Gas hearth

Abstract

A gas hearth including a combustion chamber, a gas supplier for supplying combustible gas into the combustion chamber to a firebed simulator disposed in the combustion chamber, an ignitor for igniting the combustible gas in the combustion chamber, a flue-gas discharge duct connected to the combustion chamber for discharging combustion flue gases from the combustion chamber, and a metering means disposed in the combustion chamber for metering a pyrotechnical additive into the flames of the burning combustible gas during operation.

Claims

1. A gas hearth, comprising: a combustion chamber; a gas supply for supplying combustible gas into the combustion chamber to a firebed simulator positioned in the combustion chamber; an ignitor for igniting the combustible gas in the combustion chamber; a flue-gas discharge duct connected to the combustion chamber for discharging combustion flue gases from the combustion chamber; and metering means arranged in the combustion chamber for metering a pyrotechnical additive into flames of burning combustible gas during operation.

2. The gas hearth according to claim 1, wherein the metering means comprises a reservoir for holding the pyrotechnical additive, wherein the reservoir has at least one metering opening.

3. The gas hearth according to claim 2, wherein the metering means comprises at least one supply line connected to the metering opening and ending near the firebed simulator.

4. The gas hearth according to claim 2, wherein the metering means comprises at least one pump disposed near the at least one metering opening for passing a predetermined amount of pyrotechnical additive through the supply line in a direction of the firebed simulator by way of a pressurized medium.

5. The gas hearth according to claim 4, wherein the metering means comprises a valve for closing the at least one metering opening.

6. The gas hearth according to claim 5, wherein the metering means comprises a controller for sequentially actuating the valve and the at least one pump.

7. The gas hearth according to claim 5, wherein the valve is a magnet coil-actuated valve.

8. The gas hearth according to claim 4, wherein the at least one pump is a compressed air pump.

9. The gas hearth according to claim 2, wherein the reservoir is attached to a shaft.

10. The gas hearth according to claim 9, wherein the metering means comprises drive means for rotatably driving the shaft.

11. The gas hearth according to claim 10, wherein the drive means is a chain drive.

12. The gas hearth according to claim 2, wherein the reservoir has a filling opening configured to be closed with a closure.

13. The gas hearth according to claim 12, wherein the closure forms part of the firebed simulator.

14. The gas hearth according to claim 2, wherein the reservoir is configured to pass the pyrotechnical additive to the at least one metering opening.

15. The gas hearth according to claim 2, wherein the reservoir has one or more walls oriented at an angle in a direction of the at least one metering opening.

16. The gas hearth according to claim 1, wherein the metering means is arranged below the firebed simulator.

17. The gas hearth according to claim 1, wherein the metering means is arranged above the firebed simulator.

18. The gas hearth according to claim 1, wherein the pyrotechnical additive comprises granules including a carbon-containing additive.

19. The gas hearth according to claim 1, wherein the granules are a pulverulent or granular material.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) These and other features, aspects and advantages of the present invention are better understood when the following detailed description of the invention is read with reference to the accompanying drawings, in which:

(2) FIG. 1 shows a diagrammatic view of a gas hearth according to the prior art with a metering means according to the present invention;

(3) FIG. 2 is a perspective view of a metering means and hearth according to an embodiment of the invention;

(4) FIG. 3 is an elevation view of the metering means;

(5) FIG. 4 is a cross-sectional view of the metering means;

(6) FIG. 5 is a perspective view showing the metering means, pump, and controller;

(7) FIG. 6 is an exploded view of another embodiment of a metering means;

(8) FIG. 7 is an assembled perspective view of the metering means of FIG. 6; and

(9) FIG. 8 is a detailed view of a portion of the hearth according to an embodiment of the invention.

DETAILED DESCRIPTION

(10) For a better understanding of the invention, the similar components shown in the various figures are denoted by identical reference numerals in the following description of the figures.

(11) FIG. 1 diagrammatically shows an embodiment of a gas hearth according to the prior art. In particular, the burner system of a hearth is shown in the way in which it is arranged in the combustion chamber of the gas hearth.

(12) In general, a decorative hearth is composed of a housing comprising side walls, a bottom wall, a front wall and a rear wall. The front wall is often transparent and can also be rotated away or slid away for maintenance. The front, bottom, rear and side walls enclose a combustion chamber 10 in which the firebed-simulating means, denoted here, for example, by reference numerals 12a-12d, are accommodated. The firebed-simulating means 12a-12d are configured to simulate a fire image and all respective components are fitted to a bottom panel which forms part of the bottom wall of the combustion chamber 10.

