BE1018666A3 - CLOSED BUILT-IN GAS FIREPLACE. - Google Patents

Abstract

The present invention relates to a high efficiency closed built-in gas fire and a gas burner. In particular, the invention provides a gas fire which is characterized by an increased efficiency by providing the inner lining with vertically grooved vermiculite panels with a black cover. Likewise, cooling is provided by convention and there is significant heat recovery. In addition, the gas fireplace is characterized by a compact and space-saving construction and the adjustable burner allows a quick adjustment with regard to the use of different flame bodies.

Description

CLOSED BUILT-IN GAS FIREPLACE

Technical field

The present invention relates to a combustion device. More in particular, the invention relates to a high efficiency closed built-in gas fire and a gas burner for domestic use.

BACKGROUND OF THE INVENTION

Closed fireplaces are well known, since they are an attractive alternative to fireplaces. In the first instance, no direct contact is possible with the produced flames, which considerably increases the safety of such systems. Moreover, such a system ensures efficient and targeted discharge of the flue gases, with the result that there is a reduced risk of the release of toxic gases in the room where the fire is located. Closed fireplaces are usually provided with at least one transparent side, which provides the same visual aspect as the traditional fireplaces.

Closed gas fires can be subdivided based on the fuel used. For example, there are closed fireplaces where wood or coal is the fuel and closed fireplaces where gas serves as fuel. The advantage of gas fires is that they are connected to the gas pipes, so that continuous operation can be guaranteed, where wood fires must be regularly supplied with new fuel.

Gas fires are usually provided with flame bodies. Such flame bodies are often pebbles or fake wood blocks, often made of ceramic material, which cover the bottom of the gas fire and act as flame conductors. The object of this is to obtain a flame that is as natural as possible in order to simulate the burning of wood. The type, position, size and quantity of such flame bodies will determine the final flame pattern. Moreover, the type of flame bodies, boulders or ceramic blocks will influence the ideal placement of the gas openings. For example, the gas openings will often be arranged stepwise in the case of gas fires fitted with ceramic blocks, whereas the gas openings are usually situated in one plane with gas fires fitted with boulders. The conversion of a gas fireplace with pebbles to a gas fireplace with ceramic blocks therefore requires considerable structural adjustments,

Closed fireplaces in general, and closed gas fireplaces in particular, are for the most part built into a wall, so that only the transparent front is visible, while the other components such as the housing, the gas pipes and the air supply or exhaust pipes of the fireplace are connected to the wall. be hidden from view. With conventional closed gas fires, however, extra space often has to be provided on the sides of the fireplace for the supply of convection air via pipes. The purpose of convection air is to provide cooling for, among other things, the control of the gas fire, which nowadays often contains heat-sensitive electronic components. A fan is often provided as an additional aid for cooling, which in turn takes up extra space.

Although certain versions of closed gas fires fulfill a purely decorative function, it is often intended that the fireplace can be effectively used as a heating appliance. This makes it extremely important that the fireplace has a high efficiency. In other words, an efficient fireplace provides a maximum of heat with a minimum of fuel. For this purpose, the walls at the existing fireplaces are often covered with cast iron. Cast iron can withstand very high temperatures and is known for its heat-retaining properties, which means that a large amount of radiant heat can potentially be exempt. However, this is at the same time also one of the disadvantages of cast iron. A large part of the heat produced is initially absorbed by the cast iron, resulting in slow heating. Moreover, cast iron is very heavy, difficult to machine and relatively expensive.

It may be clear that there are a number of shortcomings associated with the existing closed gas fires. The efficiency is often not optimal with regard to flame production, heat generation and heat dissipation as well as heat loss. Moreover, the existing gas fires are often not very compact, resulting in a considerable amount of unnecessary loss of space.

To this end, the present invention provides a number of improvements whereby the efficiency is increased, both with respect to the heating aspect and the location aspect.

