EP4199650A1 - Infrared heater - Google Patents

Abstract

The invention relates to an infrared heater with a reflector body, which has a first and a second planar reflection section for arranging an infrared radiator in each case, and a reflector opening opposite the reflection sections. In order to provide an infrared heater that enables controlled heat radiation, it is provided that the reflection sections run in planes that are inclined to one another relative to a first longitudinal axis and that each run at different inclinations to an opening plane that is aligned parallel to the first longitudinal axis and is spanned by the reflector opening.

Description

• einen ersten und einen zweiten ebenen Reflexionsabschnitt zur Anordnung jeweils eines Infrarotstrahlers und
• eine den Reflexionsabschnitten gegenüberliegende Reflektoröffnung aufweist.

The invention relates to an infrared heater with a reflector body that

• first and second planar reflecting sections for arranging an infrared radiator, respectively, and
• has a reflector opening opposite the reflection sections.

Infrared heaters of the type mentioned above are known in a variety of configurations from the prior art and are used to heat living spaces, for example, by means of thermal radiation.

Infrared heaters with reflector bodies are also known from the prior art, which usually have two reflection sections which are designed to accommodate infrared radiators. In this case, the reflection sections are designed in such a way that infrared radiation from the associated infrared emitters is reflected and directed in a desired direction. This is of particular importance in order to emit the infrared radiation in a directed manner in order to achieve reliable heating of selected areas, for which purpose the infrared heater has a reflector opening opposite the reflection sections.

However, the known infrared heaters are only insufficiently suitable for emitting infrared radiation in a given spatial direction, so that only insufficient, in particular uneven, heating of living spaces or selected areas, for example, can be achieved or several infrared heaters are required to heat up a living space in the desired way heat.

Proceeding from this, the invention is based on the object of providing an infrared heater which enables heat radiation to be controlled as far as possible.

The present invention solves this problem with an infrared heater having the features of claim 1. Advantageous developments of the infrared heater are specified in the dependent claims.

It is characteristic of the infrared heater according to the invention that it has reflection sections which run in mutually inclined planes relative to a first longitudinal axis, which each run at different angles to an opening plane oriented parallel to the first longitudinal axis and spanned by the reflector opening.

Depending on the geometric configuration of the reflector body, the reflector opening has different cross sections. In the case of a, for example, hemispherical reflector body, the reflector opening can be circular, while in the case of a cuboid reflector body, the reflector opening can be rectangular. An opening plane is spanned by the reflector opening, which is arranged at a distance from the reflection sections and is aligned parallel to the first longitudinal axis.

According to the invention, the first and second reflection section each run in a first and second plane, these being inclined about the first longitudinal axis in such a way that the two planes are aligned inclined to one another. Within the scope of the invention, an alignment of the first and second planes is understood in which they enclose an angle of 120° to 178° opposite the opening plane. The angle between the first plane and the opening plane thus differs from the angle between the second plane and the opening plane. Thus, the first plane and second plane are inclined at different angles to the plane of the opening.

Infrared radiators are arranged on the first and second reflection sections, respectively. Due to the differently inclined configuration of the reflection sections, the infrared emitters are also aligned with different inclinations. The infrared radiation of the infrared emitters is partly emitted directly through the reflector opening and partly reflected by reflection on the reflection sections through the reflector opening. The divergence of the infrared radiation reflected by the reflection sections is determined by means of the angles between the first and second planes. The infrared radiation can thus be directed in a targeted manner.

The infrared heater according to the invention thus allows the infrared radiation to be radiated in a targeted manner due to the differently inclined reflection sections. By forming different angles, for example, a living space or certain areas can be heated precisely with thermal radiation.

Within the framework of the configuration according to the invention, the number and the specific orientation of the reflection sections can be freely selected. According to a preferred embodiment of the invention, however, at least a third and fourth reflection section is provided, which are each inclined to the opening plane with respect to a second longitudinal axis perpendicular to the first longitudinal axis. Due to the orientation of the second longitudinal axis at right angles to the first longitudinal axis, the third and fourth reflection section can thus deflect infrared radiation in a further direction. A radiation angle for heating can thus be determined particularly precisely. In the context of the invention, the emission angle designates the angle at which the infrared radiation is emitted from the plane of the opening.

The angle which the third and fourth reflection section has to the opening plane relative to the second longitudinal axis can in principle be freely selected. For example, the third and fourth reflection section can be oriented at different angles to the plane of the opening with respect to the second longitudinal axis. According to an advantageous embodiment of the invention, however, it is provided that the third and fourth reflection sections are inclined at symmetrical angles to the plane of the opening with respect to the second longitudinal axis. Symmetrical angles are angles that are equal. This arrangement enables heat to be radiated evenly in relation to the second longitudinal axis.

