inorganic binders are desirable a solution of sodium silicate can be used.
  • colloidal graphite solution such as a 5% solution derived from commercial aqueous solution known as Aquadag. It can be obtained by mixing micronized graphite (Dixon) with a binder such as a 5% solution of urea formaldehyde resin in butanol xylol solvent. It can also be obtained from a platinic chloride solution. Where inorganic binders are desirable a solution of sodium silicate can be used
  • the unit can be completely assembled on the base prior to adjusting the contacts.
  • the flexible leads 29 and 30 prevent any stresses being transferred from the plug-in base to the unit after assembly.
  • a small capacitance can be connected across the unit to reduce any radio interference during break of circuit.
  • the shunt effect of the resistor layer is adequate.
  • An electrically operated thermostatic switch comprising a sheet of insulating material, an electric resistance strip on one face thereof and a metal strip secured to the opposite face thereof, means to make electrical connection to the ends of said resistance strip, and a pair of co-operating electric contacts controlled by said metal strip upon thermal expansion and contraction thereof, said contacts beingopen when said metal strip is cold and closed when it is heated and being connected to opposite ends of said resistance strip to short-circuit said resistance strip upon contact closure.
  • An electrically operated thermostatic fluorescent lamp starting switch comprising a sheet of insulating material, an electric resistance strip on one face thereof and a metal strip secured at its ends to the opposite face thereof, means to make electrical connection to the endsof said resistance strip, said metal strip being connected to one end of said resistance strip and having a first electric contact on its outer face at a point intermediate its ends, a second relatively stationary electric contact secured to the opposite end of said resistance strip and supported in cooperative relation to said first contact to short circuit said resistance upon thermal expansion of said metal strip.
  • An electrically operated thermostatic switch comprising a rectangular sheet of insulating material, a pair of metal channel supports clamping opposite edges of said sheet, a layer of resistance material diagonally on said sheet and connecting said supports, a metal strip riveted at its ends diagonally against the opposite face of said sheet substantially in register with said resistance layer and electrically connected to the first of said supports, said metal strip carrying a first contact at an intermediate point thereon, a second contact and means supporting said second contact in cooperating relation to said first contact and connecting said second contact to the second of said supports whereby to short-circuit said resistance upon thermal expansion of said metal strip.
  • a thermostatic switch comprising a layer of mica, a layer of metal of higher thermal expansion coeificient than said mica secured thereto in face-to-face contact therewith, and a pair of electric contacts controlled by said metal layer upon thermal expansion and contraction thereof.
  • a thermostatic switch comprising a layer of mica, a layer of metal of higher thermal expansion coefiicient than said mica riveted thereto in face-to-face contact therewith, and a pair of electric contacts controlled by said metal layer upon thermal expansion and contraction thereof.
  • An electrically operated thermostatic switch comprising a sheet of insulating material, an electric resistance layer on one fac thereof, a metal layer secured to the opposite face thereor whereby it may be readily heated by said electric resistance layer, and a pair of electric contacts controlled by said metal layer upon thermal expansion and contraction thereof.

