In order to adapt a gas-infrared radiator (a radiant burner) to operating conditions in a particularly efficient manner, the energy delivered is reduced by intermittently reducing a controlled supply of gas so that the energy delivery is below about 40% or even less of the maximum energy delivery of the infrared radiator, and a flame supplied separately from the controlled gas supply is maintained in the combustion chamber of the gas-infrared radiator, at least when operating in the aforementioned range. This is achieved more particularly by providing at least one nozzle (22) for a pilot light, directed towards the combustion chamber (4).
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5. A gas infrared radiator comprising a pre-chamber connected to gas and air supply pipes and a combustion chamber surrounded substantially on all sides by components, a plurality of individual pipes for supplying a gas-air mixture and extending between the pre-chamber and the combustion chamber through a heat-resistant gas permeable barrier layer, pulse control means for intermittently varying the supply of fuel gas, at least one nozzle for a pilot light directed into the combustion chamber, and means providing a separate gas supply to said nozzle independent of the means for varying the supply of fuel gas.
8. A gas infrared radiator, comprising:
a pre-chamber connectable to gas and air supply pipes; a combustion chamber surrounded substantially on all sides by components; a heat resistant, gas permeable barrier layer disposed between the pre-chamber and said combustion chamber; a plurality of individual conduits for supplying a gas and air mixture from the pre-chamber into the combustion chamber through said heat resistant barrier layer; pulse control means for supplying and intermittently varying the supply of fuel gas to said pre-chamber; at least one nozzle for a pilot light directed into the combustion chamber through said barrier layer, said nozzle being surrounded by means forming a flow path of said mixture into said combustion chamber; and means providing a separate gas supply to said nozzle independently of the means for varying the supply of fuel gas.
1. A method of operating a gas infrared radiator with variable energy output and comprising means forming a combustion chamber surrounded substantially on all sides by components and a pre-chamber adjacent the combustion chamber, a barrier layer of fibrous material with a plurality of pipes extending therethrough separating the pre-chamber from the combustion chamber, the amount of gas other than air supplied to the combustion chamber or said pre-chamber chamber being variable by a control device, characterized in that the amount of gas supplied is intermittently varied by a pulse control system down to a range corresponding to an energy delivery level less than about 40% of the maximum rated energy obtainable from the infrared radiator, the air supply being continuously maintained, and a flame supplied with gas is maintained in the combustion chamber separately from the controlled gas supply when operating in the previously-mentioned range.
2. A method according to
3. A method according to
4. A method according to any of
6. A radiator according to
7. A radiator according to
9. A method of operating a gas infrared radiator to provide a variable energy output and comprising means forming a combustion chamber and pre-chamber, a barrier layer arranged between said pre-chamber and said combustion chamber, said barrier layer having a plurality of pipes extending through said barrier layer for communicating said pre-chamber with said combustion chamber, the amount of a gas other than air supplied to the combustion chamber or said pre-chamber being variable by a control device, characterized in that the amount of gas supplied is intermittently varied by a pulse control system to regulate the output energy of the infrared radiator over a range extending from the maximum rated energy level capable of being delivered by the infrared radiator to an energy level less than about 40% of said maximum rated energy level, the air supply to said mixing chamber being continuously maintained and a pilot flame in said combustion chamber being maintained by gas supplied to the combustion chamber separately from the controlled gas supply to assure combustion within said combustion chamber whenever gas is delivered to the combustion chamber from said pre-chamber. 10. The method of
supplied with combustion air. 13. A gas infrared radiator comprising: a pre-chamber connectable to gas and air supply sources; a combustion chamber; a heat resistant barrier layer disposed between said pre-chamber and said combustion chamber; said barrier layer having a plurality of individual conduits for supplying a gas and air mixture from said pre-chamber into said combustion chamber through each of said conduits; pulse control means for supplying and intermittently varying the supply of fuel gas to said pre-chamber; at least one nozzle for a pilot flame extending through said barrier layer and directed into the combustion chamber; and means providing a separate gas supply to said nozzle independently of said pulse control means for supplying fuel gas to said pilot flame nozzle unaffected by said pulse control means. 14. A gas infrared radiator according to claim 13 wherein said separate gas supply includes means for continuously supplying gas for said pilot flame totally unaffected by the intermittent operation of said pulse control means. |
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The invention relates to a method of operating a gas-infrared radiator and to a gas-infrared radiator of use more particularly in the method.
Gas-heated infrared radiators, also called radiant burners, are used inter alia in the treatment or processing of webs of material, particularly in the paper and cardboard industry. The treatment more particularly comprises heating the web material in the press part of board machines, drying the paper and cardboard and drying the coating on paper or cardboard.
Known infrared radiators (radiant burners) have a casing containing a pre-chamber supplied with a mixture of gas or fuel vapour with air, a combustion chamber separated from the pre-chamber by a barrier layer of heat-resistant material, and a hot member which externally covers the combustion chamber. The barrier layer is formed with through apertures for the mixture. In a particularly well-tried embodiment the hot member is made up of a number of individual quadrilateral parts held by a grid disposed in front of them (German patent specification 16 29 952).
In the case of drying plants for web material, infrared radiators are disposed in a number of rows one behind the other, each row extending across the entire width of the web. Each row consists of a corresponding number, of adjacent infrared radiators. The moisture content of a web for drying often varies across the web and may also vary along the web. The web is said to have a moisture profile, which can be mapped by measuring devices in front of the radiator system. Normally the object is to dry the web uniformly, and consequently the supply of heat to the web has to be varied from one region to another.
