NO814166L - MODULAR, INFRARED SPACE HEATER. - Google Patents

Description

Infrared radiation heaters have been known for many years

years, but a permanent problem with these is their inefficiency. Known technology includes patent document 3,180,972 which deals with

a side table heater comprising a fan, lamps, plates and conductor rods over which air is kept in circulation. Patent document 3,575,582 mentions an electric oven with lamps, fan unit and metal cylinder which is installed in a cabinet structure, where a current of air, under the influence of the fan, circulates through and around the cylinder, to absorb heat developed by the lamps and concentrated in the unit of galvanized metal, for producing heated air which flows out through grids at the upper end of the heater. Other, known technology is described in US patents 2,520,830, 2,938,101, 3,104,307, 1,534,571, 2,527,013, 2,919,338, 1,694,351 and 2,888,007, which deal with windows for letting in solar radiation. The purpose of the present invention is to achieve an improvement in efficiency compared to the above systems.

It is an object of the present invention to produce a unique and highly efficient electric heater.

Another object of the invention is to produce a simple, but highly efficient, infrared radiation space heater.

Another object of the invention is to produce an electric heater in which air circulates over and around lamps as well as over and through ferrous wires.

Another object of the invention is to produce an electric space heater which includes a cubicle in which infrared lamps, a reflector, a fan, a refractive lens and ferrous metal lines are arranged, and through which an air current driven by the fan circulates.

Another object of the invention is to produce a modular electric heater with a compartment which houses a fan, infrared lamps, reflector, refracting lens and ferrous wires near the lens, where air is drawn into the compartment by means of a fan, and circulates past the lamps around the lens as well as through and around the wires, and is blown out of the cubicle as heated air, and where said cubicle can be adapted for installation in furniture, so-

as side tables, extra tables and other home furniture.

Another purpose of the invention is to produce a modular space heater with a continuous path for circulating air, which will provide maximum heat transfer to the circulating air.

Another object of the invention is to produce a modular infrared space heater with a continuous path for circulating air, which will provide maximum heat transfer to the circulating air.

A further object of the invention is to produce an infrared radiation space heater which comprises a fan, infrared lamps, refractive lens and ferrous wires, and which is suitable for use in outer houses which can be stacked on top of each other, to provide additional heating. Fig. 1 shows a horizontal section along the line 1-1 in fig. 2 of a modular heater according to the invention. Fig. 2 shows a vertical section along line 2-2 in fig. 1. Fig. 3 shows a perspective view of the modular heater according to the invention. Fig. 4 shows an enlarged partial section along the line 4-4 in fig. 1. Fig. 5 shows an enlarged partial section along the line 5-5 in fig. 1. Fig. 6 shows an enlarged partial section along the line 6-6 in fig. 1. Fig. 7 shows a view of the modular. heater

exhaust end.

Fig. 8 shows a connection diagram for the circuit used in the modular heater.

Fig. 9 shows a partial section along the line 9-9 in fig. 6.

Reference is made to the drawings in which similar parts are denoted by the same reference number and in which a modular heating system according to the invention is generally denoted by reference number 10. The heating system is enclosed in a solid, rectangular metal outer housing 12 which is shown in perspective in fig. 3

and which can be dimensioned with a height of approx. 30.5 cm, length approx.

61 cm and width approx. 38 cm. The size of the outer housing 12 can of course be increased or decreased, without deviating from the basic idea of the invention

or idea. As can be seen from fig. 1 and 2, there is arranged at one end of the outer housing 12 an enclosed fan 22 of the short circuit type which is driven by an electric motor 2 2a and which is manufactured for the commercial market by Fasco Industries Ozark, Missouri or by Emerson Electric Company, St. Louis, Missouri. A typical electric motor for the fan unit develops a fraction of a horsepower, and the fan has a capacity of approx. 3.4 m^ per minute. The fan unit 22 is placed between one end of the outer housing 12 and a metal plate 26, as can be seen from fig. 1 and 2. The plate 26 forms one end of a cubicle 27 of rectangular box shape which delimits a heating chamber 30 which comprises an upper part 14, a lower part 15, sides 18 and an opposite end 16. The cubicle 27 is placed in its entirety inside the outer housing 12 and is suspended for safety reasons with at least 2.5 cm clearance to the outer housing 12 on all sides. The heating chamber 30, which is formed by the cubicle 27, is suspended in relation to the outer housing 12 by means of intermediate struts (not shown). The fan unit 22 is mounted on the metal plate 26 in such a way that the exhaust flow is led through an opening 28 into the heating chamber 30. Electric lamp sockets or holders 32 are arranged in the heating chamber 30 and are mounted on the plate 26 on both sides of the opening 28. The lamp sockets 32 are made of the commercially available type which is provided with internal threads to more easily accommodate the threaded sockets of infrared lamps 34. The lamps 34 supplied by the Sylvania Company, the General Electric Company or the Westinghouse Company are preferably 250 or 375 W, although also, without deviating from the basic idea of the invention, lamps of a different wattage can be used. A reflector 36 is placed across the heating chamber 30 in such a way that it is in unbroken contact with the lower part 15 and the sides 18 of the chamber 30, but is separated from the upper part 14, as shown in fig. 2, so that air can pass over the reflector. The reflector 36 includes through openings 38 through which the lamps are introduced within the assembly in the lamp holders 32.