Description

Patented Dec. I4, 1943 UNITED STATES PATENT OFFICE THERMOSTATIC swrron Samuel Ruben, New Rochelle, N. Y. Application March 11, 1941, Serial No. 382,687
6 Claims.
This invention relates to a thermostatic switch for starting fluorescent lamps.
An object of the invention is to improve therinostatic switches and parts thereof.
Another object is to improve the starting switches for fluorescent lamps and the like.
Other objects of the invention will be apparent from the following description and accompanying drawing taken in connection with the appended claims.
The invention comprises the features of construction, combination of elements, arrangement of parts, .and methods of manufacture and op eration referred to above or which will be brought out and exemplified in the disclosure hereinafter set forth, including the illustrations in the drawing.
In the drawing:
Figure l is a top view partly in section of a thermostatic switch suitable for starting fluorescent lamps embodying features of the present invention;
Figure 2 is a vertical section thereof;
Figure 3 is another vertical section looking at the opposite side of the active element;
Figure 4 is a section on the line 1-4 of Figure 2;
Figure 5 is an outside perspective view of the complete device; and
Figure 6 shows a circuit in which the device may be employed.
In the present, commercial voltage operated fluorescent lamp there is required an automatically operating switch which serves two functlons:
'1. Heating of the filaments. The fluorescent lamps, having heat filaments for thermionic emission, thesemust be heated to electron emissive temperature prior to the application of line voltage. I
2. Producing a transient starting voltage. The switch must open an inductive circuit so as to provide a transientbreakdown voltage for the ,gas column, which voltage is higher than the to overcome some of the limitations in present types of switches.
The switch preferably comprises a heater element of high resistancewhich is applied to one side of an insulating layer, preferably a thin sheet of low thermal expansion, such as sheet mica. Adjacent to the opposite side of the sheet is a strip of material having a high coeflicient of expansion. The operation is dependent upon the difference in expansion coeflicient. Due to low mass and close relation of elem rs a quick acting device is had, insensitive to external mechanical conditions such as vibration, operation or position.
While a preferred embodiment of the inventionis described herein, it is contemplated that considerable variation may be made in the method of procedure and the construction of parts without departing from the spirit of the invention. In the following description and in the claims, parts will be identified by specific names for convenience, but they are intended to be as generic in their application to similar parts as the art will permit.
In order to more specifically describe this invention, reference is made to the accompanying drawing which illustrates a device of this invention. In Figures 1 to 5 are illustrated the complete switch comprising a piece of mica 10 which, by way of example, may have the dimensions x 1 /4" x 5 mil thick. It is mounted on steel channel supports I l and I2 which clamp it firmly and also make electrical contact with the other elements. A strip of brass or beryllium bronze 13 having a silver contact I4 in the center is riveted at both ends to mica plate In by rivets l5 and I6 and the upper end makes electric contact with support H at l1. Strip l3 may be 5 mils thick, for example.
Attached to the opposite support post I 2 is stationary contact arm l8 carrying contact l9 which is preferably spaced about 6 mils from contact M on metal strip 13. The integral heating element comprises a layer of resistance material 20, such as graphite, which is applied from a colloidal solution. and baked on. The width of the layer may be about and its resistance 9500 ohms, for example. One end of the resistance layer 20 is connected to support I l and the other end to support l2.
Supports H and [2 are connected, by flexible leads 29 and 30 to connector prongs 2| and 22,
respectively, mounted in Bakelite disc base 23 to form a plug-in unit. The unit flts into a circular aluminum container 24 which has a fibre wall lining 25 to prevent short circuit of supports II and I2. Th construction provides a compact plug-in unit.
The device may be connected in a fluorescent lamp circuit as a starting device therefor in the manner shown in Figure 6. As shown in this figure, the tubular fluorescent lamp 26 having filament electrodes in each end thereof is connected to the electric power supply line 21, the thermostatic starting switch described above and an inductive reactance 28 as follows: from one side of the power supply line through reactance 28, one filament electrode of tube 26, the resistance 20 of the thermostatic starting switch and the second filament electrode of tube 26 to the opposite side of the power supply line. The reactance 28 may, by way of example, have a reactance of about 300 ohms.
In operation, when the line voltage is applied current flows through the circuit the parts of which are of relatively low resistance compared to resistance layer 20, and layer 20, therefore, receives practically the full line voltage. This causes it to heat rapidly due to the low mass of circuit the resistor element 20 and allow full line current less drop in reactance 28, to be applied to the filaments in' the ends of tube 26 and, being of low mass (20 milligrams) they rapidly heat up to emission temperature.
, In view of the fact that the heater resistor layer 20 becomes short-circuited when contacts I4 and I9 close, heating of the resistance stops thereby allowing rapid cooling of themica with the result that the contacts are quickly opened due to contraction of the metal strip 13. This in turn breaks the filament circuit and a surge voltage is produced across the lamp by reactance 28 which causes a current flow to be had between the hot electron emissive filaments.
