LOW EMF HALOGEN TUBE HEATER

Abstract

Sauna heaters are used to generate heat for saunas. Sauna heaters include a first halogen tube configured to generate heat, a second halogen tube configured to generate heat, wherein the first halogen tube is implemented a distance from the second halogen, and wherein the distance between the first halogen tube and the second halogen tube is configurable to adjust an amount of electromagnetic field (EMF) emitted by the heater. Sauna heaters also include a source of alternating current electrically coupled to the first halogen tube and the second halogen tube such that the source of alternating current is configured to provide the first halogen tube and the second halogen tube with a current, wherein the current powering the first halogen tube is out of phase with the current powering the second halogen tube.

Description

BACKGROUND

Field of the Invention

The present invention relates generally to heaters, and more particularly to halogen-tube heaters for saunas that emit no or minimal EMF.

Background of the Invention

Halogen tube heaters are widely used in saunas, as they provide a good amount of therapeutic heat while being inexpensive, compact, and having low power consumption. However, one drawback of such heaters is that they emit a high electromagnetic field (EMF).

Electromagnetic waves are generated wherever electricity flows. There has been a suggestion that electromagnetic waves induce anxiety in humans and are harmful to general health. Since sauna heating elements are typically used at close range, electromagnetic emissions are a serious concern.

While a metal enclosure (or an enclosure made of another conductive material) can shield the user from electromagnetic waves, such an enclosure would severely lower the heat-generating efficiency of a heating element, which renders it impractical.

A need therefore exists for a halogen tube heater that does not emit a high amount of EMF.

LIST OF FIGURES

FIG. 1 shows an embodiment of the present invention.

FIG. 2 shows an alternate embodiment of the present invention.

FIG. 3 shows an alternate embodiment of the present invention.

FIG. 4 shows an alternate embodiment of the present invention.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a cheap and simple halogen heater for a sauna that emits low or minimal EMF.

The present invention comprises a heater for a sauna, wherein the heater comprises a first halogen tube and a second halogen tube, both powered by alternating current, where the current powering the first halogen tube is opposite in phase from the current powering the second halogen tube. The distance between the halogen tubes is less than 4 inches, and they are parallel to each other. The tubes are identical in size and power output.

In an embodiment, the tubes are wired together as follows. Each tube comprises a first end and a second end. The first end of the first tube is wired up to a source of alternating current. The second end of the first tube is connected to the second end of the second tube. The first end of the second tube is wired up to the source of alternating current. This way, the current going through the second tube is opposite in phase from the current going through the first tube.

In an embodiment, the tubes are wired as follows. The first end of the first tube and the second end of the second tube are wired up to one pole of the source of alternating current, and the second end of the first tube and the first end of the second tube are wired up to the other pole. This way, the current going through the second tube is opposite in phase from the current going through the first tube.

The halogen tubes are preferably touching each other for maximum cancellation of EMF.

In the preferred embodiment, the heater assembly comprises a reflector for reflecting the heat in a desired direction.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

FIG. 1 shows an embodiment of the present invention. Halogen tubes 100 and 110 are wired up to current source 120 as shown in the Figure, connected in series. The ends of the halogen tubes are wired together as shown in the Figure; in the embodiment shown in the Figure, the two wires are twisted together 130 and a wire cap 140 is placed on the twisted ends to insulate the connection. Thus, the current going through the first halogen tube 100 is opposite in phase from the current going through the second halogen tube 110, and the EMF emitted by the first halogen tube 100 is also opposite in phase from the EMF emitted by the second halogen tube 110. If the halogen tubes are identical and placed very close together, that means that the EMF emitted by the two tubes will be cancelled out, resulting in minimal EMF emissions for the whole assembly.

FIG. 2 shows an alternate embodiment of the connection between the two halogen tubes. Rather than a twist connection like the one shown in FIG. 1, a single wire 200 could be used to wire the two ends together.

