DE1064671B - Gas burner for insertion in a heating pipe - Google Patents

Description

Gas burners for insertion in a heating tube The invention relates on a gas burner for insertion in a heating tube. Such a pipe can be used in red heat act as heat radiators and made of a high temperature resistant There are special alloys, but also as an immersion tube or as a finned tube thanks to the burner Od. Like. Be fired for convection heating.

"" Compared to immersion or convection tubes are Värmestrahlerrohre most in use. In the present description, all of these pipes, no matter what type, commonly referred to as heating tubes, since they themselves, from the burner flame heated, serve to heat any medium.

The heating tube can have a wide variety of known shapes. In all cases the burner is on one side and the outlet for the heating gases is located at your other end of the pipe.

There are already such burners for submerged pipes guided under water known to burn gaseous fuel with air in an ignition tube during the actual combustion of the gas-air mixture used for heating takes place outside this ignition tube in a combustion chamber. With such Underwater burners but a relatively short flame is formed, their Length is determined by the depth of the liquid bath to be heated. By doing pipes running at the bottom of the bath then essentially only have hot, no longer flammable gases to flow. Such burners are therefore not with any equipped technical means with which the flame length inside the heating pipe can be changed.

A burner for a radiant heating tube is also known, in which the combustion gas via a pipe and a chamber is single ring-shaped arranged pipe nozzles is fed, while the combustion air these pipe nozzles is introduced into the heating pipe by stroking approximately in the longitudinal direction of these pipe nozzles. Such a burner is also not provided with devices with which the flame length is changeable inside the heating pipe.

Finally, a burner is also known, the one with the largest part the length of a main pipe protrudes into the heating pipe and in which the main pipe is substantially greater length than diameter and at its front end in a burner mouthpiece ends. This known burner is already a fuel gas-air mixture from the outside fed, while the annular space between the main pipe and the Secondary air is fed into the heating pipe via another line. A scheme the ratio between primary air and secondary air and a control of the flame length is not provided with this burner.

Compared to all known burners, the invention is technical Task is based on a gas burner, which is primarily in a radiant heating tube is to be used to regulate the flame length by simple means, so that the Burner adjustable to any length of the heating pipe and to any heating gas to be burned is.

After the invention, this object is achieved in that changeable Connection openings between an air supply chamber of the distributor body and the Inside the main pipe for supplying primary air to the fuel gas, also a for Change in the quantity ratio between primary air and secondary air can be adjusted Annular gap at the outlet of the air supply chamber to the annular space between the main pipe and heating pipe and means for deflecting the secondary air in a helical manner Track are provided along the inner surface of the heating tube.

The invention has the essential advantage that the Burner practically without any change in its dimensions and in its construction every occurring length of the heating pipe and every possible heating gas can be customized. Above all, the invention creates the possibility to draw the flame long enough to cover the entire length of a radiant heating tube to take. In other cases, however, it is also possible to set the flame as short as possible. that it does not knock out of the open end of shorter heating tubes.

By deflecting the flame along a helical path the inner surface of the heating pipe is not only a particularly favorable control option created for the flame length and the rate of burn, but above also a particularly high heat exchange efficiency on the inner wall of the Heating tube achieved.

Due to the wide control range of the burner achieved with the invention This is still not the only possibility. such a burner for a short time one after the other with different heating gases, but also a burner take away from his heating pipe and attach to another heating pipe and then adapt to this new heating pipe in just a few simple steps.

In a preferred embodiment of the invention, the means consists of Change of the air-gas ratio in the main pipe from a socket that forms the main pipe surrounds in front of the primary air inlets and on it relative to the primary air inlets is displaceable to regulate the primary air passing through these inlets. That The front end of the sleeve can also be used as a valve for the Rin passage of the secondary air be trained. The arrangement is preferably made so that the front The end of the sleeve is designed as a conical collar and at the outlet of the air supply chamber a throttle ring is provided, on the other hand the conical collar is arranged in this way is that with axial displacement of the sleeve for increasing closure of the primary air inlets the ring passage widened increasingly and with axial displacement of the -Tuffe to increasing opening of the primary air inlets, the ring passage is increasingly narrowed.