Summary of the invention

The present invention relates to a gas fire, in particular a high efficiency closed built-in gas fire. The emphasis In comparison with existing similar gas fires, the present invention lies in an increase in efficiency in terms of heating properties.

To this end, the invention provides a closed combustion chamber which is provided with air supply and gas discharge openings. To prevent excessive soot formation, a smoke inhibitor is provided at the level of the flue gas discharge opening. The fire chamber is closed off at the front by a removable transparent panel. Furthermore, a gas burner is provided in the fire chamber, which comprises on the one hand a gas sprayer and on the other hand an adjustable panel of fire rosettes. The adjustable nature of the panel with fire rosettes allows the same device to be compatible with different types of flame bodies. The precise placement of the fire rosettes on the panel results in a more concentrated flame.

The components of the gas burner are provided at the bottom of the combustion chamber. The gas nozzle is controlled by means of a control element mounted under the fire chamber. Such an arrangement allows cooling of the control element to be provided by means of convection air, which is sucked passively through an opening in the front of the gas fire, so that no fan has to be fitted.

The present invention is further characterized by providing the inner walls of the combustion chamber with panels made of a heat-resistant clay material, preferably vermiculite, more preferably pressed vermiculite and most preferably pressed vermiculite provided with a black coating. Moreover, such panels are provided with a relief, whereby the inner surface of the combustion chamber is enlarged. Such an arrangement considerably increases the efficiency of the gas fire.

In addition, the placement of the control as well as the convection air intake openings provides a compact device, which offers advantages with regard to the speed of installation and installation of the gas fire, accompanied by a minimal loss of space.

Description of the figures

Figure 1 shows a front perspective view of a preferred embodiment of the invention.

Figure 2 shows a front perspective view of a preferred embodiment of the invention with heat-resistant panels on the inner wall of the combustion chamber.

Figure 3 shows a cross-sectional top view of a preferred embodiment of the invention with heat-resistant panels on the inner wall of the combustion chamber (upper part) and a detailed representation of a heat-resistant panel (lower part).

Figure 4 shows a detailed representation of the gas burner according to a preferred embodiment of the invention on the basis of a cross-sectional side view, wherein the panel with fire rosettes is shown horizontally (upper part) or tilted (lower part).

Figure 5 shows a detail representation of the panel with fire rosettes according to a preferred embodiment of the invention in top view (upper part) and perspective view (lower part).

Figure 6 shows a preferred embodiment of the invention in perspective (left upper part) and side view (right upper part) with an open front side, with a detailed representation of the handle or hinge (lower part).

Figure 7 shows a bottom perspective view of a preferred embodiment of the invention on which the diaphragm is displayed.

Figure 8 shows a front view (left-hand part) and a cross-sectional side view (right-hand part) of a preferred embodiment of the invention on which the smoke inhibitor and the internal circulation of the combustion gases is shown.

DETAILED DESCRIPTION OF THE INVENTION

A preferred embodiment of the invention is described with reference to the figures.

In general, the present invention involves a closed built-in gas fire, which is designed in such a way that a higher efficiency is obtained in comparison with existing devices and that the installation of such a device can be carried out quickly and with minimal superfluous space.

Higher efficiency means that given a certain amount of fuel a higher amount of usable heat is obtained. In the present invention this is achieved on the one hand by the materials used, the design of the materials and the placement of the materials. This will, on the one hand, optimize heat production and distribution and, on the other hand, minimize heat loss, including heat recovery.

The gas fire (1) according to a preferred embodiment of the invention is essentially composed of a sealed combustion chamber (2). The gas will be burned in this combustion chamber (2). For this, the gas fire (1) must be connected to the gas supply pipe by means of pipes. Since the invention relates to a closed gas fire (1), the combustion chamber (2) must be provided on the one hand with an opening for the supply of fresh air (8), necessary to catalyze the combustion of the gas, and on the other hand with an opening for the exhaust of flue gases (9). The air supply opening (8) and the flue gas discharge opening (9) can be provided as concentric tubes, the flue gas discharge opening (9) being surrounded by the air supply opening (8). Such an arrangement results in the supplied, cold, air being heated by the discharged, warm, flue gasses. As a result, heat recuperation takes place and pre-heated fresh air will be supplied to the combustion chamber (2).

