The invention concerns a gas powered burner, emitting substantially IR-radiation, with perforated ceramic elements which are adjustable in and/or perpendicular to their planes.

IR-technology is used nowadays in many different areas. Common weaknesses of existing gas powered constructions are:

1. Sensitivity to position. Existing constructions function adequately as long as they are horizontally mounted (radiating upwards or downwards) . In vertical arrangements, due to the heat rising, the burner is warmer at the top than at the bottom, whereby the infra-red radiation becomes non-uniform. This results in it being impossible to set the desired wavelength on the infra-red emitter.

2. Difficulties to obtain an even high intensity at the same time as being able to adapt the wavelength in the infra-red spectrum to differing areas of application.

3. Inadequate efficiency. When the gas pressure and thereby the through-flow speed for the gas increases, the flames try to separate from the burner with the result that the heat emission to the infra-red radiating element reduces. The result is that convection heat increases and the infra-red radiation decreases.

With the invention, a gas powered burner has been achieved for emitting infra-red radiation. Due to the possibilities of adjustment of the infra-red radiating burner element, the burner is relatively insensitive to placement or position.

The burner element is intended to emit radiation within the infra-red spectrum, containing energy of sufficient intensity for industrial use such as for instance heating up solid or liquid material, drying of organic or inorganic material as well as hardening of, for example, paints or glue in so-called infra-red chambers or the like.

The invention can also advantageously be used for grills for grilling of food products since it can be placed vertically and thereby can give an odour-free cooking of the raw products requiring most heat.

The construction of the burner according to the present invention is intended for all types of flammable gas. It is built up from two or more perforated plates or fire proof ceramic material. By displacing the two plates closest to the back part and which lie in contact with each other, symmetrical or asymmetrical hole patterns and hole geometries can be set up. This permits the gases which flow through the plates to be able to be directed in different directions. In addition to this, the construction allows the hole width to be able to be adjusted uniformly or asymmetrically in a continual throttling of the gas supply from one edge to the other. The construction of the burner permits the combustion chambers in and between the perforated ceramic plates, in principal, to be adjusted during operation. This means that the drawbacks, which results in i.a. uneven combustion and difficulties to keep all the emitted radiation within the desired wave-length in the infra-red spectrum, which occur when known gas powered infra-red radiators are placed vertically, can be removed via adjustment with this invention.

By placing one or more ceramic plates, perforated with holes, outside and at a suitable distance from the inner plate combination, a combustion chamber is achieved. This

combustion chamber can be closed or provided with throttle valves for supply air. Should one use supply air to the chamber, automatic ignition and cut-out should be placed here. The supply air can occur passively or actively by the use of fans. It is mainly this outer plate or plate combination which constitutes the infra-red radiating element in the burner. By using two or more plates it is possible to achieve slanted or curved through-bore geometries. This means that the length of the through-bore which is created increases in relation to perpendicular holes whilst using the same thickness of burner element. This in turn implies that the heat absorbing surface on the infra-red radiating element increase with respect to if it was perforated by holes arranged are right angles. This relationship increases the efficiency.

The clay material included in the ceramic elements can be chosen such that the infra-red wavelength band is emitted at different temperatures. By a careful choice of ceramic material, the intensity within each wavelength can be controlled. The ceramic burner elements can be manufactured in plane or curved shapes and can be pressed or cast in different sizes.

A vertically placed gas powered infra-red radiator, as previously mentioned, always tends to be warmer at the top than at the bottom. To counteract this, the gas outlet can be directed downwardly and/or throttled successively from the lower outlet to the upper. In this manner a uniformity in the combustion and thereby the temperature can be maintained over the burner elements whole surface independently of the placing and the position of the burner. Additional, perforated plates can be added, the ceramic composition and the structure of which can be varied.