An example of a burner according to the invention is given below in Details are described on the basis of the drawing; It shows Fig. 1 a partially sectioned Longitudinal view of a gas burner with the features of the invention, FIG. 2 a schematic View of the burner on a U-tube, FIG. 3 a longitudinal section through the gas burner mouthpiece and the flame restriction, Fig. -1 the front view of the burner, in the direction of Arrows 4-4 of Fig. 1, Fig. 5 is a similar view, but partially approximate in the plane of the line 5-5 of FIG. 1, sectioned, and FIG. 6 shows a cross section approximately in the plane 6-6 of FIG. 1.

In the drawing, especially in Fig. 2, a backward backward or U-shaped bent heating tube 12 is shown, which when used as a heat radiator made of heat-resistant material, e.g. B. a steel alloy can be made. The inlet end 14 of the tube 12 is through a heat resistant wall 16 made of masonry, refractory bricks or the like. Passed through and the outlet end 18 connected to a trigger 20. The rear, generally labeled B. End of the burner is attached to the inlet end 14 of the heating tube 12, e.g. B. by a flange 22 welded to the pipe end 14, which is connected to a flange 24 of the air supply body 26 connected, e.g. B. is screwed. Air is this burner part 26 by a with a control valve 30 provided pipeline 28 and gas a seated on part 26 gas supply body 36 is supplied through a pipeline 32 equipped with a control valve 34. For the introduction of high voltage for electrical ignition, an insulating sleeve 38 can be provided be.

The air is supplied under a pressure of about 0.018 to 0.1-1 atü and that of the gas at a pressure of about 0.009 to 0.14 atü. The valve 30 can be used to regulate the total amount of air (primary and secondary). So can be a single automatically controlled if a group of burners is present Control the air supply to the entire burner group. The total amount of air depends in each case on the need for complete combustion.

Fig. 2 is only a schematic representation. In practice, for usually such a heating tube if the supply lines, as shown, are vertical run, arranged with legs of equal length in a horizontal plane. at a U-tube standing vertically on edge according to FIG. 2 would be the supply lines usually lying horizontally. Accordingly, in Fig. 2 is the protrusion of the burner leg 14 of the heating pipe from the wall 16 is shown exaggeratedly long. In reality this measurement is usually only a few centimeters. The heating pipe can do more as two-way, e.g. B. be designed as a W instead of U-shaped. On the other hand, can it also pass through it in a single line from one side of the furnace to the other.

1Tach Fig. 1, the burner consists of a main pipe 40, the gas and Air or a mixture of gas and primary air is supplied. A highly hydrogenous one Gas, as in artificially generated gases. needs little or no primary air. However, in the case of gases with a low hydrogen content, such as propane, butane or natural gas, a larger addition of primary air is required to maintain combustion. Of course, the total air requirement, primary and secondary, is for a complete Combustion at a given fuel consumption.

The pipe 40 can be referred to as a gas pipe. It's on the inside end provided with a mouthpiece 42, the design of which is particularly evident from FIG. The air supply body 44 (Fig. 1), which surrounds the rear end of the tube 40, lets through a series of passages 46 in the pipe 40 primary air and through one annular passage 48 into the space between the tube 40 and the heating tube end 14 Secondary air flow in. The passages 46 may be rectangular instead of as shown also be designed differently. The burner ends in a throttle space that extends the flame 50, which is larger than the tube 40 and smaller than the heating tube 14 in diameter. Towards the rear, the space 50 is surrounded by a burner mouthpiece 42 Plate 56 except for an annular gap 58 for the inflow of part of the secondary air closed.

An externally controllable means 52 is used to adjust the gas / air ratio to change in the main pipe 40, preferably so that primary and secondary supply be controlled at the same time, but in the opposite sense. To this end is by means of part 52 a sleeve 60 on the pipe 40 towards the air passages 46 mounted axially displaceable. The sleeve 60 is connected by a cross bar 62 an adjustable threaded rod 64 connected to a threaded bushing 66 in the Engagement is. This bushing is on the outside as a hexagonal head 52 formed and against displacement to the outside by a set screw 68 and against Inward displacement secured by head 52. With a second set screw 69 (Fig. 4) rotation of the sleeve 66 is also prevented because the only an axial movement of the bushing preventing screw 68 in contrast to screw 69 is not long enough to attack the rifle with a self-locking mechanism.