The discharge of the flue gases is controlled by a diaphragm (10) which is placed in front of the flue gas discharge opening (9). In a preferred embodiment of the invention, the diaphragm (10) is integrated in the gas fire (1) and therefore cannot be lost, which sometimes happens with separately supplied diaphragms. The aperture (10) is adjusted by choosing between fixed discrete positions.

The gas fireplace (1) is also equipped with a smoke inhibitor (11). This is placed at the top of the combustion chamber (2) and is preferably made of stainless steel or stainless steel. The smoke inhibitor (11) is also preferably designed as a corrugated plate. The shape and position of the smoke trap (11) ensure that an afterburning occurs in the combustion chamber (2), which results in a more complete combustion of the flue gases before they leave the combustion chamber (2).

Such an arrangement results on the one hand in a cleaner combustion, whereby less energy is lost as a result of an incomplete combustion, and thus the efficiency is increased. On the other hand, the smoke inhibitor (11) will reflect part of the heat (21). Moreover, the corrugated design of the smoke inhibitor (11) ensures that the surface of the smoke inhibitor (11) is considerably enlarged, resulting in an increased heat reflection and an additional efficiency-increasing effect.

The combustion chamber (2) is made of steel and is surrounded by a convection jacket (19). Such a convection jacket (19) provides an air layer around the combustion chamber (2), whereby on the one hand the combustion chamber (2) is cooled on the outside and on the other hand a heat recovery takes place.

The combustion chamber (2) is closed at the front by means of a transparent panel (12), preferably a glass panel, more preferably a ceramic glass panel and most preferably a demountable ceramic glass panel. The panel is provided with a frame, which is attached to the combustion chamber (2) by one or more handles or hinges (15). The panel (12) hereby acts as a door and the combustion chamber (2) can be opened for maintenance, for example. The panel (12) is mounted in such a way that the combustion chamber (2) can be closed completely so that there is no inflow or outflow of fresh air and / or flue gases, respectively, along this route.

The mounting of the panel (12) on the combustion chamber (2) also allows the panel (12) to be completely detached from the combustion chamber (2) in a quick and simple manner. For this the handle or hinge (15) is mounted on a glider (17). This slider (17) allows the handle or hinge (15) to be slid horizontally, preferably 10 to 30 mm, more preferably 15 to 25 mm and most preferably about 20 mm. In the advanced position the panel (12) can easily be lifted out of the handles or hinges (15). A fully removable panel (12) has the advantage that the internal maintenance of the gas fire (1) is considerably facilitated.

The combustion chamber (2) is furthermore provided with a gas burner (3). The gas burner (3) essentially consists of one or more gas sprayer (s) (6) and a panel (4) provided with fire rosettes (5) and is provided centrally on the bottom of the combustion chamber (2). The gas nozzle (6) supplies the fuel, gas, and is therefore connected to the gas line. The gas nozzle (6) is controlled via a control element (7), which controls the flow rate of the supplied gas. The controller (7) is preferably equipped with a thermostat function, whereby the gas supply can be regulated automatically. In addition, there is the option of controlling the control (7) via a remote control. The regulation of the flames preferably takes place continuously.

An innovation of the present invention is that the control (7) is installed under the bottom plate of the combustion chamber (2). Such an arrangement has a dual effect. In the first instance, there will be less loss of space compared to gas fires where the control is mounted at the rear or on the side of the fireplace. On the other hand, the placement of the controller (7) in the present invention ensures that cooling thereof can be done in an efficient manner.