The burners according to the present invention are couplable together to large infra-red radiation units which, due to the burners' adjustability, can be constructed in many diff rent ways. The burners can be put together in a laying or standing circle or respectively a half-circle shape and can even form complete radiation walls where each separate burner, independently of the placing in the group, can be optimized with regard to the wavelength and intensity emitted.

The invention can be illustrated by the burners being placed in a grill for grilling of food products, the resultant grill being particularly simple to maintain and which gives a very good grilling result for many different types of raw products. The characteristics of the burner according to the invention are defined in the appended claims.

The invention shall now be described in more detail with reference to the accompanying drawings, in which

Fig. 1 shows a vertical section through a part of the burner according to the invention.

Fig. 2 shows the burner in Fig. 1 in an exploded view seen from the front.

Fig. 3 shows the burner according to the invention from the side, coupled together according to one embodiment and

Fig. 4 shows another embodiment.

Fig. 5 shows the hole width decreasing with height by displacement of two perforated plates.

Fig. 6 shows a variation of the burner with five perforated plates.

The construction is, of course, not limited to the embodiments which are shown and described, but can be varied in many ways within the scope of the following claims. This concerns not only the number of burners 1 but also their relative location, along with the number of perforated ceramic plates 3, 3a, 3b included in each burner 1 and their appearance regarding the shape of the holes 2, 2a, 2b.

The main component of the arrangement is a gas powered burner 1, the basic form of which includes plates 3 of ceramic material perforated by holes 2. The shown embodiment comprises three plates 3, 3a and 3b, each provided with holes 2, 2a, 2b.

A conduit A is attached to the burner 1 to provide a supply of gas. After being ignited, the gas warms up the perforated plates 3, 3a, 3b to red-hot temperature, whereby infra-red radiation is transmitted, said radiation being of a comparatively high frequency and thereby effective.

The holes 2, 2a, 2b can be round, three-, four-, five-, or six-sided or can have another shape for forming a pattern. Each of the plates 3, 3a, 3b is displaceable in its plane. In this way the ceramic lattice work of the three plates 3, 3a, 3b obtains holes with different opening widths in different regions. Thus the amount of gas flowing through the lattice work can be regulated to achieve the optimum effect.

As far as possible, the combustion should occur inside the lattice work. In order to prevent the combustion from reducing to an undesirably low level due to insufficient

oxygen, the plates can conveniently be moved apart. Fig. 1 shows the plate 3b moved a little from the plate 3a for forming an air-gap 5 between these plates. In this way the oxygen supply to the combustion zone can be regulated and at the same time it can be ensured that the combustion occurs entirely inside the lattice work so that the energy content of the gas is absorbed to a maximum by the plates 3, 3a, 3b. The plates which lie in contact with the combustion area will hereby start to become red-hot and the outermost plate 3b emits energy in the form of infra-red radiation. The wavelength and the intensity are dependent on the energy supplied and the choice of materials for the burner elements. The wasted energy which flows out into the air is hereby negligible and the burner 1 thus functions very economically.

In order to avoid that the combustion zone, due to unfavourable adjustment of the plates 3, 3a, 3b, moving into the space behind the plates, this space is suitably filled up with any mineral wool, filter material 6 or the like. This material firstly prevents an explosive type combustion of the gas, but at the same time provides a uniform distribution of the gas over the rear side of the lattice work.

Due to the fact that the plates are relatively adjustable, the burner 1 can be attached upright and meat juices from food products will therefore never contact the burners' surface, but instead they will travel down towards to the bottom plate. In this way no smell occurs.

The ignition of the gas can occur in a conventional manner using matches or fire lighters but it can also occur using a more sophisticated technique, such as for example a piezo-electric manner. An automatic ignition system of this type can conveniently be placed in the intermediate space

between the flow-limiting plate combination and the heat radiating plate/plates combination. A combustion monitoring cut-out can also be placed in this intermediate space. Fig. 3 shows a combination of three burners placed close to each other and with a gas conduit 4 connected to each one of the burners.