The front part of the sleeve 60 is preferably designed so that it can act as a valve for the annular passage 48. As can be seen from FIG. 1, at Movement of the sleeve to the left throttled the primary air supply into the pipe 40 and the secondary air supply in the room around the pipe 40 is increased. When moving the socket 60 to the right, however, conversely, the primary air supply is increased and the secondary air supply throttled. Moving the sleeve to the left increases the longitudinal extension the flame and gives a long bright flame while shifting to the right a shortened bluish flame is produced.

As already mentioned, the need for primary air depends on the nature of the to be burned from the gas. Any axial displacement of the sleeve 60 for regulation the length of the flame depends on the position of the socket, which is determined by the nature of the gas the end. In other words, the axial adjustment is related to any central position, and this central position depends on the particularity of the gas to be burned. There the total amount of air depends on the requirements for complete combustion aligns means adjusting the sleeve to control the flame length essentially an adjustment of the ratio of primary and secondary air. When changing the Total air volume, the main air valve 30 (Fig. 2) must be used to help ensure a sufficient overall air supply for complete combustion.

From Fig. 1 it can be seen that the throttle 50 holding the flame together is substantially larger in diameter than the pipe 40, but substantially smaller than the heating pipe 14. The concentric position of the throttle 50 in the heating pipe is z. B. secured by three spacers 70, as FIG. 6 shows. The majority of the secondary air flows past the throttle 50 or close to the inner surface of the heating tube 14. Some secondary air, however, takes its way through an annular opening 58 between the burner mouthpiece 42 and the rear wall 56. The wall 56 itself is supported by a few, in the example four, ribs 72 which extend away from the wall to a collar 74 surrounding the tube 40. In addition to the mouthpiece 42, these ribs are provided with cutouts which are adapted to the ring opening 58. In this way, the ring opening 58 remains unobstructed by the ribs 72.

The ring opening around the mouthpiece 42 can 3 to 3 in the radial direction 6 mm wide with a 32 mm diameter mouthpiece. The continuity of this Opening has the advantage that the flow in the throttle 50 is not disturbed and can be whirled up. Previously, the gas or gas mixture was at the rear Part of the throttle 50 creates a vacuum, which in the device according to the invention balanced by the trouble-free flow of secondary air through passage 58 will. It is best to have the continuous passage 58 immediately around the mouthpiece 42 and applied axially close to it. A stop screw 76 (Fig. 3) determines the Position of the annular collar 74, which itself is provided with fastening screws 78 (Fig. 6) is.

Due to the continuous flow of air through the uninterrupted Ring opening 58 also avoids soot and has a better shape and shape Control of the flame in room 50 is achieved.

The cylindrical part of the throttle 50 is on the wall 56 by several Barriers 70 (Fig. 3 and 6) attached, the heads of which are extended so far that they act as the aforementioned spacers. The cylinder 50 has the throttle preferably a length approximately corresponding to the diameter.

As FIGS. 1, 4 and 5 show, the air supply body 44 is connected to an air supply line by means of the flange connection 80. It includes a deflector surface or flap 54 that rests on a pin 82 that can be rotated by a handle 84 disposed on the exterior of the body 44. In the same place a scale 86 is attached to indicate the direction of the flap adjustment when adjusting the flame length. It can e.g. B. the maximum deflection by the flap 54 with "long" and the minimum deflection with "short" on the scale under the handle 84 can be indicated. If the air flow is reduced and smoke begins to develop in the event of a greater deflection, the valve 30 shown in FIG. 2 is correspondingly opened further in order to bring in sufficient air. The setting of the gas valve 34 (FIG. 2) and of the air valve 30 must therefore be changed until the desired flame structure is achieved. For example, when the sleeve 60 (FIG. 1) is shifted to the right to allow more primary air to be admitted into the pipe 40, the gas supply is throttled because the increased air pressure in the pipe 40 counteracts the gas inflow. Therefore, the sleeve shift to the right will usually have to be accompanied by a larger opening of the gas valve 34 in order to achieve and maintain the degree of combustion which is necessary for the respective operation of the heating pipe or furnace.

The through the annular passage 48 (Fig. 1) on the outside of the tube 40 secondary air flowing in describes the space between this and the heating pipe 14 a helical path. Since the burner has a considerable overall length, the swirling air needs time to move outwards by centrifugal force and to snuggle up to the outer wall on their way. It has shown, that thereby the admixture of secondary air to the fuel and to that from the mouthpiece 42 outflowing primary air is slowed down and delayed and it is thus possible is made to extend the fuel consumption time to a large extent. A decrease of primary air and an increase in secondary air slows down and increases the combustion the flame length.

