US2046233A

US2046233A - Electrical heater

Info

Publication number: US2046233A
Application number: US69177A
Authority: US
Inventors: Audain Raoul
Original assignee: WADE B HAMPTON
Current assignee: WADE B HAMPTON
Priority date: 1936-03-16
Filing date: 1936-03-16
Publication date: 1936-06-30
Anticipated expiration: 1953-06-30

Description

June 30, 1936. R AUDAIN 2,046,233

ELECTRICAL HEATER Filed MaICh 16, 1956 GUM/MMA Patented June 30, 1936 UNITED STATES ELECTRICAL HEATER Raoul Audain, Washington,

one-fifth to Wade B. Hampton,

D. C., assignor of Washingtom Application March 16, 1936, Serial No. 69,177

7 Claims.

This invention relates to electricalheaters and, among other objects, aims to provide an improved, relatively simple, highly eillcient and inexpensive type of electrical heater employing cathode rays instead of the usual resistance elements. The main idea is to provide a heater which can be manufactured as a compact unit and sold ata reasonable price to be used for heating or cooking and which has no electrical parts requiring re-v placement. l

Otheraims and advantages of the invention will appear in the specification, when considered in connection with the accompanying drawing, wherein:

Fig. l is a vertical sectional view of one embodiment of heater embodying the invention; and

Fig. 2 is a sectional view taken on the line 2-2 of Fig. 1.

Referring particularly to the drawing, the illustrated form of heater is designed to operate on .the same general principle as the commercial cathode ray tubes except that it employs an evacuated metal casing ,or shell adapted to radiate or transfer heat. In this example, the heater embodies a hollow supportor pedestal I0 made of porcelain or other suitable insulating material. It is shown as having an upstanding cylindrical flange Il providing a seat I2 to receive the base Il of the heater unit which is made of metal. On the metal base t3 there is shown a hollow cylindrical shell Il made of sheet metal and preferably welded around the base as shown to make an airtight joint. The construction is such that the shell and its base can be inserted in the seat in the pedestal.

Since the shell is made of sheet metal and is adapted to be evacuated to act as a cathode tube. itis highly desirable to prevent the infiltration of air through the metal when it is heated. It is therefore coated or plated with metal of a higher atomic number. It is preferably, though not necessarily, electroplated. Assuming that it is made of steel or bronze, it may be electro-plated with nickel or chromium, for example,gthe coating I5 being shown of an exaggerated thickness for the sake of illustration.

The air is adapted to be evacuatedor exhausted from the shell through a valved nipple I6 conveniently projecting from the base I3 into the hollow pedestal l0 and the pedestal is shown as having a lateral opening through which an exhausting tube or pipe (not shown) may be lnserted and connected to the nipple.

The illustrated design of heater is adapted to operate on direct current, although it is to be understood that slight changes may be made to adapt it to operate on alternating current. In this example, one conductor I1 leading from a cable' I8 projecting through an opening I9 in the pedestal is electrically connected to a conductor in the form of a rod 20 carrying a cup-shaped cathode 2| in the form ot a parabolic reflector preferably arranged on the axis of the shell within a short distance of the top. The cathode conductor 2li is shown as being imbedded in an insulating bushing 22 which is preferably molded thereon and is tapered toward its upper end. This bushing is inserted in a tapered opening 23 extending through the center of the base. It is held firmly seated in said opening by means a packing gland 24 and a suitable packing 25. The construction is such that the joint is always maintained airtight to prevent infiltration of air through it to destroy the vacuum in the shell. The other conductor 26 is shown` as being electrically connected to the base I3 so that the circuit is completed through the cathode and the shell through the base.

In this instance, the cathode cooperates with an anti-cathode plate 21 conveniently made in the form of a disk in contact with vthe upper wall of the shell. While this anti-cathode may be made of any suitable metal having a high fusion point, it is preferably made of an alloy which, for example, is composed of copper, nickel and tin. These metals may be melted together in suitable proportions and cast to form the plate. However, it is sometimes convenient to make the plates of metal powder by what is known as the cold process. In the latter example, the powder of the metals in the proper proportion may be formed into a paste by the addition of mercury and the paste molded under pressure into the proper form. As an example of an alloy composed of theabove metals, I prefer to employ approximately 30% by weight of nickel, 50%v by weight of copper and 20% by weight of tin. all in the form of a metal powder or ne particles. This is converted into a paste by adding mercury. To increase the fusion point and the hardness of the plate, a minute quantity of beryllium is added to the batch.