For example, at the front of the gas fire (1) at the bottom, purposefully selected openings (19) are provided through which the control is cooled via convection air (18) sucked in by a flue effect. Such form of cooling is passive, therefore there is no need to provide fans for forced cooling. Because no connections are provided for cooling on the side of the gas fire (1), the installation of the gas fire (1) is simplified and less space will be lost, resulting in a more compact construction.

The gas is fed to a panel (4) via the gas nozzle (6) and distributed via fire rosettes (5) mounted on the panel (4). Ignition takes place at the fire rosettes (5), causing the flames to form. The panel (4) contains at least two parallel rows of fire rosettes (5), with more fire rosettes being provided on the rear row (5 ') than on the front row (5 "), with the front row of fire rosettes (5") closest is located at the transparent panel (12) at the front of the gas fire (1) .In addition, the rows of fire rosettes (5 ', 5 ") are arranged squarely. Such an arrangement provides a more concentrated flame, which better matches the natural form of burning logs.

As already stated, gas fires are usually fitted with flame bodies. Such flame bodies have the purpose of directing and shaping the flames in order to estimate an aesthetically pleasing aspect. The present invention provides the possibility of enabling the use of different types of flame bodies without having to make major structural modifications to the device.

In contrast to the known gas fires, where the fire rosettes are either provided in one plane or are provided stepwise, the present invention offers the possibility of providing both options in a single embodiment due to the adjustable character of the plate (4) with fire rosettes (5) . The plate (4) can either be provided horizontally (4 '), but can also be tilted (4 ") · In both cases the arrangement of the gas nozzle (6) is fixed and independent of the position of the plate (4) with In the horizontal position (4 ') the arrangement lends itself to be provided with boulders as flame bodies, whereas in the tilted position (4 ") the arrangement lends itself to be provided with counterfeit logs or other elements that form a less compact structure.

In an angled arrangement of the panel (4) provided with fire rosettes (5), the rear row of fire rosettes (5 ') will be higher than the front row of fire rosettes (5 "), resulting in a higher flame pattern with the same amount of gas. Such an arrangement also contributes to an increase in the efficiency of the gas fire (1).

A further innovation of the present invention is that the inner wall of the combustion chamber (2) is provided with panels (13) which are made from a heat-resistant clay material, preferably vermiculite, more preferably pressed vermiculite and most preferably pressed vermiculite provided with a black cover.

The mineral vermiculite is a hydrated magnesium-iron-aluminum silicate with the chemical formula (Mg, Fe 2+, Al) 3 (Al, Si) 4 O 10 (OH) 2-4 (H 2 O). This phylosilicate belongs to the smectite group within the clay minerals. Important properties with regard to the use in heating appliances are the non-flammability of vermiculite and its high insulating capacity,

Vermiculite insulates better than cast iron. Moreover, it is lighter, cheaper and more workable than cast iron. The use of vermiculite in gas fires therefore not only reduces the cost of the gas fire, but also the total weight of the appliance, but will also increase the efficiency of the gas fire due to its superior insulating properties. More heat will thus be reflected and released via the transparent panel (12) on the front of the gas fire (1).

Moreover, the vermiculite panels (13) are preferably provided with a relief, whereby the inner surface of the combustion chamber (2) is enlarged. A larger inner surface is equivalent to a larger reflective surface. In other words, the larger the surface, the more heat is reflected and released to the environment through the transparent front panel (12). The relief provided on the heat-resistant panels (13) is preferably formed by vertical slats (14), the distance between the individual slats (14 '), the width (14 ") and the depth (14" ") of the individual slats are preferably between 2 and 18 mm, more preferably between 6 and 14 mm and most preferably about 10 mm. The panels (13) provided with slats (14) therefore also have an additional efficiency-increasing effect.