The secondary air enters well behind the ignition point (mouthpiece 42) a large chamber, d. H. into the space between the tubes 40 and 14 and can assume a smooth streamlined shape therein; it then becomes outside the throttle guided around them, with or without eddies, but through eddies the Combustion is delayed and the flame is lengthened. In any case, however, occurs a minimum of eddy currents and turbulence.

When the sleeve 60 shifted to the right and the ring opening 48 narrowed is, the effect of the deflector 54 for the turbulence is reduced Secondary air, but this happens at a time when the burner is set on a short flame is. As a result, both settings work in the same direction.

With the present burner is an extensive setting of the Flame length achievable. There is no difficulty in keeping the flame short to be brought down if the burner is used in a very short radiant tube, and on the other hand to achieve such a lengthening of the flame that it is still on The outlet end of a jet pipe of 6 m and more in length is visible and emerges there.

Returning to Fig. 1, it is seen that the gas supply body 90 has a cylindrical front end 92 which is inserted into an opening 94 of the air supply body 44 and therein by a radial in a iL \ Tut 97 (Fig. 1) engaging screw 96 (Fig. 4) is recorded. The body 90 is rotatable relative to the body 44 so that the gas and air supply lines can be connected to the burner in any direction. For example, the gas can be supplied from below and the air supplied from above. The pipe 40 is attached to the gas supply body 90 by a press, not shown, as is the mouthpiece 42 at the end of the pipe 40. The connection of the gas supply line to the body 90 is made by a flange connection 98. In the case shown, this connection is for a 4-inch gas pipe is set up, while the flange connection 80 fits a 11/2 "air pipe, with a burner in a 4 or 5-inch radiant tube. However, these are only examples without restricting the invention.

As is known per se, between the flange connections and the Bodies 44 and 90 thin washers are used to provide the gas and air supply cross-sections to regulate and adapt to the respective circumstances, especially in the case of existing ones and other installations for other purposes. where gas at a special and air is applied at a very different pressure. There is a security measure in this against overloading the burner and the heating tube, which are made of an expensive alloy exists and should not burn out.

The burner is ignited in the usual way by a high-voltage electrode. A terminal 38 provided with insulator 100 and resembling a spark plug is used like this screwed into a threaded opening. The head of the clamp is with a Loop or an eyelet 102 is suspended from a horizontal rod 104 which passes through a cylindrical insulator 106 is guided. This is done by a clamp or Clamp 108 and a screw connection 110 held in place and goes through the Rear wall 56 of the throttle 50 therethrough. At this point, the conductor replicates one inwardly bent electrode 112. The circuit is made by earth connection after the Torch body closed.

The Brennur can, according to FIGS. 1, 4 and 5, with an inspection opening 114 be provided. the through a hollow screw socket with inserted transparent Material is formed. Small screw pins 116 and 117 (Fig. 1) are used for measuring purposes for connecting pressure gauges.

The air supply body 44 essentially has one in the present example rectangular connection plate 120, the corners with holes 126 for mounting screws or bolt is provided. It is attached to a z. B. welded at 124 Flange 122 of the outer end of the tube 14.

A major advantage of the arrangement described is that that the overall length of the torch can be changed, the same at each end Standard parts remain in use. You only need the length of the tube 40 and of the electrode rod 104 to change. This advantage is more important in practice This is important because the different installations have different burner lengths become necessary. In all cases it is desirable to have the throttle 50 in or close to it to attach the passage opening in the wall 16, as shown in FIG. This is why because the inside of the heating tube 14 of the flame and heating is not in one place should be exposed where there is no heat to transfer. So it definitely does the wall thickness of the masonry 16 is the minimum length of the burner. Other factors are peculiarities of the respective installation, such as B. the space required for the pipe connections outside the furnace or, in other words, the distance between the protruding heating pipe 14 from the furnace (Fig. 2) and the type of exhaust connection at the outlet ends of the heating pipes, if these are U- or W-shaped.

From the above, the design and mode of operation of a according to Invention set up gas burner for firing heating pipes and thereby achievable advantages clearly emerge. The burner comes in different sizes manufactured according to the changing diameters of the heating pipes. It is each burner can be used for several sizes of heating tubes, but a substantial one A change in the size of the heating pipe also makes an adjustment to the size of the burner necessary. The burners can be in different versions depending on the wishes of the buyer Lengths are supplied, and a change in torch length is on the factory Can be carried out quickly as required. as explained above.