(13) As is illustrated in FIG. 1, the hearth 1 is provided with gas supply means (gas supply line) 13 which are connected to a main supply line (not shown). The gas supply line 13 branches off into branch lines 13a-13d, each of which extend into the combustion chamber 10, and which, in particular, each end at the location of the firebed-simulating means 12a-12d. A control valve 14 is incorporated in the gas supply line 13 which can be controlled by suitable control means (not shown) via the control line 15 and can be closed off in order to close off the gas supply into the combustion chamber 10.

(14) The firebed-simulating means 12a-12d may be configured, for example, as imitation logs, which may, for example, be made of a fireproof ceramic material. Such imitation logs are often also porous, so that the gas supplied via the respective branch line 13a-13d may flow through or leak into the porous imitation logs and can be made to ignite locally on the surface using suitable, gas ignition means (not shown). In this way, a fire image may be simulated which is similar to that of a conventional fire of burning wooden logs.

(15) The combustion flue gases can be discharged from the combustion chamber 10 via the flue-gas discharge duct 11.

(16) As one objective of a decorative hearth is to produce a realistic fire image, and is not intended, unlike conventional hearths, to emit heat to the surroundings, it is desirable for a decorative hearth to produce as realistic a fire image as possible while using a minimal amount of gas.

(17) However, a lower gas consumption (i.e. gas supply to the combustion chamber via the gas supply 13) also leads to fewer flames, as a result of which the fire image is less realistic. However, the firebed-simulating means 12a-12d aim to enhance the fire image by simulating burning logs.

(18) In order to be able to also produce a realistic fire image with an improved fire impression in the case of reduced gas consumption, metering means 20 are arranged in the combustion chamber 10 which, during operation, meter a pyrotechnical additive into the flames of the burning combustible gas. In particular, the metering means are arranged above the firebed-simulating means 12a-12d, as is illustrated in FIG. 1, in such a way that, when metering the pyrotechnical additive being contained in reservoir 22 via the metering opening 22b, this additive ends up in the air stream of the rising combustible flue gases and is ignited by the flames when it flutters down in the direction of the firebed created by the firebed-simulating means 12a-12d. Upon ignition, the pyrotechnical additive generates additional fire and light effects, such as sparks, which also occur during burning of natural wooden logs.

(19) In another embodiment, such as illustrated, for example, in FIG. 5, the metering means 20 are arranged at the bottom of the combustion chamber 10 and more particularly under the firebed-simulating means 12a-12d.

(20) The metering means 20 are composed of a mounting panel 21 to which, and on which, all relevant components are attached. Reference numeral 22 indicates a reservoir wherein a certain amount of pyrotechnical additive is stored. The reservoir 22 is sufficiently fire-resistant and heat-resistant in order to ensure that the heat which is produced in the combustion chamber during operation does not result in an undesirable and premature spontaneous combustion of the pyrotechnical additive which is held in the reservoir 22.

(21) The reservoir 22 is provided with a top side 22a which is provided with an opening which may be closed off by a closure, in particular a closing lid 23. The reservoir 22 can be filled with a certain amount of pyrotechnical additive via the opening which is provided in the top side 22a. Furthermore, the reservoir 22 is provided with a metering opening 22b for supplying a certain amount of pyrotechnical additive from the reservoir 22 to a supply line 25 which runs from the metering opening 22b through the combustion chamber and the free end 25a of which ends at one of the firebed-simulating means 12a-12d, as is illustrated in FIG. 1.

(22) The reservoir 22 is constructed in such a way that it promotes or facilitates the supply of the pyrotechnical additive from the reservoir 22 in the direction of the metering opening 22b and the supply line 25. In particular, the reservoir 22 is provided with oblique walls 22c and 22d which thus form a funnel in the direction of the metering opening 22b.

(23) According to the invention, the metering opening 22b can be closed off by means of a controllable shut-off valve 24. By briefly opening and closing the closable valve 24, a certain amount of pyrotechnical additive can leave the reservoir 22 via the metering opening 22b closed off by the valve 24 and be received in the line 25. At the location of the closable valve 24, the line 25 is connected to an air line 27 which is connected to a pump 26. By means of the pump 26, the amount of pyrotechnical additive held in the line 25 by means of a pressurized medium, for example air, can be blown in the direction of the outlet opening 25a.

(24) When the pyrotechnical additive leaves the outlet opening 25a, which, as has already been mentioned, is positioned at the location of the firebed-simulating means 12a-12d, it will come into contact with the burning gas and thus create additional flame and fire effects, such as sparks.

