DE202007018419U1 - infrared Heaters - Google Patents

Abstract

Infrared heaters, in particular for installation in a wall, for simultaneous heat dissipation through Radiation and convection is formed, with radiant heat mainly in a preferred direction is issued and convection heat through Conversion of at least a part of the opposite to the preferred direction emitted radiant heat is produced.

Description

The The invention relates to an infrared radiator, in particular for installation in a wall, for example the wall of a sauna, heat treatment cabin or similar.

Known Infrared heaters generate almost exclusively radiant heat; the Air of the cabin heated only slightly. Users are often irritated when reading the low temperature on the thermometer. These known infrared radiators are to be improved so that they have a particularly service-friendly construction, revision and allow lamp replacement when installed, are safe to operate and ensure improved energy utilization.

Of the proposed infrared radiator meets these requirements, by allowing for simultaneous heat dissipation is formed by radiation and by convection, wherein in one Preferred direction mainly radiant heat is discharged and convection heat by converting at least part of it against the preferred direction emitted radiant heat is produced. The term "mainly" should be understood in this context be that the greater part, more than half, the radiant heat generated by the infrared radiation source in the Preferred direction is delivered, it is irrelevant whether radiant heat directly is emitted in the preferred direction or initially against the preferred direction sent out and then is deflected by reflection in the preferred direction.

By the conversion of radiated against the preferred direction radiant heat is the wall of the cabin, which is generally made of flammable materials, For example, wood, is protected from overheating. simultaneously the energy used to operate the infrared radiator gets better exploited by additional convection for the Cabin interior is provided.

For example can be provided that the infrared radiator one in a housing with a front cover and a rear wall arranged infrared radiation source and one for cooling the rear wall of the housing on the back wall arranged air duct comprises.

In a first embodiment is provided that the back wall an air duct forming double-walled is executed. The from the infrared radiation source Radiated heat emitted contrary to the preferred direction partially from the side facing the infrared radiation source the back wall of the housing reflected and partially absorbed, causing their temperature to rise. Between this side facing the infrared radiation source (inside) and the outside the back wall a cavity is provided which forms an air passage and through the accordingly air in to flow free convection or, for example by a blower or other suitable means, conducted in forced convection can be.

A other embodiment provides that the infrared radiation source between the front cover and one in the case provided reflector is arranged, wherein the reflector and the rear wall forming an air duct formed at a distance from each other are. In this case, the opposite from the infrared radiation source the preferred direction emitted radiant heat partially from the reflector reflected and partially absorbed, causing its temperature to rise. Between the reflector and the back wall a cavity is provided which forms an air passage and through which, as described above, air flow or can be performed.

It is appropriate if also for a pure cooling function not required, the air flowing through the air duct, the Cabins inside to take and after flowing through the air duct back in to lead the cabin interior. As a result, the convection heat contributes to Heating of the cabin interior at. In a simple embodiment can For this purpose, both ends of the air duct simply open into the cabin interior. optical more attractive, however, is a solution in which the front cover at least an air inlet opening in the air duct and at least one air outlet opening having the air channel. For example, for the air intake and the Air outlet in the front cover each have an array of slots or holes are provided.

The Front cover can be made in one piece of a suitable material, such as Glass or glass ceramic executed be. According to one Another embodiment provides that the front cover in several parts accomplished with a first part covering the front of the reflector, a second part has at least one air inlet opening and a third Part has at least one air outlet opening.

there The front cover can be completely or partially made of glass ceramic be. This results in a high strength and on the one hand Heat resistance, but also an aesthetic one visual appearance.

To improve the air flow in the air duct may further be provided that at least one flow guide is arranged in the air duct. The term of the flow guide should not to be construed as limited to a particular design or material, but include any means capable of affecting the direction of flow of the air within the air duct. These devices can be installed fixed or movably mounted.

Further can be provided that on or in the air duct continue at least a fan is arranged. Under a blower should be understood as any technical device that is suitable to generate an airflow. This device can be a constant or changeable, in particular adjustable air flow and in one embodiment be controlled or regulated, where the controlled variable is a in the interior of the infrared radiator, for example in the air duct, or outside, For example, inside an infrared cabin, measured temperature can be.

following The infrared radiator is based on embodiments and accompanying drawings explained in more detail. there demonstrate:

1 a perspective view of an infrared radiator,

2 a longitudinal section through the infrared radiator 1 .

3 an exploded view of another embodiment of the infrared radiator.

The infrared radiator according to 1 is designed for installation in the wall of an infrared cabin. For this purpose he has a housing 1 with a front cover 2 on. The housing 1 can be fitted into an opening of a cabin wall and through four tabs 3 be bolted to the cabin wall. At the back of the case 1 are electrical connections 5 arranged for the power supply of the infrared radiator.

The front cover 2 includes a first part 21 , which is made of glass ceramic and the arranged inside the infrared radiator infrared radiation source 7 covered. The glass ceramic pane 21 at the same time defines the preferred direction of the heat radiation of the infrared radiator. Next includes the front cover 2 a second part 22 with an arrangement of a plurality of air inlet openings 23 and a third part 24 with an arrangement of a plurality of air outlet openings 25 , In the embodiment, the second part 22 and the third part 24 the front cover 2 made of sheet metal and simultaneously form an end wall of the housing 1 ,

From the longitudinal section in 2 it will be apparent that the infrared radiation source 7 in two versions 4 which is supplied with power to the infrared radiator via the electrical connections 5 is supplied. The infrared radiation source 7 is between the first part 21 the front cover 2 and one inside the case 1 arranged reflector 6 arranged. As a result, the majority of the radiant heat generated directly or - after reflection at the reflector 6 - submitted indirectly in the preferred direction. However, part of the heat radiation emitted in the opposite direction is reflected by the reflector 6 absorbs and leads to its heating.