The burner emits a flame that is adjustable in length within wide limits. In most practice one will be the length of the burner flame's length adjust the heating pipe in which it comes into effect. Adjusting the flame length takes place by changing the mutual ratio of primary and secondary air by convenient adjustment from the outside at 52 and changing the air turbulence, as well convenient thanks to the external adjustment 84.

The setting of the burner depends, among other things, on the The nature of the gas to be burned. Needs artificial gas with a high hydrogen content little or even no addition of primary air. Natural gas can be a moderate addition require primary air. Gases with an extremely high calorific value, such as propane and butane, must receive a correspondingly large proportion of primary air. Gases of the latter Art can initially produce a flame that is far longer than the heating tube; then valve 60 must be operated to shorten the flame.

The ignition is easy and noiseless. Soot formation is excluded. The large burner length forces the secondary air under the influence of centrifugal force to move outward before reaching the burn zone.

Of course, the invention can be modified in detail Shapes are carried out without departing from the basic concept of the invention. So can e.g. B. the externally accessible adjusting means with a cover a flap, plate or the like. Be provided to prevent unauthorized handling. In any case, this is preferably a change during the To be able to carry out burner operation and to monitor the result of the setting.

Claims (10)

PATENT CLAIMS: 1. Gas burner for insertion in a heating tube, whereby the burner protrudes into the heating pipe with most of the length of a main pipe and the main pipe is much greater in length than diameter at its front End ends in a burner mouthpiece and at its rear end in a multiple Is mounted having chambers distributor body, via one chamber of the fuel gas supply opens into the main pipe and the combustion air flows into the ring-shaped chamber via a second chamber Space is supplied between the main pipe and the heating pipe, characterized in that that variable connection openings (46) between the air supply chamber (44) of the Distributor body (26) and the interior of the main pipe (40) for supplying primary air to the fuel gas, furthermore one to change the quantity ratio between primary air and secondary air adjustable annular gap (48) at the outlet of the air supply chamber (44) to the annular space between the main pipe (40) and heating pipe (12) and devices (54) for deflecting the secondary air onto a helical path along the inner surface of the heating pipe (12) are provided. 2. Gas burner according to claim 1, characterized in that that the annular passage (48) is arranged in front of the primary air inlets (46). 3. Gas burner according to claim 1 or 2, characterized in that means (60, 62, 64, 66) for Change of the air-gas ratio in the main pipe (40) are provided. 4. Gas burner according to claim 3, characterized in that the means for changing the air-gas ratio in the main pipe (40) consists of a sleeve (60) which connects the main pipe (40) in front of the primary air inlets (46) and is displaceable on it relative to the primary air inlets (46), to regulate the primary air passing through these inlets (46). 5. Gas burner after Claim 3 or 4, characterized in that the front end of the sleeve (60) as Valve for the annular passage (48) of the secondary air is formed. 6. Gas burner according to claim 4 and 5, characterized in that the front end of the sleeve (60) is designed as a conical collar opposite one at the outlet of the air supply chamber (44) arranged throttle ring is arranged such that upon axial displacement the sleeve (60) for progressively closing the primary air inlets (46) the ring passage (48) widened and the axial displacement of the sleeve (60) to increasing Opening the primary air inlets (46) the annular passage (48) is increasingly narrowed. 7. Gas burner according to one of claims 4 to 6, characterized in that means (62, 64, 68, 52) for moving the sleeve (60) on the main pipe (40) by hand are provided. B. Gas burner according to one of Claims 1 to 7, characterized in that that the means (54, 82, 84) for deflecting the secondary air on a helical Track are adjustable during operation of the burner. 9. Gas burner according to claim 8, characterized in that the deflection device for the secondary air from a adjustable in its angular position deflector flap (54), which extends outwards extending adjustment means (82, 84, 86) carries. 10. Gas burner according to one of the claims 1 to 9, characterized in that the main pipe (40) at its front part carries a mouthpiece (50) whose diameter is between that of the main pipe (40) and that of the heating pipe (12) and that of one the end of the main pipe (40) surrounding but an annular gap (58) leaving free annular plate (56) and a it consists on the circumference surrounding cylinder (50). Considered publications: German Patent Nos. 905 304, 964 535; U.S. Patent No. 2,226,816, 2,764,145.