FIG. 3 shows an alternate embodiment of the present invention. In that embodiment, both halogen tubes are connected in parallel to the source of alternating current 120. However, tube 100 is connected to the source of alternating current in one direction and tube 110 is connected in the other direction. This way, the current is still in opposite phases in the two tubes.

The distance between the tubes in this embodiment, as shown in the figure, is 2″-4″. At that distance, the total EMF emitted by the assembly is 20-30 mG. In the preferred embodiment, however, the tubes are touching or nearly touching. When the tubes are touching, the total EMF emitted by the assembly is around 1-5 mG, as shown in FIG. 4.

The tubes are preferably attached to a mounting fixture in such a way as to keep them at the proper distance and the proper relative position to each other. The attachment may be permanent or temporary. In an embodiment, the distance between the halogen tubes may be adjustable to “tune” the amount of EMF emitted by the tubes.

The heater assembly preferably also comprises a reflector to reflect all the heat in the desired direction. The reflector may be a parabolic reflector or any other shape of reflector typically used in a sauna for halogen heaters.

The heater assembly may also comprise electrical shielding to block any remaining EMF from reaching the user. The shielding is preferably metal mesh that does not unduly block heat.

Exemplary embodiments are described above. It will be understood that the present invention comprises other embodiments, and that the invention is only limited by the appended claims.

Claims

1. A sauna comprising: a seating area;a first heating element configured to generate heat; anda second heating element configured to generate heat, wherein the first heating element is separated from the second heating element at a specifically configured distance to reduce a sauna electromagnetic field (EMF) towards the seating area to be lower than a designated threshold, wherein a second heating element EMF emitted by the second heating element cancels at least some of a first heating element EMF emitted by the first heating element, the sauna EMF including the first heating element EMF and the second heating element EMF;wherein an alternating current powering the first heating element is out of phase with the alternating current powering the second heating element.

2. The sauna of claim 1, wherein a first heating element first terminal is connected to line associated with a source of alternating current.

3. The sauna of claim 2, wherein a first heating element second terminal is connected to a second heating element first terminal.

4. The sauna of claim 3, wherein a second heating element second terminal is connected to neutral associated with the source of alternating current.

5. The sauna of claim 4, wherein the first heating element is the same length and power as the second heating element.

6. The sauna of claim 5, wherein the first heating element and the second heating element are substantially parallel.

7. The sauna of claim 6, wherein the first heating element first terminal is aligned with the second heating element second terminal.

8. The sauna of claim 7, wherein the first heating element second terminal is aligned with the second heating element first terminal.

9. The sauna of claim 8, wherein the first heating element and the second heating element are halogen tube heaters.

10. The sauna of claim 1, wherein the designated threshold is between 20-30 mG.

11. The sauna of claim 1, wherein the first heating element and the second heating element are separated by a distance of 0.

12. The sauna of claim 11, wherein the designated threshold is between 1-5 mG.

13. The sauna of claim 12, wherein the distance is adjustable to allow tuning of the sauna.

14. An apparatus comprising: a first heating element configured to generate heat; anda second heating element configured to generate heat, wherein the first heating element is separated from the second heating element at a specifically configured distance to reduce a apparatus electromagnetic field (EMF) towards a seating area to be lower than a designated threshold, wherein a second heating element EMF emitted by the second heating element cancels at least some of a first heating element EMF emitted by the first heating element, the apparatus EMF including the first heating element EMF and the second heating element EMF;wherein an alternating current powering the first heating element is out of phase with the alternating current powering the second heating element.

15. The apparatus of claim 14, wherein a second heating element second terminal is connected to neutral associated with the source of alternating current.

16. The apparatus of claim 15, wherein the first heating element is the same length and power as the second heating element.

17. The apparatus of claim 14, wherein the designated threshold is between 20-30 mG.

18. The apparatus of claim 14, wherein the first heating element and the second heating element are separated by a distance of 0.

19. The apparatus of claim 18. wherein the designated threshold is between 1-5 mG.

20. The apparatus of claim 19. wherein the distance is adjustable to allow tuning of the apparatus.