In the case of known installations this is done by regulating the gas supply to individual infrared radiators or groups thereof. To this end, a valve can be disposed in the gas feed pipe to each radiator and opened and closed in supplying the gas-air mixture, extending through from pre-chamber 3 to combustion chamber 4. Supply pipes 12 are advantageously in the form of metal tubes inserted in the barrier layer and secured e.g. to a metal plate 8 holding the barrier layer 9 and shutting off the pre-chamber 3.
Reference 10 denotes a split-pin or the like for joining the casings of two adjacent radiators 1 and 1', more particularly when the radiators are disposed in a row. Only a portion of radiator 1' is shown for purposes of simplicity.
One or more radiators in an aforementioned row can be equipped with one or more ignition and monitoring electrodes in known manner. Alternatively the radiator according to the invention can without difficulty be equipped with an ignition and/or monitoring electrode or corresponding devices.
The combustion process occurring in the combustion chamber heats the hot member, which gives out energy in the form of radiation, mainly infrared.
Details of the fuel supply are shown in FIG. 2. Reference 13 denotes an air supply line and reference 14 a gas supply line. These lines can supply a larger large number of radiators or rows of radiators. Air and gas travel from lines 13 and 14 through a mixing nozzle 15 into a mixing chamber 16, the bottom end of which terminates in the prechamber 3 (compare FIG. 1).
In the embodiment shown, the air from line 13 constantly flows through nozzle 15 and chamber 16 to radiator 1, whereas the gas supply is controllable in a special manner.
Firstly, a gas tube 17 extends from line 14 to a branch member 18 from which a feed pipe 19 extends through a headpiece 20 to the mixing nozzle 15.
Pipe 19 contains a valve 26 actuated by a device 27, more particularly from a completely closed position into a completely opened position and vice versa. Device 27 is connected by a line 28 to a pulse control device (not shown) or a central unit thereof, which emits pulses controlling the device 27 and valve 26. Components 26 and 27 may more particularly be anelectromagnetically actuated valve.
The pulse control device (not shown in detail) associated with one or more radiators advantageously operates as follows: during a preset fixed time interval or cycle of e.g. 6 seconds, valve 26 is opened during a certain number of switching operations, each for a given time, the opening time being adjustable. The amount of fuel gas supplied per unit time can thus be altered in order to vary the energy delivered by radiator 1. The times during which valve 26 is opened and closed are always so short that compensation occurs owing to the inertia conditions in the adjacent system, the result being that the mixture reaching the combustion chamber always has the desired quality corresponding to the aimed-at energy delivery by the radiator.
FIG. 3 is a diagram of various adjustable methods of operation in the case of the pulse-controlled gas feed pipe, and consequently with regard to the output of the burner. In each case the basis is a time interval or cycle of 6 seconds. The shaded areas indicate that valve 26 is opened and consequently gas flows to the mixing chamber 16, which is constantly connected to the air pipe 13. At other times, valve 26 is closed by the pulse control system, when air alone is supplied.
In the operating mode denoted by the letter A, the burner is operated at 100% output. In mode B, gas is supplied during only half each cycle, so that the burner operates at 50% capacity. Correspondingly, the other modes C, D and E represent outputs of 25%, 12.5% and an even lower value, e.g. 5%. Mode F corresponds to the burner being switched off.
A gas feed pipe 21 always freely continuously connected to the gas pipe 17 leads from a branch member 18 to a nozzle 22 directed towards the combustion chamber 4 or ending therein. The nozzle 22 therefore has a gas supply which is separate and independent of the aforementioned means controlling the amount of fuel gas supplied to the mixing nozzle 15 and mixing chamber 16 and then supplied with air to the radiator. Consequently a pilot light is continuously maintained in the combustion chamber 4, and its tip is directed more particularly towards a part 7 of the hot body.
As a result, and in a particularly advantageous manner the amount of fuel gag supplied in controlled manner by valve 26 (as previously explained inter alia in conjunction with FIG. 3) can be reduced to very small values, and the energy delivered by the radiator can be reduced as required without interrupting or disadvantageously influencing its operation. The pilot light is not an ignition flame or the like the igniting a known burner, but a flame which ensures that the radiator can operate in the described manner even at low power.
Nozzle 22 can project into the combustion chamber 4. In the embodiment shown, the mouth of nozzle 22 is positioned in a metal tube 24 extending through the barrier layer 9 and bounding an annular flow path 23 leading from the prechamber 3 to the combustion chamber 4. The pilot light from nozzle 22 thus receives combustion air from the prechamber through the flow path 23.
As a variant to the described embodiment, various other arrangements and embodiments are possible for a nozzle or the like for a pilot flame. For example one of the supply pipes 12 can be used as a nozzle for a pilot flame and connected to a separate gas supply, as shown chain-dotted at reference 21' in the right half of FIG. 1. The combustion air will then be the air supplied in any case to chamber 4.
The pilot-light nozzle can also be supplied beforehand with a gas-air mixture independently of the fuel gas supply.
All features mentioned in the preceding description or shown in the diagrams should be regarded as coming under the invention, either alone or in combinations, insofar as permitted by the known prior art.
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