To the reflector 6 to cool, are the reflector 6 and the back wall 11 of the housing 1 arranged at a distance from each other so that the remaining cavity between them an air duct 8th forms. Air can through the second part 22 the front cover 2 provided air inlet openings 23 in the air duct 8th enter. The incoming air is through the heat of the reflector 6 also heated. As a result, an upward convective air flow forms, so that the heated air forms the housing 1 and the air duct 8th by the third part 24 the front cover 2 provided air outlet openings 25 leaves again. Because both the air inlets 23 as well as the air outlet openings 25 on the front cover 2 are arranged of the infrared radiator, the air in the infrared cabin is due to the heat exchange in the air duct 8th heated so that the energy used is better utilized.

Based on the exploded view in 3 the assembly of the infrared radiator is described. First, the infrared radiator with the rear wall 11 of the housing 1 fitted in a designated opening of the cabin wall and then four lugs 3 bolted to the cabin wall. The back wall 11 of the housing 1 carries the two versions 4 for the infrared radiation source 7 as well as the electrical connections 5 for the power supply. Then the reflector 6 used. A screw connection of the reflector 6 with the housing 1 is not necessary in this embodiment, since the fixation of the reflector 6 through the versions 4 and the inner contour of the body 1 he follows. Between the reflector 6 and the back wall 11 of the housing 1 remains a cavity that serves as an air channel 8th for a vertical, convective air flow for cooling the reflector 6 and simultaneously heating the passing air, with the air passing through the air inlets 23 in the air duct 8th into and through the air outlet openings 25 from the air duct 8th get out. Thereafter, the infrared radiation source 7 in the versions 4 be used. Now, in this embodiment, a divided glass ceramic plate is placed.

The two parts of the glass ceramic plate together form the first part 21 the front cover 2 that the infrared radiation source 7 covers, defines the preferred direction of heat radiation and at the same time serves as a light filter and contact protection. The holder of the two parts of the glass ceramic plate, ie the first part 21 the front cover 2 , is done by screwing on the bar 26 and the two ventilation plates 22 . 24 , of which the lower ventilation plate 22 the second part 22 the front cover 2 with the air inlets 23 and at the same time the lower end face of the housing 1 and the upper ventilation plate 24 the third part 24 the front cover 2 with the air outlet openings 25 and at the same time the upper end face of the housing 1 forms. The bridge provided between the two parts of the glass ceramic plate 26 can with continuous, ie one-piece glass ceramic plate 21 of course omitted. An advantage of the split design is that a possibly necessary change of the infrared radiation source 7 to do it with less effort. The ventilation sheets 22 . 24 as well as the jetty 26 be in the embodiment by means of fastening screws 27 on the housing 1 attached.

In practice, however, the infrared radiator expediently delivered completely assembled, on the back 11 electrically connected and mounted with four screws on the cabin wall.

1

casing

11

rear wall

2

front cover

21

first part

22

second Part, lower ventilation panel

23

Air inlet openings

24

third Part, upper ventilation panel

25

Air outlet openings

26

web

27

fixing screw

3

flap

4

version

5

Electrical connection

6

reflector

7

Infrared radiation source

8th

air duct

Claims (9)

Infrared radiator, in particular for installation in a Wall, for simultaneous heat dissipation through Radiation and convection is formed, with radiant heat mainly in a preferred direction is issued and convection heat through Conversion of at least a part of the opposite to the preferred direction emitted radiant heat is produced. Infrared radiator according to claim 1, comprising one in a housing ( 1 ) with a front cover ( 2 ) and a back wall ( 11 ) arranged infrared radiation source ( 7 ) and one for cooling the rear wall ( 11 ) of the housing ( 1 ) on the back wall ( 11 ) arranged air duct. Infrared radiator according to claim 2, characterized in that the rear wall ( 11 ) an air duct ( 8th ) is designed double-walled. Infrared radiator according to claim 2, characterized in that the infrared radiation source ( 7 ) between the front cover ( 2 ) and one in the housing ( 1 ) reflector ( 6 ) is arranged, wherein the reflector ( 6 ) and the back wall ( 11 ) an air duct ( 8th ) are arranged at a distance from each other. Infrared radiator according to one of the preceding claims, characterized in that the front cover ( 2 ) at least one air inlet opening ( 23 ) in the air duct ( 8th ) and at least one air outlet opening ( 24 ) from the air duct ( 8th ) having. Infrared radiator according to one of the preceding claims, characterized in that the front cover ( 2 ) is made in several parts, wherein a first part ( 21 ) the front of the reflector ( 6 ), a second part ( 22 ) at least one air inlet opening ( 23 ) and a third part ( 24 ) at least one air outlet opening ( 25 ) having. Infrared radiator according to one of the preceding claims, characterized in that the front cover ( 2 ) is made entirely or partially of glass ceramic. Infrared radiator according to one of the preceding claims, characterized in that in the air duct ( 8th ) Furthermore, at least one flow guide is arranged. Infrared radiator according to one of the preceding claims, characterized in that on or in the air duct ( 8th ) is further arranged at least one fan.