(25) To this end, the metering means 20 also comprise control means 28 (see FIG. 3) which pass control signals to the closable control valve 24 or the pump 26, respectively, via suitable control lines 29a and 29b. More specifically, the control means 28 are configured in such a way that the control means actuate the control valve 24 and the air pump 26 sequentially. Sequentially means firstly that the closable control valve 24 is actuated by the control means 28, resulting in the control valve 24 being opened briefly. As a result thereof, a certain amount of pyrotechnical additive can be poured or metered into the line 25 from the reservoir 22 via the metering opening 22b which has been opened in this way.

(26) Subsequently, the control valve 24 is closed by the control means 28 and the air pump 26 is actuated which blows this metered amount of pyrotechnical material through the supply line 25 in the direction of the outlet opening 25a by means of a short air pressure pulse via the air line 27 and the supply line 25. Upon leaving the outlet opening 25a on account of the air pulse delivered by the pump 26, the dispensed pyrotechnical additive will be brought to ignition at the location of the firebed-simulating means 12a-12d (see FIG. 1) by the burning gas and thus produce the additional flame and fire effects.

(27) The air pump 26 is in each case actuated briefly by the control means 28 for delivering an air pressure pulse in the air line 27 in the direction of the control valve 24 and the supply line 25. To this end, the air pump 26 takes air from elsewhere and preferably from outside the combustion chamber 10 (see FIG. 1) via the inlet opening 27a. Thus, the air line 27 has such a length, as a result of which the air pump 26 and preferably the inlet opening 27a are arranged at some distance from and outside the combustion chamber 10. This prevents hot combustion flue gases from being introduced into the air line 27 via the inlet opening 27a, which could possibly cause the pyrotechnical additive metered into the supply line 25 to ignite spontaneously. The position of the inlet opening 27a of the air line 27 as far as outside the combustion chamber 10 is thus a safety aspect of the present gas hearth.

(28) In this embodiment, a non-return valve has to be incorporated in the inlet line 27a which extends to the outside of the combustion chamber in order to prevent combustion flue gases from escaping from the combustion chamber 10 via the air line 27 and the inlet opening 27a instead of via the flue-gas discharge duct 11.

(29) In a preferred embodiment, the inlet opening 27a of the air line 27 and the outlet opening 25a of the outlet line 25 are both in the combustion chamber 10. This results in a closed system, so that combustion flue gases cannot escape from the combustion chamber except via the flue-gas discharge duct 11. However, the inlet opening 27a has to be arranged in the combustion chamber 10 in such a way, for example at some distance from the firebed-simulating means, so as to prevent an undesired inflow of combustion flue gases.

(30) In yet another embodiment, the air pump is not switched on or off by the control means 28, but the air pump is actuated continuously and an air stream is continuously blown in the direction of the supply line 25 and the outlet line 25a by the air line 27.

(31) As is illustrated in FIG. 4, the closable control valve 24 is, in particular, a magnetic valve (also referred to as a magnet-coil actuated valve). To this end, the control valve 24 is provided with a bore hole 24b in which a reciprocating plunger 24a is accommodated. The plunger 24a is movable into a closed position, such as illustrated in FIG. 4, in which it closes the metering opening 22b and closes it off from the air line 27 and the supply line 25, and into an open position, in which the metering opening 22b is briefly connected with the supply line 25, so that pyrotechnical additive which is situated in the reservoir 22 can be metered out.

(32) The reciprocating plunger 24a is provided with grooves 24d wherein coil windings 24c are wound. In addition, the valve 24 is provided with a magnet 24e which is arranged around the bore hole 24b and the part of the plunger 24a where the coil windings 24c are situated. By means of suitable control signals which are emitted by the control means 28 to the magnetic valve 24 via the control line 29a, the plunder 24a can be moved to and fro in the bore hole 24b between the closed position and the open position on account of the coil/magnet interaction.

(33) In this way, it is possible to transfer a small amount of pyrotechnical additive from the reservoir and the open metering opening 22b to the supply line 25 by in each case briefly opening the magnetic valve 24. Closing the magnetic valve 24 again first and then actuating the air pump 28 to deliver an air pulse into the air line 27 prevents the air pulse from blowing the pyrotechnical additive which has just been metered back into the reservoir 22. By contrast, the closed magnetic valve 24 causes the metered pyrotechnical additive which is present in the supply line 25 to be blown in the direction of the outlet opening 25a by the air pulse through the supply line 25.

(34) Preferably, the actuation of the magnetic valve 24 by the control means 28 is random, so that the supply of the pyrotechnical additive via the outlet opening 25a to the burning firebed-simulating means 12a-12d is also random and unpredictable. The random unpredictable actuation of the magnetic valve 24 and the resulting random supply of pyrotechnical additive to the firebed-simulating means 12a-12d also contributes to a more realistic fire image, since this also produces random flame and fire effects, similar to the fire image of a conventional burning log fire.