A heat-set refractive lens 39 is, as shown in Fig* 1

and 2, arranged in unbroken contact with and at right angles to the sides 18 and the top 14 of the heating chamber 30. The lens 39

is placed at a distance from the heating chamber bottom 15, as shown in fig. 2, allowing air to pass under the lens. As most clearly shown in fig. 4, the lens comprises 39 rows of circular or convex

surface parts 40 which project towards the lamps 34. The lens 39 is, as previously mentioned, a heat-hardened refractive lens which is made of commercially available glass and can, for example, be without. thereby being limited, be made of Corning Glass No. 7760. The lens 39 has the function of concentrating the infrared radiation from the lamps 34 on an iron plate 42 and iron-containing wires 44, as described in the following.

The iron plate is mounted in unbroken contact with and at right angles to the sides 18 and the bottom 15, and with spaces against the upper part 14 so that air can flow over the plate. A series of wires 44 of ferrous metal are welded or otherwise simply mounted to the plate 42, at right angles thereto. The number of wires 44 corresponds to the number of "bubbles" 40 in the lens 39, and the wires are arranged in line with the lens bubbles, so that the radiation transmitted through each "bubble" in the lens 39 is concentrated towards the nearest end of the associated wire 44. The plate 42 includes round window devices 46 which are shown

in fig. 5, and whose number corresponds to the number of "bubbles" 40 in the lens 39 and the number of wires 44. Each window device coincides, on one side of the plate 42, with the opening for the associated wire 44. Each wire is thus welded or otherwise fixed with one end around the periphery of the associated window device in such a way that air passing through the window devices 46 in the plate 42 is led directly into the associated lines 44.

The unsupported ends of the wires 44 extend through window devices 48, as shown in fig. 6, in the plate 16, for exhaust immediately in front of a grid 50 in the end wall of the outer housing 12. The diameter of the window devices 48 in the plate 16 is somewhat larger than the outer diameter of the wires 44. The wires 44 consequently pass through the plate 16 without touching it, and with sufficient clearance so that air will be able to flow through the window devices 48 in the plate 16 around the outside of the wires 44. The wires 44 are shown bent, whereby the heat exchange surface over and through which the air flows is increased, but the wires 44 could of course run in a straight line or be extended in some other way, if desirable.

As shown in fig. 3, a ventilation grid opening 24 is arranged at the fan assembly 22 for the intake of air, as can be seen from fig. 1 and 2.

The circuit diagram of the invention is shown in fig. 8,

and comprises a conventional alternating current source 60 which is connected in series with a conventional thermostat 66 and a relay coil 62

with associated contacts 64. When the contacts 64 are closed, the fan motor 22a and the lamps 34 are connected across the source 60. The parallel combination of lamps and fan motor is connected in series with a commercially available, 78°C reversible switch 68, e.g. a model L 140-2 from Texas Instruments, and an 89°C time burnout switch 70, e.g. model RD 070-002 manufactured by the Minnesota Mining and Manufactoring Company.

The necessary voltage for the thermostat 66 can, through a step-down transformer not shown, be supplied from the source 60 or from another power source.

Since the outer housings 12 are constructed in such a way that they can be stacked on top of each other in order to more easily achieve a greater heating capacity if needed, an opening (not shown) is arranged in 12 and in one of the sides, to facilitate the replacement of lamps 34.

The size of the unit can of course be varied, so that it includes more or fewer lamps, fans, lenses and wires, without thereby deviating from the basic idea of the invention.

The cable dimensions can of course vary, but iron-containing cables of dimension 6.35 mm have in practice been shown to function satisfactorily. Although the wires 44, as previously mentioned, are shown bent at an angle, they may also be arranged in a loop or coil form, or bent as a series of Wer, to

increase the heat transfer surface and still remain within the framework of the invention.

The outer housing's 12 shape can be changed, and the housing can e.g.

have the shape of a cylinder or cube, and be fitted into furniture, such as side tables, extra tables, chests of drawers or chests of drawers or other arbitrary furniture of sufficient size to meet the physical and thermal requirements. Of course, the outer housing 12 can also be mounted in walls or floors, provided that the requirements for adequate air flow and insulation are met.

The preceding description is to be considered exclusively as

illustrative of the principles of the invention. Modifications other than those mentioned above will be obvious to the person skilled in the art. The invention is therefore not intended to be limited to the exact construction and/or mode of operation shown in the figures and description. Mon

can, on the contrary, utilize all equivalents and modifications that fall within the scope of the patent-applied invention.