The infrared heating can, for example, be designed independently only as a reflector body with the necessary add-on parts such as the infrared radiators and the necessary supply lines. According to a preferred embodiment of the invention, it is provided that the reflector body is arranged in a housing having a housing opening and a housing rear wall. The reflector body can be arranged in the housing in such a way that the reflector opening is arranged in the direction of the housing opening. The housing rear wall can, for example, be designed in such a way that it has the shape of the reflector body in order to ensure a compact design. Further the rear wall of the housing can have recesses for cable feed-through. The housing can be made of heat-resistant plastic or metal, for example. Particularly preferably, the housing can be made of a thermally conductive material in order to prevent the infrared heater from overheating. The housing rear wall can have means to attach the housing to a wall.

According to an advantageous embodiment of the invention, it is provided that the reflector body is spaced apart from the rear wall of the housing. Thus, a cavity can be spanned between the reflector body and the rear wall of the housing. This cavity can be filled with insulating material, for example. Furthermore, cables from a power supply or control components for controlling the infrared radiators can also be arranged in the cavity.

According to a further preferred embodiment of the invention, a front panel is provided which covers the reflector opening and the housing opening of the housing which is advantageously provided. The front panel can include the housing at least in sections. Since the infrared emitters can also emit a small amount of visible light, a front panel on the housing opening protects the user from glare. Furthermore, a front panel offers good protection of the reflector body and the infrared radiator from external influences, which are also protected from being touched by a user, which can lead to injuries.

The way in which the front panel is designed is basically freely selectable. For example, the front panel can be designed as a continuous, infrared-transparent plastic body. According to a particularly advantageous embodiment of the invention, however, the front panel has at least one opening. On the one hand, this opening can be provided to prevent the infrared radiators from overheating. On the other hand, the opening ensures that the infrared rays emitted by the infrared heater can escape unhindered from the housing, which allows rapid heating of the targeted areas. The opening can also be filled with an infrared-permeable material, for example. The front panel can particularly preferably have openings in the form of perforations. Perforations can be in the form of small, spaced holes or slots, for example.

In order to increase the efficiency of the reflection section, a suitable coating can be applied to the reflection section, for example. According to a preferred embodiment of the invention, at least one reflection section, preferably all reflection sections, has a profiled reflection surface at least in sections. Here, the reflection surface can be formed, for example, grooved or wavy. This configuration of the reflection surface allows the divergence of the infrared radiation to be increased and the radiation angle to be increased.

The number of components for producing the reflector body can be selected as desired. For example, the reflector body can be in several pieces. According to an advantageous embodiment of the invention, the reflector body is designed in one piece, in particular as a sheet metal body. A one-piece reflector body has the advantage that there is no need to assemble the individual components, so that it can be manufactured in a few work steps, which leads to faster manufacture. In this case, the reflector body can be made of plastic, for example, with metallic inserts preferably being formed in sections in order to reflect the infrared radiation. So that plastic can reflect infrared radiation, the reflector body made of plastic can be coated, for example.

Particularly preferably, the reflector body can be formed from a metal that is easy to process, such as sheet metal. In order to form flat reflection sections, the sheet metal can be deep-drawn, for example, or formed from a flat sheet metal body by suitable folding processes. For this purpose, the sheet metal body for producing the reflector body can be stamped from a flat sheet metal and provided with folds and incisions in order to facilitate the bending processes for producing the reflector body. Furthermore, the reflector body can have a device for attachment to a wall.

A temperature sensor can be provided to monitor the operating temperature of the infrared heater. For example, the temperature sensor can be arranged in the living space to be heated. Alternatively or additionally, the temperature sensor can be provided in the housing at a distance from the reflector body. According to a particularly advantageous embodiment of the invention, at least one temperature sensor is on the reflector body arranged. The temperature sensor can thus monitor the operating temperature of the infrared heater to prevent overheating. Particularly preferably, two temperature sensors can be arranged as overheating protection. A control unit, which is connected to the temperature sensor, can be provided for monitoring and control. Particularly preferably, this control unit can have a module that enables wireless control.

• Fig. 1 eine Vorderansicht einer Infrarotheizung mit vier Infrarotstrahlern;
• Fig. 2 einen Querschnitt der in Fig. 1 gezeigten Infrarotheizung entlang einer zweiten Längsachse.