(35) The time period of the brief opening of the magnetic valve 24 may also be set randomly within a certain range, so that the amount of pyrotechnical additive during each metering from the reservoir 22 in the supply line 25 also varies. Consequently, the intensity of the resulting flame and fire effects vary with each dose. This also helps to create an improved simulation of the random and chaotic fire image of a conventional burning log fire.

(36) The pyrotechnical additive preferably includes granules, in particular a pulverulent or granular material. In particular, the pyrotechnical additive is a carbon-containing additive, in which the granules have a grain size of between 0.05 mm-2.5 mm.

(37) In a further embodiment, such as illustrated in FIG. 5, wherein the metering means 20 are positioned under the firebed-simulating means 12a-12d of the gas hearth, as is illustrated in FIG. 1, the closure 23 is formed in such a manner that it forms part of the firebed-stimulating means. In FIG. 5, the closure is denoted by reference numeral 230 and is formed as an imitation log. In this way, the metering means 20 can be fitted at a small distance below the level of the firebed-simulating means 12a-12d in the gas hearth, thus achieving a further reduction in the installation space.

(38) It should be noted that although the sealing cap 230 is formed as an imitation log, it does not actively contribute to the play of flames and fire during operation. The sealing cap 230 will therefore not be porous and will also not be provided with a connection to the gas supply means 13, as illustrated in FIG. 1.

(39) FIGS. 6-8 show another embodiment of a gas hearth according to the invention.

(40) In this embodiment, the metering means 40 are positioned at the top of the combustion chamber 10 and in particular above the firebed-simulating means 12a-12d. The reservoir 42 is provided with a top side 42a in which an opening 42a is provided which can be closed off by a closure, in particular a closing lid or cap 43. The reservoir 42 can be filled with a certain amount of pyrotechnical additive via the opening 42a which is provided in the top side 42a.

(41) Furthermore, the reservoir 42 is provided with one or more metering openings 42b for supplying or scattering a certain amount of pyrotechnical additive at the top of the combustion chamber 10 (and above the burning firebed-simulating means 12a-12d) from the reservoir 42. In this case, the reservoir 42 is placeable in a holder 41 which is supported by shafts 45 which are rotatably accommodated in the combustion chamber 10 (see FIG. 8). In this case, reservoir 42 is retained in the holder 41 by means of a retaining pawl 44a which can be fixed to the threaded end 41c of the holder 41 by means of a swivel or screw 44b.

(42) Analogous to the reservoir 22 as shown in FIGS. 2-6, the reservoir 42 has oblique walls 42c and 42d which thus form a funnel in the direction of the metering opening 42b in order thus to assist or facilitate the supply of the pyrotechnical additive to the combustion chamber 10.

(43) Furthermore, the metering means 40 comprise drive means 50 for rotatably driving the shaft 45. The drive means 50 are placed on one side of the combustion chamber 10 and in this embodiment comprise a drive motor 51 (electric motor) provided with a first gear wheel 53a by means of which the shaft 45 is rotatably driven via a chain transmission. To this end, a chain 52 is placed over the first gear wheel 53a and also runs across a second gear wheel 53b. The second gear wheel 53b is placed on the shaft 45. On the other side of the combustion chamber 10, the shaft 45 is mounted in a bearing 46 which is accommodated in the wall of the combustion chamber 10.

(44) In operation, the drive motor 51 will rotate the shaft 45, as a result of which the holder 41 with the reservoir 42 in the combustion chamber 10 and above the firebed-simulating means 12a-12d co-rotate. With each rotation, the pyrotechnical additive in the reservoir 42 will be displaced in the direction of the metering opening(s) 42b (partly assisted by the oblique side walls 42c and 42d) and will be released into the top of the combustion chamber 10 and above the burning firebed-simulating means 12a-12d (see FIG. 1) via the metering opening(s) 41b/42b on account of the force of gravity.

(45) The pyrotechnical additive will enter the air stream of the rising combustible flue gases and will be ignited by the flames when it drifts down in the direction of the firebed created by the firebed-simulating means 12a-12d. Upon ignition, the pyrotechnical additive creates additional fire and light effects, such as sparks, which also occur during burning of natural wooden logs.

(46) Instead of performing a complete rotation, the reservoir 42 may also be rotated to and fro by the drive motor 51. Upon each rotation or reciprocating movement, the pyrotechnical additive in the reservoir 42 will be disturbed and will be released in the form of a small dose of a random amount of additive via the metering opening 42b (and 41b).