Referring to Fig. l, the anti-cathode plate isA shown as having a central opening and is secured centrally to the upper wall of the shell by means of a screw 2B having a conical head 29 which constitutes the anode. The conical head is arranged axially of the casing and points directly into the cup-shaped cathode, it being understood that the conical head delivers ions into the cathode which anode and the bottom of the cathode reflector` should be approximately the same as the diameter of the cathode reflector. It is contemplated that the heater may be operated at various voltages and that the current consumed will be dependent upon the mass and the ultimate temperature required. It was found desirable to evacuate as much air as possible lfrom the shell and that the heater worked more efficiently by introducing a very minute quantity of conductive gas. such as neon.

Obviously, the present invention is not restricted to the particular embodiment thereof herein shown and described. Moreover, it is not indispensable that all the features of the invention be used conjointly, since it may be employed advantageously in various combinations and sub.

combinations.

What is claimed is: y l. A portable cathode ray heater comprising,

in combination, an evacuated metal casing; a

concave reflector-shaped cathode within the casing; an anti-cathode plate secured in heat transferring relationto a wall of the casing opposite the cathode so that the cathode rays bombard substantially the entire inner surface thereof; and a relatively small anode on the inner face of said plate directlyopposite the cathode.

2. A cathode ray heater comprising, in combination, an evacuated substantially vertical, cylin` drical, metal casing; a base supporting saidcasing; a concave cathode arranged axially ofthe casing and directed toward the upper wall there` of; a disk-shaped anti-cathode plate secured in heat transferring relation to the upper wall of the casing opposite the cathode; a pointed anode in the center of the said anti-cathode plate directly^ opposite the cathode; and electrical conductors connected to the cathode and the casing.

3. In ar cathode ray heater of the character described, an evacuated metal casing; `a concave cathode within the casing directed toward a wall and connected thereto the cathode.

, of the cathode s,

thereof; a thin anti-cathode plate arranged in heat transferring relation to the said wally of the casing; and a relatively small, pointed anode of different material from said anti-cathode plate to discharge directly into 4. A portable cathode ray heater of the character described comprising, in combination, a vertical, `evacuated metal casing; a hollow base of insulating material supporting said casing; a conductor projecting from the inside oi the base into the casing and electrically insulated therefrom; 'a cup-shaped cathode on the upper end of said conductor directed toward the upper wall of said casing; an anti-cathode plate in heat transferring relation to the upper wall of the casing; and a substantially conical anode secured centrally to said plate and arranged directly opposite the bottom of said cup-shaped cathode.

5. A cathode ray heater comprising, in combination, an airtight metal casing; a cupped cathode within the casing spaced from and directed toward one wall thereof; and a thin anti-cathode plate having a higher fusion point than said casing and secured in heat transferring relation to said wall opposite the cupped cathode and so arranged that the cathode rays bombard substantially the entire inner surface thereof.

6. A cathode ray heater of the character described comprising, in combination, an evacuated casing having a substantially at wall; a concave cathode positioned within the casing and directed toward the central portion of said flat wall: a

disk-shaped anti-cathode plate secured in heat transferring relation to the inside face of said fiat wall and of a diameter considerably greater than the diameter of said cathode; and a pointed anode secured to the center of said plate and pointing toward the center of the cathode and spaced therefrom a distance substantially equal to the diameter of the cathode.

7. In a cathode ray heater of the character described, a closed casing; a concave cathode within the casing; a disk-shaped anti-cathode plate secured in heat transferring relation to one wall of the casing and of a diameter substantially four times that of the cathode; an anode arranged approximately in the center of said plate and directed toward the bottom of said cathode, the tip of said anode distance substantially equal to the diameter of the cathode.

RAOUL AUDAIN.

being spaced from the bottom