Claims (29)

A gas fire (1) comprising a fire chamber (2) provided with a gas burner (3) on the bottom which is equipped with a panel (4) of fire rosettes (5), including a gas nozzle (6) and a control (7) ; an air supply opening (8); a flue gas discharge opening (9) provided with a flue gas discharge diaphragm (10); a smoke inhibitor (11) and a removable transparent panel (12) which closes the front burning chamber; characterized in that at least one inner wall of the combustion chamber is provided with one or more panels (13) made from a heat-resistant clay mineral. Gas fireplace according to claim 1, characterized in that it is heat-resistant clay mineral vermiculite. Gas fireplace according to one of claims 1 and 2, characterized in that it is heat-resistant clay mineral pressed vermiculite. Gas fireplace according to one of claims 1 to 3, characterized in that the heat-resistant clay mineral is provided with a black coating. Gas fireplace according to one of claims 1 to 4, characterized in that the panels made from the heat-resistant clay mineral are provided with a relief. Gas fireplace according to one of claims 1 to 4, characterized in that the panels made from the heat-resistant clay mineral are provided with vertical slats (14). Gas fireplace according to claim 6, characterized in that the distance between the individual slats (14 '), the width (14 ") and the depth (14"') of the individual slats is preferably between 2 and 18 mm, more is preferably between 6 and 14 mm and most preferably about 10 mm. Gas fireplace according to one of claims 1 to 7, characterized in that the rosettes panel is adjustable. Gas fireplace according to one of claims 1 to 8, characterized in that the fire rosette panel can be placed both horizontally (4 ') and tilted at an angle (4 "). Gas fireplace according to one of claims 1 to 9, characterized in that the panel of fire rosettes consists of at least 2 rows of fire rosettes, the rear row (5 ') containing more fire rosettes than the front row (5 "). Gas fireplace according to claim 10, characterized in that the rows of fire rosettes are arranged in a staggered manner. Gas fireplace according to one of claims 1 to 11, characterized in that the transparent removable panel is a ceramic glass panel. Gas fireplace according to one of claims 1 to 12, characterized in that the transparent removable panel is attached to the fire chamber via handles or hinges (15), so that the fire chamber can be opened. Gas fireplace according to claim 12, characterized in that the transparent removable panel is preferably 10 to 30 mm, more preferably 15 to 25 mm and most preferably approximately 20 mm horizontally extendable (16) by means of a glider (17), wherein the transparent removable panel can be lifted out of the handles or hinges in the advanced position. Gas fireplace according to one of claims 1 to 14, characterized in that the air supply opening and the flue gas discharge opening are provided concentrically in the combustion chamber, the air supply opening surrounding the flue gas discharge opening. Gas fireplace according to one of claims 1 to 15, characterized in that the setting of the flue gas discharge diaphragm is made by choosing between fixed discrete positions. Gas fireplace according to one of claims 1 to 16, characterized in that the smoke inhibitor is designed as a stainless steel plate. Gas fireplace according to one of claims 1 to 17, characterized in that the smoke inhibitor is made of stainless steel. Gas fireplace according to one of claims 1 to 18, characterized in that the smoke inhibitor is designed as a corrugated plate. Gas fireplace according to one of claims 1 to 19, characterized in that the bottom of the combustion chamber is covered with flame bodies. Gas fireplace according to claim 20, characterized in that the flame bodies are boulders. Gas fireplace according to claim 20, characterized in that the flame bodies are ceramic blocks. Gas fireplace according to one of claims 1 to 22, characterized in that the control is mounted under the bottom plate. Gas fireplace according to one of claims 1 to 23, characterized in that the control unit is provided with a thermostat function. A gas fire according to any one of claims 1 to 24, characterized in that the control functions by means of a remote control. A gas fire according to any one of claims 1 to 25, characterized in that the control is cooled via convection air (18) which is passively sucked through an opening (19) in the front of the gas fire. A gas fire according to any one of claims 1 to 26, characterized in that the combustion chamber is made of steel. A gas fire according to any one of claims 1 to 27, characterized in that the combustion chamber is surrounded by a convection jacket (20). A gas fire according to any one of claims 1 to 28, characterized in that the gas fire is a closed built-in gas fire.