Embodiments of the invention are set forth below with reference to the drawings. However, these are not intended to restrict the invention, but only to explain it. In the drawings show:

• 1 a front view of an infrared heater with four infrared heaters;
• 2 a cross section of the in 1 shown infrared heating along a second longitudinal axis.

one inside 1 The embodiment of an infrared heater 1 shown in a front view has a reflector body 2 having four planar reflection sections 3a, 3b, 3c, 3d, four infrared radiators 5 being arranged on the four reflection sections 3a, 3b, 3c, 3d. The reflector body 2 is in this case formed in one piece from sheet metal. The reflection sections 3a, 3b, 3c, 3d have a profiled reflection surface (not shown here). Opposite the reflection sections 3a, 3b, 3c, 3d, the reflector body 2 has a reflector opening 4, with the reflector opening 4 spanning an opening plane OE.

The first reflection section 3a runs in a first plane E1, while the second reflection section 3b runs in a second plane E2, so that they run at an angle to one another (cf. 2 ). The first reflection section 3a, 3b in the first plane E1 and the second reflection section 3a, 3b in the second plane E2 are inclined at different angles relative to the opening plane OE to a first longitudinal axis LA1, with the first reflection section 3a being inclined at an angle of 150° to the opening plane and the second reflecting portion 3b is inclined at an angle of 164° to the opening plane. Thus, the infrared radiators 5 arranged at the first and second reflecting portions 3a, 3b are also appropriately inclined.

The third and fourth reflection sections 3c, 3d are inclined at symmetrical angles relative to the opening plane OE to a second longitudinal axis LA2 perpendicular to the first longitudinal axis LA1 (cf. 1 ).

The reflector body 2 is formed from a sheet metal body 15 stamped from a flat sheet metal (cf. 3 ). In this case, folds 13 and incisions 16 are provided in the flat sheet metal body 15 in order to produce the cup-shaped reflector body 2 by means of bends along the folds 13 . Furthermore, the reflector body 2 has cable openings 14 .

In order to protect the reflector body 2 from external influences, the reflector body 2 is arranged in a housing 6 (cf. 2 and 4 ). The housing 6 has a housing opening 7 and a rear wall 8 of the housing. The reflector body 2 is arranged at a distance from the housing rear wall 8, as a result of which a cavity 9 is formed between them. In the cavity 9 insulating material (not shown here) for insulation and a cable duct 12 are accommodated.

Furthermore, two temperature sensors are arranged on the reflector body 2 in order to monitor the operating temperature of the infrared heater 1 (not shown here).

In order to protect the reflector body 2 from external influences, a front panel 10 is arranged on the housing opening 7 of the housing 6 in order to cover the reflector opening 4 (cf. figure 5 ). The front panel 10 is made of metal and has openings in the form of perforations 11 to prevent the infrared heater 1 from overheating.

Reference List

1

infrared heating

2

reflector body

3a, 3b, 3c, 3d

reflection section

4

reflector opening

5

infrared heater

6

Housing

7

case opening

8th

rear panel

9

cavity

10

front panel

11

perforation

12

Cabel Canal

13

fold

14

cable opening

15

sheet metal body

16

incision

LA1

First longitudinal axis

LA2

Second longitudinal axis

OE

opening level

E1

First floor

E2

second level

Claims (10)

Infrared heater with a reflector body (2), the - A first and a second planar reflection section (3a, 3b) for the arrangement of an infrared radiator (5) and - a reflector opening (4) opposite the reflection sections (3a, 3b) having,
characterized in that
the reflection sections (3a, 3b) extend in planes (E1, E2) which are inclined to one another relative to a first longitudinal axis (LA1) and which are each inclined at different angles to an opening plane ( OE) run. Infrared heater according to Claim 1, characterized by at least a third and fourth reflection section (3c, 3d), which are each inclined to the plane of the opening relative to a second longitudinal axis (LA2) perpendicular to the first longitudinal axis (LA1). Infrared heater according to Claim 2, characterized in that the third and fourth reflection sections (3c, 3d) are inclined at symmetrical angles to the plane of the opening with respect to the second longitudinal axis (LA2). Infrared heater according to one of the preceding claims, characterized in that the reflector body (2) is arranged in a housing (6) having a housing opening (7) and a housing rear wall (8). Infrared heater according to Claim 4, characterized in that the reflector body (2) is at a distance from the rear wall (8) of the housing. Infrared heater according to Claim 4 or 5, characterized by a front panel (10) which covers the reflector opening (4) and the housing opening (7) of the housing (6). Infrared heater according to Claim 6, characterized in that the front panel (10) has at least one opening. Infrared heater according to one of the preceding claims, characterized in that at least one reflection section (3a, 3b, 3c, 3d), preferably all reflection sections (3a, 3b, 3c, 3d), at least in sections has a profiled reflection surface. Infrared heater according to one of the preceding claims, characterized in that the reflector body (2) is designed in one piece, in particular as a sheet metal body. Infrared heater according to one of the preceding claims, characterized in that at least one temperature sensor is arranged on the reflector body (2).

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