As the current continues the voltage drops across resistor 20 to about 60 volts. This voltage is insufiicient to heat it up to a temperature adequate to cause the strip to expand enough and close contacts. There is a fairly rapid movement of brass strip in operation which is due to the difference in expansion between the mica and brass. Due to the riveting at the ends, a slight tension is had which aids in the rapidity of break.
The thin resistance layer can be obtained in several ways. For example, it can be produced by use of colloidal graphite solution such as a 5% solution derived from commercial aqueous solution known as Aquadag. It can be obtained by mixing micronized graphite (Dixon) with a binder such as a 5% solution of urea formaldehyde resin in butanol xylol solvent. It can also be obtained from a platinic chloride solution. Where inorganic binders are desirable a solution of sodium silicate can be used.
The unit can be completely assembled on the base prior to adjusting the contacts. The flexible leads 29 and 30 prevent any stresses being transferred from the plug-in base to the unit after assembly.
If desired, a small capacitance can be connected across the unit to reduce any radio interference during break of circuit. However, for most applications the shunt effect of the resistor layer is adequate.
While the present invention, as to its objects and advantages, has been described herein as carried out 'in specific embodiments thereof, it
is not desired to be limited thereby but it is intended to cover the invention broadly within the spirit and scope of the appended claims.
What is claimed is:
1. An electrically operated thermostatic switch comprising a sheet of insulating material, an electric resistance strip on one face thereof and a metal strip secured to the opposite face thereof, means to make electrical connection to the ends of said resistance strip, and a pair of co-operating electric contacts controlled by said metal strip upon thermal expansion and contraction thereof, said contacts beingopen when said metal strip is cold and closed when it is heated and being connected to opposite ends of said resistance strip to short-circuit said resistance strip upon contact closure.
2. An electrically operated thermostatic fluorescent lamp starting switch comprising a sheet of insulating material, an electric resistance strip on one face thereof and a metal strip secured at its ends to the opposite face thereof, means to make electrical connection to the endsof said resistance strip, said metal strip being connected to one end of said resistance strip and having a first electric contact on its outer face at a point intermediate its ends, a second relatively stationary electric contact secured to the opposite end of said resistance strip and supported in cooperative relation to said first contact to short circuit said resistance upon thermal expansion of said metal strip.
3. An electrically operated thermostatic switch comprising a rectangular sheet of insulating material, a pair of metal channel supports clamping opposite edges of said sheet, a layer of resistance material diagonally on said sheet and connecting said supports, a metal strip riveted at its ends diagonally against the opposite face of said sheet substantially in register with said resistance layer and electrically connected to the first of said supports, said metal strip carrying a first contact at an intermediate point thereon, a second contact and means supporting said second contact in cooperating relation to said first contact and connecting said second contact to the second of said supports whereby to short-circuit said resistance upon thermal expansion of said metal strip.
4. A thermostatic switch comprising a layer of mica, a layer of metal of higher thermal expansion coeificient than said mica secured thereto in face-to-face contact therewith, and a pair of electric contacts controlled by said metal layer upon thermal expansion and contraction thereof.
5. A thermostatic switch comprising a layer of mica, a layer of metal of higher thermal expansion coefiicient than said mica riveted thereto in face-to-face contact therewith, and a pair of electric contacts controlled by said metal layer upon thermal expansion and contraction thereof.
6. An electrically operated thermostatic switch comprising a sheet of insulating material, an electric resistance layer on one fac thereof, a metal layer secured to the opposite face thereor whereby it may be readily heated by said electric resistance layer, and a pair of electric contacts controlled by said metal layer upon thermal expansion and contraction thereof.
SAMUEL RUBEN.
US382687A 1941-03-11 1941-03-11 Thermostatic switch Expired - Lifetime US2336504A (en)

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2920165A (en) * 1956-08-09 1960-01-05 Servel Inc Flasher switch mechanism
US2945933A (en) * 1957-11-14 1960-07-19 Cts Corp Electric circuit controlling device
US3105889A (en) * 1957-08-17 1963-10-01 Philips Corp Bimetallic starter switch for gas discharge tubes
US3272944A (en) * 1964-11-12 1966-09-13 Sylvania Electric Prod Encapsulated thermostatic switch having a heater disposed in the stem
US3546651A (en) * 1967-12-08 1970-12-08 Texas Instruments Inc Thermal time delay relay

Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US2920165A (en) * 1956-08-09 1960-01-05 Servel Inc Flasher switch mechanism
US3105889A (en) * 1957-08-17 1963-10-01 Philips Corp Bimetallic starter switch for gas discharge tubes
US2945933A (en) * 1957-11-14 1960-07-19 Cts Corp Electric circuit controlling device
US3272944A (en) * 1964-11-12 1966-09-13 Sylvania Electric Prod Encapsulated thermostatic switch having a heater disposed in the stem
US3546651A (en) * 1967-12-08 1970-12-08 Texas Instruments Inc Thermal time delay relay

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