When the thermostat switch 6 6 is closed by the temperature at the point of use falling to a preselected value, the coil 62 is activated and closes the contacts 64. When the contacts are closed, the lamps 34 and the fan motor 22a are activated. When activated, the fan assembly 22 will suck air through the valve-grid inlet 24 and into the outer housing 12. Air is then sucked into the axial inlet in 22, as shown by arrows in fig. 1, and is blown out through the opening 28 into the heating chamber 30. In the chamber 30, the air flows up past the bases and necks of the lamps 34 and above the reflector 36, as shown in fig. 2. The air then flows down over the bulb ends of the lamps 34 and further under the lens 39 towards the iron plate 42. Part of the air is then passed through the window devices 46 in the plate 4 2 and into the wires 44. Part of the air passes over the end of the plate 42 (between plate 42 upper edge and upper part 14), and some air is allowed to flow into the space between 42 and 16, through an adjustable opening 43 in 42 near the bottom 15, for regulation of the air flowing over the outer sides of the wires 44 and through the window devices 48

in 16. The air is heated as it passes through and over the wires 44 and is blown out through the grid 50 in the housing 12 to the room in which the unit is used. When the room temperature has risen sufficiently for the thermostat 66 to open, thereby tripping the relay 62 and opening the contacts 64, the lamps 34 and the fan motor 22a will be switched off. The process is repeated when the room temperature drops where the unit is in use. The refracting lens 39

has the task of increasing the air temperature as much as possible in the chamber 30, by concentrating the infrared rays from the lamps 34 towards the plate 42 and the ends of the wires 44 which are closest to the lens 39. When the iron-containing wires and the plate 42 are heated by the infrared field, the air circulating above will absorb heat which is carried through the channel 50 into the room. The circulating air flow will naturally absorb a certain amount of heat from the iron plates 26, 18, 15, 14 and 16, in addition to the heat from 42 and 44.

Claims (10)

1. Infrared radiation medical device, characterized in that it comprises a compartment with an air inlet and an air outlet, a source of infrared radiation which is mounted in the compartment, a number of wires of ferrous metal with open ends, which are placed in the compartment between the source of infrared radiation and the air outlet and close to the infrared radiation source, to be irradiated by this, the metal wires being mounted on an iron plate at one end of the wires, and otherwise not supported, a refracting lens device which is placed in the compartment between the infrared radiation source and the metal wires and which consists of a glass plate with a number of convex surface parts which are individually connected to a separate metal wire, so that the center of each convex surface part is in line with the axial center of the corresponding metal wire, thereby concentrating the radiation from the infrared source towards the associated metal line, and a fan device for creating air circulation through the cubicle, from the air inlet to the air outlet, so that the air circulating through the cubicle will flow through and around the metal lines and thereby absorb heat from them. 2. Heater in accordance with claim 1, characterized in that the metal wires have a round cross-sectional shape. 3. Heater in accordance with claim 1, characterized in that the infrared radiation source includes at least one infrared lamp. 4. Heater in accordance with claim 1, characterized in that the other end of the metal lines extends from the inside of the cubicle to the outside of the cubicle's walls, through the air outlet, without being in direct contact with the cubicle. 5. Heater in accordance with claim 1, characterized in that window devices are arranged in the iron plate, and that the plate is placed between the refractive lens device and the metal wires, whereby the aforementioned one end of each metal wire is mounted on the plate and thereby coincides with one of the window devices in the plate. 6. Infrared radiation heater, characterized in that it comprises a cubicle with an air inlet and an air outlet, a source of infrared radiation which is mounted in the cubicle, a number of wires of ferrous metal with open ends, which are placed in the cubicle between the infrared radiation source and the air outlet and close to the infrared radiation source, to be irradiated by this, the metal wires being mounted on an iron plate at one end of the metal wires, and otherwise not supported, a refracting lens device which is placed in the compartment between the infrared radiation source and the metal wires and which consists of a glass plate which is equipped with a number of convex surface parts on the side facing the infrared radiation source, for concentrating radiation from the infrared radiation source towards the metal wires, where the metal wires and the convex surface parts are arranged in mutually corresponding numbers and positioned so that the center of each convex surface part is connected and located in line with the middle - the axis at the end of a separate metal line, whereby the radiation from the infrared radiation source, which passes through a single one of the convex surface parts, is directed towards an associated metal line, as well as a fan device for creating air circulation through the cubicle, from the air inlet to the air outlet, so that the air circulating through the cubicle flows through and around the metal wires and thereby absorbs heat from them. 7. Heater in accordance with claim 6, characterized in that the metal wires have a round cross-sectional shape. 8. Heater in accordance with claim 6, characterized in that the infrared radiation source includes at least one infrared lamp. 9. Heater in accordance with claim 6, characterized by the other end of the metal lines running from the inside of the cubicle to the outside of the cubicle walls, through the air outlet, without being in direct contact with the cubicle. 10. Heater in accordance with claim 6, characterized in that window devices are arranged in the iron plate, and that the plate is placed between the refractive lens device and the metal wires, whereby one end of each of the metal wires is mounted on the plate and thereby coincides with one of the window devices in the plate .